Novel Herbicides The present invention relates to new, herbicidally active, substituted n-pyridyl-nitrogen heterocycles, methods for the preparation thereof, compositions comprising these compounds, and the use thereof for weed control, especially in crops of cultivated plants, such as grain, cereals, maize, rice, cotton, soybeans, rape, sorghum, sugar cane, sugar beet, sunflowers, vegetables, plantations, and forage crops or for the inhibition of plant growth and for non-selective control of weeds.

N-Phenyl and N-pyridylpyrazole compounds and N-pyridyltetramethylenetriazolidinediones with a herbicidal action are described, for example, in EP-A-0 370 332, DE-A-3 917 469, DE-A-19 518 054, DE-A-19 530 606, US-A-5 306 694 and US-A-4 406 689.

Also known as herbicides are N-pyridylimides, N- (2-pyridyl) pyridazinones and 3- phenyluracils, as described for example in WO 92/00976, JP-A-58-213 776 and EP-A-0 438 209.

N- (Phenyl) tetrahydroimidazoles with a herbicidal action are described for example in US-A- 5 112 383.

New substituted n-pyridylnitrogen heterocycles have now been found with herbicidal and growth-inhibiting properties.

Accordingly, the invention relates to compounds of formula I wherein R, is hydrogen, fluorine, chlorine, bromine or methyl ; R2 is C,-C4alkyl, C,-C4halogenalkyl, halogen, hydroxy, C,-C4alkoxy, C,-C4halogenalkoxy, nitro, amino or cyano; R3 is cyano or R4C (O)- ; R4 is hydrogen, fluorine, chlorine, C1-C8alkyl, C2-C8alkenyl, C2-C8alkinyl, C3-C6cycloalkyl, C1- C2-C8halogenalkenyl,C1-C4alkoxy-C1-C4alkyl,C3-C8halogenalkyl ,cyano-C1-C4alkyl, <BR> <BR> <BR> C6alkenyloxy-C,-C4alkyl, C,-C4alkylthio-C,-C4alkyl, phenyl, phenyl substituted once to three times by halogen, C,-C4alkyl or C,-C4halogenalkyl, benzyl, benzyl substituted once to three times on the phenyl ring by halogen, C1-C4alkyl or C1-C4halogenalkyl ; or R2 R5X1C(O)-; X, is oxygen, sulfur, Rs is hydrogen, C,-C8alkyl, C3-Caalkenyl, C3-C8alkinyl, C3-C6cycloalkyl, C3-C6cycloalkyl-C,- C3-C8halogenalkenyl,cyano-C1-C4alkyl,C1-C4alkoxy-C1-C4alkyl, C6alkyl,C1-C8halogenalkyl, C3-C6alkenyloxy-C,-C4alkyl, (oxiranyl)-CH2-, oxetanyl, C,-C4alkylthio-C,-C4alkyl, phenyl, phenyl substituted once to three times by halogen, C,-C4alkyl or C1-C4halogenalkyl, benzyl, benzyl substituted once to three times on the phenyl ring by halogen, C1-C4alkyl or Ci-C4- halogenalkyl, phenyl-C2-C6alkyl, C,-C6alkyl-CO-C,-C4alkyl, C,-C6-AI kyl-C (O)-[C1-C4-al kylen]- (C6H5) , R8X2C (O)-C,-C6-alkyl, ReX2C (O)- [C,-Cs-alkylen]- or R8X2C (O)-C3-C6cycloalkyl; (C6Hs) X2 is oxygen, sulfur, Ra is hydrogen, C1-C8alkyl, C3-C8alkenyl, C3-Csalkinyl, C3-C6cycloalkyl, C,-Cshalogenalkyl, <BR> <BR> C3-Cshalogenalkenyl, cyano-C,-C4alkyl, C1-C4alkoxy-C,-C4alkyl, C3-C6alkenyloxy-C,-C4alkyl,<BR> <BR> <BR> (oxiranyl)-CH2-, oxetanyl, C,-C4alkylthio-C1-C4alkyl, phenyl, phenyl substituted once to three times by halogen, C1-C4alkyl or C1-C4halogenalkyl, benzyl, benzyl substituted once to three times on the phenyl ring by halogen, C,-C4alkyl or C1-C4halogenalkyl, or phenyl-C2-C6alkyl; R6, R7, Rg and Rio are independently of one another hydrogen, C1-C8alkyl, C3-C8alkenyl, C3- C8alkinyl, C,-C8halogenalkyl or benzyl; or R3 B1-C2-C8alkenyl,B1-C2-C8alkinyl,B1-C1-C8halogenalkyl,B1-C2-B 1-C1-C8alkyl, B1-C1-C4alkylthio-C1-C4alkylC8halogenalkenyl,B1-C1-C4alkoxy- C1-C4alkyl, or B1-C3- C6cycloalkyl; B, is hydrogen, cyano, hydroxy, C,-C$alkoxy, C3-C8alkenyloxy, R"X3C (O)-, C,- C1-C4halogenalkylcarbonyl;C4alkylcarbonylor X3 has the same meaning as X2; R"has the same meaning as R8; or R3 is B2-C (R12)=CH-; B2 is nitro, cyano or R13X4C(O)-; R, 2 is cyano or R14X5C(O)-; X4 and Xs have the same meaning as X2; and R, 3 and R, 4 have the same meaning as R8 ; W is a (Wio) group; Pis is C,-C3alkyl, C,-C3halogenalkyl or amino; R16 is C1-C3halogenalkyl, C1-C3alkyl-S(O)n1, C1-C3halogenalkyl-S(O)n1 or cyano; or R16 and Ris together form a C3-or C4alkylene or C3-or C4alkenylene bridge which may be substituted by halogen, C,-C3halogenalkyl or cyano; n, is 0, 1 or 2; hydrogen,C1-C3alkyl,halogen,C1-C3halogenalkylorcyano;orR17is R17 and R, 6 together form a C3-or C4alkylene or C3-or C4alkenylene bridge which may be substituted by halogen, C1-C3halogenalkyl or cyano; R18 is hydrogen, C1-C3alkyl, halogen or cyano; Ri9 is C1-C3halogenalkyl; or Rig and R, B together form a C3-or C4alkylene or C3-or C4alkenylene bridge which may be substituted by halogen, C1-C3halogenalkyl or cyano; R20 is hydrogen or C1-C3alkyl or halogen; or R20 and Rlg together form a C3-or C4alkylene or C3-or C4alkenylene bridge which may be substituted by halogen, C1-C3halogenalkyl or cyano; R21 is hydrogen, C1-C3halogenalkyl,R40O-,R41S(O)n2,R42(R43)N,halogen, Ras (R46) N-C (R44) =N-, hydroxy, nitro or N=C-S- ; R40 is C2-C4alkenyl,C3-orC4alkinylorC1-C5alkoxycarbonyl-C1-C3haloge nalkyl, C1-C4alkyl; R41 is C,-C4alkyl or C1-C4halogenalkyl; n2 is 0,1 or 2; R42 is hydrogen, C1-C4alkyl, C1-C4halogenalkyl, C3-C6cycloalkyl, OHC-or C,-C4alkylcarbonyl; R43, R44, and R46 are independently of one another hydrogen or C1-C4alkyl ; R45C1-C4alkyl; R22 is hydrogen, C1-C4alkyl, halogen, C1-C4halogenalkyl, C2-C4alkenyl, C3-C5halogenalkenyl, C3-C3-or C1-C4alkylcarbonyl,C1-C4halogenalkylcarbonyl,C2-C1-C4alkoxy, C4alkenylcarbonyl, C2-C4halogenalkenylcarbonyl, C2-C4alkinylcarbonyl, C2-C4halogenalkinyl- carbonyl, C1-C4alkylcarbamoyl, C1-C4alkylS(O)n3, C3- or C4alkinylS(O)n3, OHC-, nitro, amino, cyano or N=C-S- ; n3 is 0,1 or 2; R23 and R24 independently of one another are hydrogen, C1-C4alkyl, halogen, C1-C4halogen- alkyl or cyano; R25 and R26 are independently of one another hydrogen, methyl, halogen, hydroxy or =O; R27 and R28 are independently of one another hydrogen, C1-C4alkyl or C1-C4halogenalkyl; R29 and R30 are independently of one another hydrogen, C1-C3alkyl or halogen; R3, and R32 independently of one another are hydrogen or C1-C4alkyl; or R3, and R32 together form the group R47 and R48 are independently of one another C1-C4alkyl; or R47 and R48 together form a C4 or Csalkylene bridge; R33 is hydrogen or C1-C3alkyl; or R33 together with R32 forms a C3-Csalkylene bridge which may be broken by oxygen and/or substituted by halogen, C1-C3alkylcarbonyloxy,C1-C3alkyl-C2-C4alkenyl, sulfonyloxy, hydroxy or =0; R34, R35, R36 and R37 are independently of one another hydrogen, C1-C3alkyl, C3- or C4alkenyl or C3-C5alkinyl; or R34 and R35 on the one hand and R36 and R37 on the other each form a C2-C5alkylene or C3- C5alkenylene bridge, which may be broken by oxygen,-C (O)-, sulfur, or-S (0) 2-; R38 is hydrogen, C1-C4alkyl, C,-C4halogenalkyl, C3-or C4alkenyl or C3-or C4alkinyl; R39 is hydrogen, C1-C4alkyl, C1-C3alkoxy-C1-or-C2alkyl, C,-C4halogenalkyl, C3-or C4alkenyl, C3-or C4halogenalkenyl or C3-or C4alkinyl; or R39 and R38 together form a C3-C5alkylene bridge; and X6, X71 X8, Xg, X10, X11, X12, X13, X14, X15, X16, X17, X18 and Xlg are independently of one another oxygen or sulfur, and the agrochemically acceptable salts and stereoisomers of these compounds of formula 1.

In the definitions listed hereinbefore, halogen is taken to mean iodine, preferably fluorine, chlorine and bromine.

The alkyl, alkenyl and alkinyl groups mentioned in the substituent definitions may be straight-chained or branched, as is also the case with the alkyl, alkenyl and alkinyl part of the alkylcarbonyl, alkylcarbonyloxy, alkylcarbonylalkyl, alkenyloxy, alkenyloxyalkyl, <BR> <BR> <BR> <BR> alkenylcarbonyl, alkinylcarbonyl, alkylcarbamoyl, hydroxyalkyl, cyanoalkyl, alkoxyalkyl,<BR> <BR> <BR> <BR> <BR> alkylthio, alkylthioalkyl, alkylthio-C (O)-, alkylS (O) n3, alkylsulfonyloxy, alkylaminocarbonyl, dialkylaminocarbonyl, alkylcarbonylalkyl, B, alkyl, B, alkenyl, B, alkinyl, HOC (O) alkyl, phenylalkyl and R8X2C (O)-C,-C6alkyl groups.

Alkyl groups are for example methyl, ethyl, n-propyl, isopropyl, n-butyl, sec-butyl, isobutyl, tert-butyl and the various isomeric pentyl, hexyl, heptyl and octyl radicals. Preferred are methyl, ethyl, n-propyl, isopropyl and n-butyl.

Examples of alkenyis are vinyl, allyl, methallyl, 1-methylvinyl, but-2-en-1-yl, pentenyl, 2- hexenyl, 3-heptenyl and 4-octenyl, preferably alkenyl radicals with a chain length of 3 to 5 carbon atoms.

Examples of alkinyls are ethinyl, propargyl, 1-methylpropargyl, 3-butinyl, but-2-in-1-yl, 2- methylbutin-2-yl, but-3-in-2-yl, 1-pentinyl, pent-4-in-1-yl or 2-hexinyl, preferably alkinyl radicals with a chain length of 2 to 4 carbon atoms.

Alkyl groups substituted once or more, especially once to three times, by halogen are suitable as the halogenalkyl, the halogen being iodine, especially fluorine, chlorine and bromine, for example fluoromethyl, difluoromethyl, trifluoromethyl, chloromethyl, dichloromethyl, trichloromethyl, 2-fluoroethyl, 2,2-difluoroethyl, 2-chloroethyl, 2,2- dichloroethyl, 2,2,2-trifluoroethyl, 2,2,2-trichloroethyl and pentafluoroethyl.

Suitable halogenalkenyls are alkenyl groups substituted once or more by halogen, the halogen being bromine, iodine and especially fluorine and chlorine, for example 2-and 3- fluoropropenyl, 2-and 3-chloropropenyl, 2-and 3-bromopropenyl, 2,3,3-trifluoropropenyl, 3,3,3-trifluoropropenyl, 2,3,3-trichloropropenyl, 4,4,4-trifluorobut-2-en-1-yl and 4,4,4- trichlorobut-2-en-1-yl. Of the alkenyi radicals substituted once, twice or three times by halogen, those with a chain length of 3 or 4 carbon atoms are preferred. The alkenyl groups may be substituted by halogen on saturated or unsaturated carbon atoms.

Suitable halogenalkinyls are for example alkinyl groups substituted by halogen, the halogen being bromine, iodine and especially fluorine and chlorine, for example 3-fluoropropinyl, 3- chloropropinyl, 3-bromopropinyl, 3,3,3-trifluoropropinyl and 4,4,4-trifluorobut-2-in-1-yl.

Alkylsulfonyl is for example methylsulfonyl, ethylsulfonyl, propylsulfonyl, isopropylsulfonyl, n-butylsulfonyl, isobutylsulfonyl, sec-butylsulfonyl, tert-butylsulfonyl; preferably methylsulfonyl and ethylsulfonyl.

Halogenalkylsulfonyl is for example fluoromethylsulfonyl, difluoromethylsulfonyl, trifluoromethylsulfonyl, chloromethylsulfonyl, trichloromethylsulfonyl, 2-fluoroethylsulfonyl, 2,2,2-trifluoroethylsulfonyl and 2,2,2-trichloroethylsulfonyl.

Halogenalkenylsulfonyl is for example 2-and 3-fluoropropenylsulfonyl, 2-and 3-chloro- propenylsulfonyl, 2-and 3-bromopropenylsulfonyl, 2,3,3-trifluoropropenylsulfonyl, 2,3,3- trichloropropenylsulfonyl, 4,4,4-trifluorobut-2-en-1-yl-sulfonyl and 4,4,4-trichlorobut-2-en-1- yl-sulfonyl.

Cyanoalkyl is for example cyanomethyl, cyanoethyl, cyanoeth-1-yl and cyanopropyl.

Hydroxyalkyl is for example hydroxymethyl, 2-hydroxyethyl and 3-hydroxypropyl.

Alkylamino is for example methylamino, ethylamino and the isomeric propyl and butylamino.

Dialkylamino is for example dimethylamino, diethylamino and the isomeric dipropyl and dibutylamino.

Halogenalkylamino is for example chloroethylamino, trifluoroethylamino and 3-chloro- propylamino.

Di (halogenalkyl) amino is for example di (2-chloroethyl)-amino.

Alkylcarbonyl is in particular acetyl and propionyl.

Halogenalkylcarbonyl is in particular trifluoroacetyl, trichloroacetyl, 3,3,3-trifluoropropionyl and 3,3,3-trichloropropionyl.

Alkenylcarbonyl is in particular vinylcarbonyl, allylcarbonyl, methallylcarbonyl, but-2-en-1-yl- carbonyl, pentenylcarbonyl and 2-hexenylcarbonyl.

Alkinylcarbonyl is in particular acetylenecarbonyl, propargylcarbonyl, 1-methyl- propargylcarbonyl, 3-butinylcarbonyl, but-2-in-1-yl-carbonyl and pent-4-in-1-yl-carbonyl.

Alkoxy is for example methoxy, ethoxy, n-propoxy, isopropoxy, n-butoxy, isobutoxy, sec- butoxy and tert-butoxy; preferably methoxy, ethoxy and isopropoxy.

Alkenyloxy is for example allyloxy, methallyloxy and but-2-en-1-yloxy.

Alkinyloxy is for example propargyloxy and 1-methylpropargyloxy.

Alkoxyalkyl is for example methoxymethyl, methoxyethyl, ethoxymethyl, ethoxyethyl, n- propoxymethyl, n-propoxyethyl, isopropoxymethyl and isopropoxyethyl.

Alkenyloxy is for example allyloxyalkyl, methallyloxyalkyl and but-2-en-1-yloxyalkyl.

Alkoxycarbonyl is for example methoxycarbonyl, ethoxycarbonyl, n-propoxycarbonyl, isopropoxycarbonyl and n-butoxycarbonyl, preferably methoxycarbonyl and ethoxycarbonyl.

Alkenyloxycarbonyl is for example allyloxycarbonyl, methallyloxycarbonyl, but-2-en-1-yl- oxycarbonyl, pentenyloxycarbonyl and 2-hexenyloxycarbonyl.

Alkinyloxycarbonyl is for example propargyloxycarbonyl, 3-butinyloxycarbonyl, but-2-in-1-yl- oxycarbonyl and 2-methylbutin-2-yl-oxycarbonyl. <BR> <BR> <BR> <P>Alkoxyalkoxycarbonyl is for example methoxymethoxycarbonyl, ethoxymethoxycarbonyl,<BR> <BR> <BR> <BR> <BR> ethoxyethoxycarbonyl, propoxymethoxycarbonyl, propoxyethoxycarbonyl, propoxypropoxycarbonyl and butoxyethoxycarbonyl.

Halogenalkoxy is for example fluoromethoxy, difluoromethoxy, trifluoromethoxy, 2,2,2- trifluoroethoxy, 1,1,2,2-tetrafluoroethoxy, 2-fluoroethoxy, 2-chloroethoxy and 2,2,2- trichloroethoxy.

The cycloalkyl radicals suitable as substituents are for example cyclopropyl, cyclobutyl, cyclopentyl and cyclohexyl.

The cycloalkoxycarbonyl radicals suitable as substituents are for example cyclopropoxy- carbonyl, cyclobutoxycarbonyl, cyclopentoxycarbonyl and cyclohexyloxycarbonyl.

Alkylthio is for example methylthio, ethylthio, propylthio and butylthio, as well as the branched isomers thereof.

Alkylthioalkyl is for example methylthioethyl, ethylthioethyl, methylthiopropyl and ethylthiopropyl.

Halogenalkylthiocarbonyl is for example fluoromethylthiocarbonyl, difluoromethylthiocarbonyl, trifluoromethylthiocarbonyl, 2,2,2-trifluoroethylthiocarbonyl, 1,1,2,2-tetrafluoroethylthiocarbonyl, 2-fluoroethylthiocarbonyl, 2-chloroethylthiocarbonyl and 2,2,2-trichloroethylthiocarbonyl.

Corresponding meanings may also be ascribed to the substituents in the listed definitions, such as, for example, halogenalkenylcarbonyl, halogenalkinylcarbonyl, R4o0-, R4C (O)-, R"X3C (O)-, R, 3X4C (O)-, R, 4X5C (O)-, RsX, C (O)-R8X2C (O)-alkyl, R8X2C (O)-cycloalkyl, R41(0) n2-, , R42 (R43) N-, R45 (R46) N-C (R44) =N-, Bialkyl, Bialkenyl, B, alkinyl, B, halogenalkyl, B, halogenalkenyl, B, alkoxyalkyl, B, alkylthioalkyl, B, cycloalkyl and<BR> <BR> B2-C (Rl2) =CH-.

In the definition of R5, the groups C,-C6-Alkyl-C (O)- [C-C4-alkylen]- and (C6H5) R8X2C(O) [C1-C6-alkylen]- (C6H5) mean that the C,-C6alkyl-C (O)- or C,-C6alkylene chain is in addition substituted by phenyl (C6H5) on one of the 4 or 6 carbon atoms, wherein the phenyl ring is substituted once to three times by halogen, C1-C4alkyl or C1-C4halogenalkyl, and the alkylene chain may be straight-chained or branched and may, for example, be methylene, ethylene, methylethylene, propylene, 1-methylpropylene and butylene.

In the definitions cyanoalkyl, alkylcarbonyl, alkenylcarbonyl, halogenalkenylcarbonyl, alkinylcarbonyl, alkoxycarbonyl, alkoxycarbonylalkyl and halogenalkylcarbonyl, the cyano- and carbonyl carbon atoms are not included in the upper and lower limits of the carbon number.

L in the reagents of formulae XII, XXI, XXIVa, XXIVb and XXXV is a leaving group, such as halogen, for example, preferably chlorine, bromine or iodine, C1-C3alkyl-or arylsulfonyloxy, preferably CH3SO2O-or , or C,-C6alkylcarbonyloxy, preferably acetyloxy.

L, in the reagent of formula XIII is a leaving group such as, for example, HOS (O) 20-, L2 in the reagents of formulae XXVa and XXVc is a leaving group such as, for example, hydroxy, C,-C4alkoxy or halogen, preferably chlorine, bromine or iodine.

L3 in the reagent of formula XXXI is a leaving group such as chlorine or bromine, trichloromethoxy or L4 in the compounds of formulae 11 and III (reaction schemes 1 and 2) is a leaving group such as, for example, halogen, typically fluorine, chlorine or bromine or C,-C4alkyl-or phenylsulfonyi or C,-C4alkyl-, C,-C4halogenalkyl-or phenylsulfonyloxy.

R33 together with R32 (group W7) forms a C3-C5alkylene bridge which may be broken for example by oxygen and substituted by =O, and is illustrated by way of example in Tables <BR> <BR> <BR> <BR> 127 (compound of formula 1127), 130 (compound of formula 1130), 136 (compound of formula il36) and 137 (compound of formula 1137).

The invention relates also to the salts which the compounds of formula I with acidic hydrogen, especially the derivatives with carboxylic acid groups (for example, carboxyl- substituted alkyl, alkylene, alkenyl, alkinyl, alkoxyalkyl, alkylthioalkyl and cycloalkyl groups) may form with bases. These salts are, for example, alkali metal salts, such as sodium and potassium salts; earth alkali metal salts, such as calcium and magnesium salts; ammonium salts, i. e. unsubstituted ammonium salts and monosubstituted or polysubstituted ammonium salts, such as triethylammonium and methylammonium salts; or salts with other organic bases.

Salt-forming alkali metal and alkaline earth metal bases include the hydroxides of lithium, sodium, potassium, magnesium or calcium, those of sodium and potassium being especially preferred. Suitable salt-forming substances are described for example in WO 97/41112.

Examples of amines suitable for forming ammonium salts are ammonia, as well as primary, secondary, and tertiary C,-C, 8alkylamines, Ci-C4hydroxyalkylamines and C2- C4alkoxyalkylamines, typically methylamine, ethylamine, n-propylamine, isopropylamine, the four isomeric butylamines, n-amylamine, isoamylamine, hexylamine, heptylamine, octylamine, nonylamine, decylamine, pentadecylamine, hexadecylamine, heptadecylamine, octadecylamine, methyl ethylamine, methyl isopropylamine, methyl hexylamine, methyl nonylamine, methyl pentadecylamine, methyl octadecylamine, ethyl butylamine, ethyl heptylamine, ethyl octylamine, hexyl heptylamine, hexyl octylamine, dimethylamine, diethylamine, di-n-propylamine, diisopropylamine, di-n-butylamine, di-n-amylamine, diisoamylamine, dihexylamine, diheptylamine, dioctylamine, ethanolamine, n- propanolamine, isopropanolamine, N, N-diethanolamine, N-ethylpropanolamine, N- butylethanolamine, allylamine, n-butenyl-2-amine, n-pentenyl-2-amine, 2,3-dimethylbutenyl-- 2-amine, dibutenyl-2-amine, n-hexenyl-2-amine, propylenediamine, trimethylamine, triethylamine, tri-n-propylamine, triisopropylamine, tri-n-butylamine, triisobutylamine, tri-sec- butylamine, tri-n-amylamine, methoxyethylamine and ethoxyethylamine; heterocyclic amines such as pyridine, quinoline, isoquinoline, morpholine, thiomorpholine, piperidine, pyrrolidine, indoline, quinuclidine and azepine; primary arylamines such as anilines, methoxyanilines, ethoxyanilines, o-, m-and p-toluidines, phenylenediamines, benzidines, naphthylamines and o-, m-and p-chloroanilines; but especially triethylamine, isopropylamine and diisopropylamine.

The salts of compounds of formula I with basic groups, especially with basic pyridyl and pyrazolyl rings (W3 and W4), or of derivatives with amino groups, e. g. amino, alkylamino and dialkylamino groups in the definition of R2, W1 or W3 (Rig, Rsi, R22) are, for example, salts with inorganic and organic acids, for example hydrogen halides, such as hydrofluoric acid, hydrochloric acid, hydrobromic acid or hydriodic acid, as well as sulfuric acid, phosphoric acid, nitric acid and organic acids, such as acetic acid, trifluoracetic acid, trichloroacetic acid, propionic acid, hydroxyethanoic acid, thiocyanic acid, citric acid, benzoic acid, oxalic acid, formic acid, benzenesulfonic acid, p-toluenesulfonic acid and methanesulfonic acid The presence of at least one asymmetric carbon atom in the compounds of formula 1, for <BR> <BR> <BR> example in substituent R3 = Rs, C (O)-, wherein R5 is a branched alkyl, alkenyl, halogenalkyl or alkoxyalkyl group, or R3=B1-C3-C6cycloalkyl, wherein for example B, is Ci-Cgaikoxy or R"X3C (O)-, means that the compounds may occur both in single optically active isomers and also in the form of racemic mixtures. In the present invention, the active substances of formula I are understood to include both the pure enantiomers and the racemates or diastereomers.

If an aliphatic C=C double bond is present (e. g. in substituent R3 = B2-C (Ri2) =CH-), then geometric isomerism may occur. The present invention also relates to these isomers.

Compounds of formula I are preferred wherein R2 is methyl, halogen, hydroxy, nitro, amino or cyano.

Also preferred are compounds of formula I wherein W is the group and R1s, R, 6, R17, X6 and X7 are as defined under formula 1.

Especially preferred are those compounds wherein R15 is methyl; R16 is trifluoromethyl; R17 is hydrogen; and X6 and X7 are oxygen.

Likewise preferred are compounds of formula I wherein R, is fluorine or chlorine; R2 is chlorine, bromine or cyano; and R3 is RsX, C (O)-, wherein Rs has the meaning defined under formula 1; and X, is oxygen or sulfur. Of these compounds, those wherein R2 is chlorine are especially important.

The method described in the invention for the preparation of compounds of formula 1,. wherein Ri, Rz, Ra, A and W are as defined under formula 1, is carried out by analogy with known methods, such as those described for example in WO 97/00246, WO 96/01254 and International Patent Application Number PCT/EP 97/06243, and comprises treating a compound of formula 11 wherein Ri, R2 and W have the meanings indicated, and L4 is a leaving group such as halogen, either a) in a suitable solvent, where appropriate in the presence of a base such as a trialkylamine, a palladium or nickel catalyst and a compound of formula V Rs-OH (V), wherein Rs is hydrogen or C,-C4alkyl, in an autoclave under positive pressure with carbon monoxide, or b) in a suitable solvent in the presence of a tertiary amine, a palladium catalyst, and an olefin by means of the Heck reaction, or under said conditions by means of reaction with a Grignard reagent of formula Va R3-Mg-halogenide (Va), wherein R3 is B1-C1-C8alkyl, B1-C2-C8alkenyl, B1-C2-C8alkinyl, B1-C1-C8halogenalkyl, B1-C2- C8halogenalkenyl, B1-C,-C4alkoxy-C,-C4alkyl, Bi-C,-C4alkylthio-C-C4alkyl or B,-C3- C6cycloalkyl and B, is as defined under formula 1, or in an inert solvent and in the presence of a catalyst, such as palladium-bis-triphenylphosphine dichloride (Pd (C6H5) 2CI2), in a manner analogous to that described in Synlett 1998,1185, with a tin compound of formula Vb (R3) 4Sn (Vb), wherein R3 has the meaning indicated, or c) where applicable in an inert solvent at reaction temperatures of 20-300°C subjecting it to a cyanidation reaction, e. g. with an alkali metal cyanide or a cyanide whose metal ion belongs to the first or second subgroup of the periodic system, such as copper cyanide., in a manner analogous to that described in J. Het. Chem. 11,397 (1974), or d) first oxidizing it in a suitable solvent to form a compound of formula IV and treating this in an inert solvent with dimethylcarbamoyl chloride and a cyanidation reagent, and then where applicable further functionalizing it according to the definitions of A and R3.

The method described in the invention for the preparation of compounds of formula 1, wherein R"R2, R3 and A are as defined under formula 1, W is a W, group (W,), and R, 5, R, 6, R", X6 and X7 are as defined under formula I corresponding to a compound of formula la in reaction scheme 2, is carried out by analogy with the known methods such as those described for example in EP-A-0 438 209 or DE-OS- 19 604 229, and comprises reacting a compound of formula III wherein Ri, R2 and R3 have the meanings indicated, and L4 is a leaving group, such as halogen, for example fluorine, chlorine or bromine, in the presence of an inert solvent and ammonia if necessary in an autoclave at temperatures of-10 to 180°C to form a compound of formula VI reacting this in the presence of a base and a solvent a) with a chloroformate of formula Vil wherein X6 is as defined under formula 1, to form a compound of formula VIIl -R l'X6 /=A ! f R2 H 1 C Alkyl (VIII), or \ N R3 b) with oxalyl chloride, phosgene or thiophosgene to form a compound of formula IX followed by cyclization of a compound of formula VIII or IX in the presence of 0.1-1.5 equivalents of a base in an inert solvent with an enamine dervivative of formula X R 16 X7 H2N OCi-C4-Alkyl R 17 wherein R16 and R17 are as defined under formula 1, and X7 is oxygen, and a resulting compound of formula XI wherein R1, R2, R3, R16, R17, X6 and X7 have the meanings indicated, and further reacting this compound in the presence of an inert solvent and a base with c) a compound of formula XII R, 5-L (Xll), wherein R, 5 is d-Csaiky ! or C1-C3halogenalkyl, and L is a leaving group, or d) with a hydroxylamine derivative of formula XIII NH2-L1 (XIII), wherein L, is a leaving group, and subsequently performing if necessary oxidation (A and thionization.

The method described in the invention for the preparation of compounds of formula I wherein Ri, R2, R3, and A are as defined under formula 1, W is a W2 group (W2), and R, 8, Rlg, R20, and X8 are as defined under formula I corresponding to a compound of formula lb in reaction scheme 3, is carried out by analogy with known methods, such as those described for example in DE-A-4 423 934 and JP-A-58 213 776, and comprises either a) reacting a compound of formula III, wherein R,, R2 and R3 have the meanings indicated, and L4 is a leaving group such as halogen, for example fluorine, chlorine or bromine, with hydrazine, preferably in an amphiprotic solvent, to form a compound of formula XIV further reacting this with a compound of formula XV or XVa wherein R18 and Rlg have the meanings defined under formula 1, and Hal in a compound of formula XVa is chlorine or bromine, or b) first diazotizing a compound of formula VI, wherein R,, R2 and R3 have the meanings indicated, then further reacting it with a compound of formula XVI wherein R, 8 and Rlg have the meanings indicated, and obtaining a compound of formula XVII which if necessary is cyclized in the presence of a base, such as 4-dimethylaminopyridine and a compound of formula XVIII XB P (Phenyl) 3 t ! ("')- C-C4-Alkyl° R 20 wherein R2o has the meaning indicated, and X8 is oxygen, and subsequently performing if necessary oxidation The method described in the invention for the preparation of compounds of formula I wherein Ri, R2, R3 and A are as defined under formula 1, W is a W7 group (W7), and R31, R32, R33, and X8 are as defined under formula I corresponding to a compound of formula Ig in reaction scheme 4, is carried out by analogy with known methods, such as those described for example in EP-A-0 272 594, EP-A-0 493 323, DE-A-3 643 748, WO 95/23509, US-A-5 665 681 and US-A-5 661 109, and comprises for example either a) reacting a compound of formula Villa roi X14 R2-N Ocl-c4-Alkyl (Vllla), N R/ in the presence of a solvent and a base, or b) a compound of formula IXa if necessary in a suitable solvent, wherein the radicals Ri, R2, R3 and X14 in compounds of formula Villa and IXa have the meanings indicated, with a compound of formula XIX R X R32 X13 R33NH XLL OC-C4-Alkyl (XIX), I R31 wherein R31, R32, R33 and X13 have the meanings indicated, and obtaining a compound of formula XX Ruz /'v Y R2-N11 N oci-c 4-Alkyl (XX) N H i R 33 R 31 R3 Il 3cyclizing this in the presence of a suitable solvent and a base and then where applicable c) if R33 is hydrogen, reacting it with a compound of formula XXI R33-L (XXI), wherein R33 is d-Csaiky !, and L is a leaving group, and subsequently performing if necessary oxidation and thionization.

The method described in the invention for the preparation of compounds of formula I wherein Pi, R2, R3 and A are as defined under formula 1, W is a W8 group (W8), and R34, R3s, X, S, and X, 6 are as defined under formula I corresponding to a compound of formula Ih in reaction scheme 5, is carried out by analogy with known methods, such as those described for example in EP-A-0 210 137, DE-A-2 526 358, EP-A-0 075 267 and EP-A-0 370 955, and comprises a) reacting a compound of formula Vlllb ruz /Ag R2 N. Ocl-c4-Alkyl N R3 in the presence of a solvent and a base, or b) a compound of formula IXb wherein the radicals Ri, R2, R3 and Xi5 in compounds of formula Vlllb and IXb have the meanings indicated, if necessary in a suitable solvent, with a compound of formula XXII X16 R34NH N t OC1-C4-Alkyl (XXII), i R 35 wherein R34, R35, and X16 have the meanings indicated, and obtaining a compound of formula XXIII R1 X15 X16 R2 N (XX) ! !), -N Ruz R3 cyclizing this in the presence of a suitable solvent and a base and then where applicable c) if R34 and/or R35 are/is hydrogen, further reacting it with a compound of formula XXIVa or XXIVb R34-L (XXIVa) or R35-L (XXIVb), wherein R34 and R35 are independently Ci-Csaikyi, and L is a leaving group, or with a Michael acceptor, and then if necessary oxidizing and thionizing it.

The method described in the invention for the preparation of compounds of formula I wherein Ri, R2, R3 and A are as defined under formula I, W is a W3 group (W3), and R21, R22, and R23 are as defined under formula I corresponding to a compound of formula Ic in reaction scheme 6, is carried out by analogy with known methods, such as those described for example in WO 97/07114, US-A-5 306 694, DE-A-3 832 348, EP-A-0 257 479 and EP-A-0 500 209, and comprises condensing a compound of formula XIV wherein Ri, R2 and R3 have the meanings indicated, for example a) with a compound of formula XXV wherein R21 is hydrogen, Ci-Csaikyi or C1-C3halogenalkyl; R22 is hydrogen, C1-C4alkyl, Ci- C4halogenalkyi, C2-C4alkenyl, C3-C5halogenalkenyl or C3-or C4alkinyl; and R23 is hydrogen, C1-C4alkyl or C1-C4halogenalkyl, if necessary in the presence of an acidic, basic or bifunctional catalyst such as p-toluenesulfonic acid, for example, or b) with a compound of formula XXVa wherein R22 and R23 have the meanings indicated, and L2 is a suitable leaving group, to. form a compound of formula XXVI and further functionalizing the pyrazolone group in accordance with the definition of R2, in a manner analogous to known methods, for example using a halogenation agent such as phosphorus oxychloride, to form the corresponding halogen derivative of formula Ic wherein Ri, R2, R3, R22 and R23 have the meanings indicated, and R21 is halogen, and subsequently performing if necessary oxidation The method described in the invention for the preparation of compounds of formula I wherein Ri, R2 R3 and A are as defined under formula 1, W is a W4 group (W4), and R24, R25, R26 are as defined under formula I corresponding to formula Id in reaction scheme 7, is carried out by analogy with known methods such as those described for example in EP-A-0 370 332, EP-A-0 370 955 or DE-A- 3 917 469, and comprises condensing a compound of formula XIV wherein Ri, R2 and R3 have the meanings indicated, a) with a compound of formula XXVb wherein R25 and R26 have the meanings indicated, and R24 is hydrogen, C1-C4alkyl or Cl- C4halogenalkyl, if necessary in the presence of a catalyst, or b) with a compound of formula XXVc wherein R25 and R26 have the meanings indicated, and L2 is a suitable leaving group, to form a compound of formula XXV) a and treating this compound with a halogenation agent, such as phosphoroxy halogenide or thionyl halogenide, and obtaining a compound of formula Id wherein Ri, R2, R3, R25 and R26 have the meanings indicated and R24 is halogen, and reacting this compound if necessary with a cyanide of formula XXVII M(CN) s (XXVII), wherein M is an ammonium cation, alkali metal ion or metal ion of the first or second subgroup of the periodic system, and s is the number 1 or 2, where applicable in the presence of an alkali metal iodide (R24 =cyano; reaction scheme 7), and subsequently performing if necessary oxidation The method described in the invention for the preparation of compounds of formula I wherein Ri, R2, R3 and A are as defined under formula 1, W is a W5 or W6 (W6) group, and R27, R28, R29, R30, and X9 to X12 are as defined under formula 1, corresponding to compounds of formula le and If in reaction scheme 8, is carried out by analogy with known methods, such as those described for example in DE-A-3 917 469, WO 92/00976, US-A-5 069 711 and EP-A-0 260 228, and comprises for example a) reacting a compound of formula XXVIII b) a compound of formula XXVllla wherein radicals R27 to R30 in compounds of formulae XXVIII and XXVllla have the meanings indicated, with a compound of formulae VI wherein Ri, R2 and R3 have the meanings indicated, in an inert solvent in the presence of a C1-C4alkylcarboxylic acid at temperatures of 20° to 200°C and reacting the resulting compounds of formulae le and If wherein R, to R3 and R27 to R30 have the meanings indicated, and Xg to X12 are oxygen, if necessary with the aid of a suitable sulfur reagent to form the corresponding thiono compound of formulae le and If, wherein Xg and/or Xio, Xn, Xis, are sulfur, and oxidizing the said compound , reaction scheme 8).

The method described in the invention for the preparation of compounds of formula I wherein RI, R2, R3, and A are as defined under formula 1, W is a Wg group (W9), and R36, R37, Xi ?, and X, 8 are as defined under formula 1, corresponding to a compound of formula li in reaction scheme 9, is carried out by analogy with known methods, such as those described for example in WO 95/00521, EP-A-0 611 708 and WO 94/25467, and comprises for example reacting a) a compound of formula Vlllc b) a compound of formula IXc wherein the radicals Ri, R2, R3 and X18 in compounds of formulae Vlllc and IXc have the meanings indicated, if necessary in the presence of a suitable solvent and a base, with a compound of formula XXIX R37-NH-NH-R36 (XXIX), wherein R36 and R37 are as defined under formula 1, and obtaining a compound of formula XXX and subsequently reacting this, if necessary in a solvent and in the presence of a base, with a (thio-) carbonylation reagent of formula XXXI wherein X17 has the meaning indicated, and L3 is a leaving group (reaction scheme 9), and subsequently performing if necessary oxidization The method described in the invention for the preparation of compounds of formula I wherein R1, R2, R3 and A are as defined under formula 1, W is a W10 group (W10), and R38, R39, and Xlg are as defined under formula I corresponding to a compound of formula Ik in reaction scheme 10, is carried out by analogy with known methods, such as those described for example in US-A-5 980 480, DE-A-3 917 469, US-A-4 818 275, US-A-5 041 155 und EP-A-0 610 733, and comprises, for example, a) reacting a compound of formula XIV if necessary in the presence of a catalyst, with a compound of formula XXXII to form a compound of formula XXXIII wherein the radicals Ri, R2, R3 and R39 in the compounds of formulae XIV, XXXII and XXXIII have the meanings indicated, and further cyclizing this compound with an azide of formula XXXIV R38=H),or(X19=O, b) cyclizing a compound of formula XIV with a compound of formula XXXVI wherein the radicals R1, R2, R3 and R39 in the compounds of formulae XIV and XXXVI have the meanings indicated, (X19 =O, R38 =H), or c) cyclizing a compound of formula XIV first with a compound of formula XXXVII R39-CHO (XXXVII) to form a compound of XXXIIIa then with an alkali metal cyanate to form a compound of XXXVIII and finally cyclizing this compound in the presence of an oxidation agent and obtaining a compound of formula Ik wherein Ri, R2, R3 and R39 have the meanings indicated, Xig is oxygen, and R38 is hydrogen, and treating this compound if necessary with a sulfur reagent (Xig = S) and in the presence of a base with an alkylation reagent of formula XXXV <BR> <BR> R38-L (XXXV),<BR> <BR> wherein R38 is C1-C4alkyl, C1-C4halogenalkyl, C3-or C4alkenyl, C3-or C4halogenalkenyl or C3-or C4alkinyl, and L is a leaving group, and subsequently performing if necessary oxidization and thionization.

The method described in the invention for the preparation of compounds of formula I is carried out in a manner analogous to known methods and comprises, for example, reacting a compound of formula III wherein R1, R2 and R3 are as defined under formula 1, and L4 is a leaving group, such as halogen, for example fluorine, chlorine or bromine, with a compound of Wol, Wo2, W03, W04, Dose Dose W07, W08, Won or W010 (Wo1o), wherein R1s to R39 and X6 to Xi9 are as defined under formula 1, if necessary in the presence of a suitable solvent and base, and if necessary subjecting the obtainable compounds of formula I (A =N-) to oxidation and thionization.

The method described in the invention for the preparation of compounds of formula 11 wherein R, and R2 are as defined under formula 1, W is a (Wg) or (Wlo) group; R21 to R30, R36 to R39, Xg to X12 and X17 to X19 are as defined under formula 1, and L4 is a leaving group, such as halogen for example, especially chlorine or bromine, is carried out in a manner analogous to known methods and comprises, for example, first oxidizing a compound of formula XXXIX in a suitable solvent to form a compound of formula XXXX wherein radicals Ri, R2 and W in the compounds of formulae XXXIX and XXXX have the meanings indicated, and then subjecting the compound either to a) halogenation, for example with phosphorus oxychloride, if necessary in the presence of a base and a suitable solvent, or b) transformation in an inert solvent in the presence of an anhydride or antimony pentachloride, and following aqueous treatment, to form a compound of XXXXI (so-called Katada reaction), and the halogenation of this compound if necessary in the presence of a base and a suitable solvent as described under variant a).

The above methods of preparation are explained in more detail in the following reaction schemes 1 to 12.

The preparation of a compound of formula I wherein R, to R3, A and W are as defined under formula 1, is explained in the following reaction scheme 1: Reaction scheme 1: Ri Ri \ CO (pressure), Pd or Ni R2 w catalyst, e. g. PdC12 (PPh3) 2, R2 < W N A a) R5-OH, base, solvent 4 3 III (R3 = COOR5, A=N) R1 R1 Olefin, Pd catalyst, e. g. -. ''W PdCl2 (PPh3) 2, tert. amine, R2/ solvant A solvent L4 (Heck reaction) R3 (Heck reaction) I (R3 = alkenyl, alkinyl, A=N) /Pi R Cyanidation, e. g. KCN, N COCH or [N (Cl-c4alkyl) 4 CN, A if necessary, solvent, 20-300°C I (R3 CN, A=N) R, R, R [0] e. g. H202 NH2C (O) NH2, R2/ W R2//W N Carboxylic acids anhydrides 2 N + Solvent Hal 4 II IV d) Ri 1) (CH3) 2NC (O) CI 2) Cyanidation, e. g. tA (CH3) 3SiCN, solvent R3 I (R3 = CN, A=N) The pyridine derivatives of formula 1, wherein R3 is a HOOC-or R500C group, may be prepared according to variant a) in reaction scheme 1 in a manner analogous to known <BR> <BR> <BR> methods, a useful method being to react for example the 6-halogen pyridine (L4 = halogen) of formula 11 in the presence of a palladium or nickel catalyst, such as a palladium triphenylphosphine complex (PdCi2 (PPh3) 2), with carbon monoxide under pressure in an autoclave, if necessary in the presence of an alcohol of formula V R5-OH (V) and a base, such as a trialkylamine, for example triethylamine.

According to variant b) in reaction scheme 1, pyridine derivatives of formula 1, wherein R3 is a Bi-C2-C8alkenyl, B,-C2-C8alkinyl or B2-C (R, 2) =CH group, are obtainable in a manner analagous to known methods, such as those described in"Transition Metals in Organic Synthesis", Editor S. Gibson, Oxford Press, 1997, for example starting from a 6-halogen pyridine of formula 11 (L4 = halogen) under the conditions of the Heck reaction with an olefin in the presence of a palladium catalyst, such as palladium (II) acetate (Pd (CH3COO) 2), a tertiary amine, such as triethylamine, and a solvent.

According to variant c) in reaction scheme 1, pyridine derivatives of formula 1, wherein R3 is a cyano group, are obtainable for example directly by reacting for example the 6-halogen pyridine of formula 11 (L4 = halogen) with a cyanidation reagent such as an alkali metal cyanide, for example potassium or sodium cyanide, a transition metal cyanide, for example copper cyanide, a tetraalkylammonium cyanide or trialkylsilyl cyanide, for example trimethylsilyl cyanide, in an inert solvent.

According to variant d) in reaction scheme 1, a reactivation for example of the 6-halogen <BR> <BR> <BR> <BR> pyridine of formula 11 (L4 = halogen) first takes place via oxidation to form the corresponding pyridine-N-oxide of formula IV and the reaction thereof with dimethylcarbamoyl chloride to form the reactive 1-carbamoyloxypyridinium salt. The following reaction of this pyridinium salt with a cyanidation reagen is carried out in a manner analogous to that described under c). Such cyanidation reactions are described for example in Heterocycles 22,1121 (1984), J. Org. Chem. 48,1375 (1983) and US-A-4 776 219.

Further derivatization of the pyridine derivatives of formula 1, primarily obtainable according to variants a) to d) in reaction scheme 1, wherein R3 is a carboxyl, alkoxycarbonyl, alkenyl or alkinyl, or cyano group, and A is nitrogen, can be readily accomplished, taking into account the chemical reactivities of the pyridyl and W parts (groups W, to W10), in a manner analogous to known standard methods, such as esterification, transesterification, hydrolysis, oxidative or reductive processes, or condensation reactions, for example the Wittig-Horner reaction. Such standard methods are described for example in WO 93/06090, EP-A-0 240 659 and in Houben-Weyl,"Methoden der Organischen Chemie", Vol. E1, Thieme Verlag Stuttgart, 1982.

The preparation of a compound of formula la wherein Ri, R2, R3, R1s, R16, R17, X6 and X7 are as defined under formula 1, is explained in the following reaction scheme 2.

Reaction scheme 2: R R -Ri CIC (X6) O-C-C4alkyl or NH3) (autoclave)- Vil N Solvent,-10-1800C N b) Oxalyl chloride or C (X6) C'2 N N s 2 R3 R3 base, solvent "3 3 III Vl R1 X6 Ris O C-C al k I X R R2 Nz O-cl-c4alkyl Cl-C4alkyl R, X7 R17 N H2N O. R3Vlil R17 R2<N R16 X N N or or Rs X6 H Base,solvent Ri Xi c)c) R-Lor R2 Xi ! Base, d) NH2-L solvent XIII 3 IX 8 ( Ri X7 R17 Thionization reacient, e. g. Ri X7 R17 Lawesson's reagent R2 >\/t N<R16<R2 <\\/) N > R16FN\ Ras N N Solvent N N R, s R3 Xs/R15 la (X7=S) la (X7 = °) For the preparation of the compounds of formula la according to the invention, many known standard methods are available, such as those described for example in EP-A-0 438 209 and DE-OS-19 604 229 (R16 = Cyano). In reaction scheme 2, a selection of suitable preparative processes is shown, wherein the choice of reaction pathways and reagents depends on the reactivities of the substituents in the intermediate stages.

Starting for example from a compound of formula 111, the aminopyridine of formula VI can be obtained by reacting with ammonia in an inert solvent, if necessary in an autoclave at temperatures from-10 to 180°C. This aminopyridine can be reacted in the presence of a base and a solvent either a) with a chloroformate of formula VII (X6 = O or S) to form a pyridyl carbamate of formula VIII, or b) with oxalyl chloride, phosgene (X6 =O) or thiophosgene (X6 =S) to form an iso (thio) cyanate of formula IX. Such reactions are described for example in Angew. 1971,407.

The carbamate and iso (thio) cyanate of formulae VIII and IX can be cyclized in the presence of the enamine derivative of formula X in an inert solvent to form the uracil derivative of formula XI, the reaction of the iso (thio) cyanate of formula IX being advantageously carried out in the presence of 0.1-1.5 equivalents of a base, for example sodium hydride, potassium tert-butylate or alkaline earth metal oxide or hydroxide, for example barium hydroxide.

The desired compounds of formula la can be prepared from the uracils of formula XI, according to standard methods, in the presence of an inert solvent and at least 1 equivalent of a base, for example an alkali metal carbonate such as potassium carbonate, c) with an alkylation agent of formula XII to form an N-alkyl derivative of formula la (R15=alkyl), or d) in analogy to WO 97/05116 with a hydroxylamine derivative of formula XIII, wherein L, is a leaving group such as HOS (0) 20-, , for example 2,4-dinitrophenylhydroxylamine or hydroxylamine-O-sulfonic acid, to form the N- amino derivative of formula la (R, 5 =amino). The desired thiono derivatives of formula la (X6, X7 =S) can be obtained by thionization, for example with phosphorus pentasulfide or Lawesson's reagent.

The preparation of a compound of formula Ib wherein Ri, R2, R3, R18, Rig, R20, and X8 are as defined under formula 1, is explained in the following reaction scheme 3.

Reaction scheme 3: Ri NH2NH2,- Ri Ri NH,,/=-\ solvent R3 III R3 XIV y-N 0 c R19 OR C or Br_Cw 0 ORl9 t or! AC brocs XV XVa X8 R C-C c-c Ri X8 R20 C-C alkyl-O'\\P (Ph) ß_ -XVIII R N R19 R2 NH C-Rl9 N N-N N=C lb Ra ra Via lob h 1) diazotization (preferably under exclusion of water) 2) O/Rs C Japp-Klingemann- reaction COOH Ris XVI RUZ b) R2 NH2 N R3 vi The compounds of formula lb can be prepared according to known methods, for example according to reaction scheme 3 (variant a)) by reacting a 2-halogen pyridine derivative of formula III (L4=halogen) with hydrazine, preferably in an amphiprotic solvent, such as alcools, by analogy with GB-A-2 230 261, to form the 2-hydrazino derivative of formula XIV.

This is reacted with a diketone of formula XV, by analogy with DE OS-19754348, or with a dihalogen ketone of formula XVa, by analogy with WO 97/07104, to form the hydrazone derivative of formula XVII.

Subsequent cyclization to the desired compound of formula Ib takes place in the presence of the phosphoran derivative of formula XVIII, if necessary in the presence of a base, for example 4-dimethylaminopyridine. If X8 = O in a compound of formula lb, then thionization can subsequently be carried out in a manner similar to that described under reaction scheme 2 (X8 = S).

According to reaction scheme 3, the hydrazone derivative of formula XVII can also be obtained from the 2-aminopyridine derivative of formula VI by means of diazotization, preferably under exclusion of water, and subsequent coupling with the keto acid of formula XVI (Japp-Klingemann reaction similar to that described under DE-OS-19754348)- (variant b) in reaction scheme 3).

The preparation of a compound of formula Ig wherein Ri, R2, R3, R31, R32, R33, and X14 are as defined under formula 1, is explained in the following reaction scheme 4.

Reaction scheme 4: R x14 i a) R 2 N O-Cl-c4alkyl x Ci-C4alkyl C-C4alkyl Rus Vllla 0'R R 31 R 32 1 R 31 0 or XIX H 32 ( Base, solve t 10 R 2 N R non Roi N XI b) R2 -N=C=X XX N Baste, R3 IXa solvent X13 R32 R x13 R32 R1 X13<R32 c) Alkylation e. g. R33-L R1 X13 R32 Rs XXI R Rsi Base, solvent , "33 R, X R 14 33 ! g (e. g. X=0) Thionization e. g. Lawesson's reagent Xt3 R32 R 31 '7-N eN I 14 33 X R Ig (e. g. X14 =S) Compounds of formula Ig can be prepared in a manner analogous to known methods, as described, for example, in EP-A-0 272 594, EP-A-0 493 323, DE-A-3 643 748, WO 95/23509, US-A-5 665 681 or US-A-5 661 109.

For example, according to reaction scheme 4, either a) a carbamate derivative of formula Villa in the presence of a solvent and a base, or b) an iso (thio-) cyanate of formula IXa, if necessary in a suitable solvent, can be cyclized with an amino acid derivative of formula XIX via a compound of formula XX in the presence of a base and a suitable solvent to form a compound of formula Ig.

For those cases (variant c)) where, in a compound of formula Ig, R33 is hydrogen and Xj3 and/or X14 are/is oxygen, alkylation can subsequently be carried out, if necessary with an alkylation reagent of formula XXI, on the free N-atom of the hydantoin ring and the ring carbonyl group then thionized (X, 3 and/or X14 = S).

The preparation of a compound of formula Ih wherein R1, R2, R3, R34, R35, X15, and X16 are as defined under formula 1, is explained in the following reaction scheme 5.

Reaction scheme 5: Ru 15 t a) R2 i R3 H NA 0'I-4 \OU R 3 1 R C-C4-Alkyl 35 0 or XXII or xxi I R2 NH \N Base, solvent I N\ x16 1 3 X15 b) R < N=C=X15 XXIII Base, R3 IXb solvent r Ri Alkylation e. g. R34-L, R35-L, or Ri X16 NR35 , i--N XXIVa XXIVb R2 /N R2 _/N v Michael acceptor, base N N\ N N solvent R3 34 x 15 R3 X15 R34 Ih (e. g. X15 = O) Ih Thionization e. g. Lawesson's reagent Ri X, s Ras N R2 N N R3 X, s Rsa <NfN,R3vDst5 34Ih (e. g. X15 = S) Compounds of formula Ih can be prepared in a manner analogous to known methods, as described for example in EP-A-0 210 137, DE-OS-2 526 358, EP-A-0 075 267 or EP-A-0 370 955.

For example, according to reaction scheme 5, either a) a carbamate derivative of formula Vlllb in the presence of a solvent and a base, or b) an iso (thio-) cyanate of formula IXb, if necessary in a suitable solvent, can be cyclized with a carbazate of formula XXII via a compound of formula XXIII in the presence of a base and a suitable solvent to form a compound of formula Ih.

For those cases (variant c)) where, in a compound of formula Ih, R34 and/or R35 are/is hydrogen and X, 5 and/or X16 are/is oxygen, alkylation can subsequently be carried out with an alkylation reagent of formula XXIVa or XXIVb on the free N-atoms and the ring carbonyl groups then thionized with a thionization reagent (X, 5 and/or X16 = S) For the preparation of compounds of formula Ih in reaction scheme 5, wherein R34 and R35 together form an alkylene bridge which is broken for example by-S (O) 2-, a compound of formula Ih, wherein R34 and R35 are hydrogen, can be reacted for example with an appropriate Michael acceptor, e. g. CH2=CH-S (0) 2CH3 or CH2=CH-S (O) 2-CH=CH2, and the resulting Michael addition products then functionalized.

The preparation of a compound of formula Ic wherein Ri, R2, R3, and R21 to R23 are as defined under formula 1, is explained in the following reaction scheme 6.

Reaction scheme 6: 0 0 RYR Ri R y R,, /'R,"1 - R2 xiv R3 R21 R22 N N O O Ic O O Ic b) L29 R23 R22 s, XXVa RI Ri z R Halogenation reagent e. g. N R POLI3 R3 O R22 R3 R R22 21 o R p, XXV Ic (R21 = halogen) According to reaction scheme 6, the pyrazol compounds of formula Ic can be prepared e. g. either from the hydrazinopyridine derivatives of formula XIV by means of condensation with a 1,3-dicarbonyl derivative of formula XXV (variant a)), or by means of condensation with a B-carbonylcarboxylic acid derivative of formula XXVa, where L2 is a leaving group, such as C1-C4alkoxy, hydroxy or halogen, for example chlorine or bromine (variant b)), and subsequent treatment of the resulting pyridylpyrazolone derivative of formula XXVI with a halogenation agent, for example phosphorus oxychloride (R2, =halogen). The two reaction steps a) and b) in reaction scheme 6 are carried out if necessary in the presence of an acidic, basic or bifunctional catalyst, such as p-toluenesulfonic acid.

The compounds of formula Ic obtained in this way can be further functionalized using standard methods according to the definition of substituents R21 to R23.

Compounds of formula Ic in reaction scheme 6, wherein R22 is hydrogen, can be further functionalized according to the definition of R22, e. g. using an electrophilic reagent, for example a halogenation agent, such as an elementary halogen or sulfurylhalogenide, to form the corresponding compounds of formula Ic, wherein R22 is halogen, or using a nitrating agent such as nitric acid in a mixture with a further strong acid, such as sulfuric acid, to form the corresponding compounds of formula Ic, wherein R22 is nitro.

The preparation of a compound of formula Id wherein Ri, R2, R3, and R24 to R26 are as defined under formula 1, is explained in the following reaction scheme 7.

Reaction scheme 7: 0 0 Ria Ras R2s N R2 \ N N R3 XIV R3 R26 R3 XIV R3 R24 R26O O Id b) 0 0! d R2s k R26 fl r XXVc Ri R2s R'R25 R2 N'Halogenatione N POCI3 or SOCI2 N R2s R3XXVia0 R24 R26 Id (R24= halogen) M (CN) s , j, xxvn XXVN Id (R24= CN) According to reaction scheme 7, the tetrahydroindazol compounds of formula Id can be obtained by known methods from the hydrazinopyridine derivatives of formula XIV, for example either by means of condensation with a cyclohexanone derivative of formula XXVb acylated in the 2-position, wherein R24 is as defined under formula 1, except where R24 is halogen or cyano (variant a)), or by means of condensation with a cyclohexanone derivative <BR> <BR> of formula XXVc, wherein L2 is a leaving group, such as C1-C4alkoxy, hydroxy or halogen, for example chlorine or bromine, and subsequent halogenation (variant b)) in a manner analogous to that described under reaction scheme 6.

The halogen derivatives of formula Id, wherein R24 is halogen, can be reacted according to known methods with an alkali metal, ammonium or metal cyanide, wherein the metal ion is selected from the first or second subgroup of the periodic system, if necessary with the addition of an alkali metal iodide, to form the corresponding cyano-substituted derivatives pf formula Id (R24=CN).

The preparation of compounds of formulae le and If wherein Ri, R2, R3, R27 to R3o and Xg to X12 are as defined under formula 1, is explained in the following reaction scheme 8.

Reaction scheme 8: Ri X R24XNßR28 I R2s N y R-N R2s 2 r i Solvent, propionic acid, , 20-2oo°c Rz 0 R3 XXV!! i., Y y . te (Xg, X=0) R2-\ y-NH, 9/P R1 R R1 R2 NH2 N Ras VU Solvent, propionic acid, 2 20-200°C R3 Xi i R30 XXVllla If (X11, X12=O) According to reaction scheme 8, the pyrrolindione derivatives of formula le and the tetrahydroisoindolindione derivatives of formula If can be obtained in a manner analogous to known methods, for example by reacting an anhydride of formula XXVIII (variant a)) and/or XXVllla (variant b)) with an aminopyridine of formula VI in an inert solvent, such as ether, for example dioxan, or a lower alkylcarboxylic acid, for example propionic acid, at temperatures of 20-200°C.

The compounds of formulae le and If (X9 to X12 = O) which are obtainable according to reaction scheme 8 can be thionized if necessary with a suitable sulfur reagent (X9 to X12 = S).

The preparation of a compound of formula li wherein R1, R2, R3, R36, R3,, X", and X, 8 are as defined under formula 1, is explained in the following reaction scheme 9.

Reaction scheme 9: R1 /1Q /''0 a) R2 >--NH-ll-OC-C4-Alkyl Xia R3 VI I Ic R3NH-NHR3s NHR3 Nu Souvent, R'base R N R36 /riQ b) N=C=Xl8 N Solvent, L3 R3 base IXc L3 XXXI Ri N N~N if N N-N R3/Ro36 R37 li According to reaction scheme 9, compounds of formula li can be prepared by known methods, for example by first reacting a carbamate of formula Vlllc (variant a)) and/or an isothiocyanate of formula IXc (variant b)) with a hydrazine derivative of formula XXIX to form the semicarbazide derivative of formula XXX, and then cyclizing this derivative in the presence of a carbonylation or thiocarbonylation reagent of formula XXXI. Both reaction steps are usefully accomplished in a suitable solvent and in the presence of a base. A suitable (thio) carbonylation reagent of formula XXXI is for example phosgene, diphosgene, thiophosgene or carbonyldiimidazol. L3 in a compound of formula XXXI is therefore a leaving group such as a halogen, for example, chlorine or bromine, trichloromethoxy or The preparation of a compound of formula Ik wherein Ri, R2, R3, R38, R39, and X19 are as defined under formula 1, is explained in the following reaction scheme 10.

Reaction scheme 10: Ri Ri a) 9-aorc-\ Rcox, L.- mtW ,/\-"39 XXXW./' Catalyste. g. Hd a CaMyste. 9. HC! o, 2 \\//mUt-) \ \-N piduenesulfonicadd \ N COOH N N, R/R3/X R33 XIII Ik (X19=O, R33 =H) I %-t, base OC,-Ca ! kyt (Lawesson's reagent R b) y, cooc, c, ay R R ) N N axvi- Ras ;, N Ras R 2 NHNH 2 R 2 N xxxv P'R N N N/N. «, sN. R//R33////R 3 xiv 3 9 3 xig Ik (X9=O, R =H) IkXis=S R3e) TR, base LaMMon-fteagens C) l) R,.-CHO R m z> nn rrem o y e. s. rraoa N Y Ras 2 N-N : CHR3. 2 N' ekadd e. g. N CpNH2 38 N CONH 2 R Ik (X19=O, R38=H) According to reaction scheme 10, the triazolone derivatives of formula Ik can be prepared in a manner analogous to known methods, starting for example from the hydrazinopyridine derivative of formula XIV, which according to variant a) is usefully reacted with a keto acid of formula XXXII in the presence of an acid catalyst, such as a lower alkylcarboxylic acid, for example propionic acid, a mineral acid, for example sulfuric acid or hydrochloric acid, or a sulfonic acid, for example p-toluenesulfonic acid, to form a hydrazone derivative of formula XXXIII. This can subsequently be cyclized with an azide of formula XXXIV to form a triazolone derivative of formula Ik, wherein X19 is oxygen, and R38 is hydrogen, and then further derivatized if necessary according to standard methods using an alkylation reagent of formula XXXV or a sulfur reagent.

According to variant b), the hydrazinopyridine derivative of formula XIV can be cyclized with an iminoether of formula XXXVI to form a triazolone derivative of formula Ik, wherein Xlg is oxygen, and R38 is hydrogen, and then if necessary alkylated or thionized as described under variant a).

According to variant c) in reaction scheme 10, the hydrazinopyridine derivative of formula XIV can be reacted first with an aldehyde of formula XXXVII and then, in the presence of a lower alkylcarboxylic acid, such as acetic acid, with an alkali metal cyanate to form a compound of formula XXXVIII which, if necessary, is not isolated, and finally cyclized with an oxidizing agent, such as alkali metal hypochlorite (Javelle) to form a compound of formula Ik, wherein Xlg is oxygen, and R38 is hydrogen. If necessary, the resulting compound of formula Ik can be alkylated or thionized, as described under variant a).

In certain cases, compounds of formula I can also be usefully obtained in a manner analogous to that described in J. Het. Chem. 15,1221 (1978) by the substitution of a 2- halogen pyridine of formula III (L4=halogen), if necessary in the presence of a suitable solvent and a base, with the desired heterocycles of formulae Woi to W010 or (Woio), or alkali metal salts thereof, as illustrated with the example of a compound of formula Ic in reaction scheme 11.

Reaction scheme 11: Rot R , R s ou Nez .. .., _ R2 -W Na+ N R2s R2 L4 o R2 N/ , N Solvent, base-N R3 R22 R3 R3 R21 III IN The intermediate products of formula 11 wherein R, and R2 are as defined under formula 1, L4 is a leaving group, such as halogen or<BR> C1-C4alkyl or phenylsulfonyl, and W is a W3, W4, W5, W6, Wg or W10 group, are new. The invention thus also relates to these compounds.

The preparation of compounds of formula 11 is explained in reaction scheme 12.

Reaction scheme 12: R1 R'R Ri [0]: e. g. 4 Haiogenation e. g. R R2W R W POC13 or POBr3,- N 2 2 2 2/N+ if necessarysoivent, 2 t/gw Solvant, XXXIX carboxylic acids/p anhydrides XXXX La 11(L4=halogen) 1) Anhydride, solvent 2) H20, Katada reaction R1 Ri Halogenation e. g. POC13 or POBr3, if necessary solvent, base HO L4 XXXXI XXXXll (L4=halogen) The pyridin-N-oxides of formula XXXX (reaction scheme 12) can be prepared according to known methods, such as described in Org. Synth. 4,828 (1963); ibid. 3,619 (1955); US-A- 3 047 579; and B. Iddon and H. Suschitzky in"Polychloroaromatic Compounds", Editor H.

Suschitzky, Plenum Press, London 1974, page 197, a useful method being to react the pyridine derivatives of formula XXXIX with oxidizing agents, such as organic peroxy acids, for example m-chioroperbenzoic acid, peracetic acid and pertrifluoracetic acid, or aqueous hydrogen peroxide solution or hydrogen peroxide urea adduct together with carboxylic acids and/or carboxylic acid anhydrides, or inorganic peroxy acids, for example peroxymonosulfuric acid (Caro's acid).

Suitable solvents are, for example, water, organic acids such as acetic acid and trifluoracetic acid, halogenated hydrocarbons such as dichloromethane and 1,2- dichloroethane, esters such as ethyl acetate, ethers such as tetrahydrofuran and dioxan or mixtures comprising these solvents. The reaction temperatures lie within the range of-20°C to 100°C, depending on the solvent or solvent mixture used.

The pyridin-N-oxides of formula XXXX can be halogenated either directly according to known methods, for example with phosphorus oxychloride, phosphorus oxybromide, sulfuryl chloride, thionyl chloride or phosphorus pentachloride in phosphorus oxychloride to form the <BR> <BR> <BR> halogen pyridine derivatives of formula 11 (L4 = halogen), or first reacted-likewise according to known methods (e. g. Quart. Rev. 10,395 (1956); J. Am. Chem. Soc. 85,958 (1963); and J. Org. Chem. 26,428 (1961))-in the presence of anhydrides, for example acetic anhydride, trifluoracetic anhydride and methanesulfonic acid anhydride in a suitable inert solvent, such as halogenated hydrocarbons, for example dichloromethane and 1,2- dichloroethane, amides such as N, N-dimethylformamide and 1-methyl-2-pyrrolidone and if necessary in the presence of sodium acetate, to form the pyridol derivatives of formula XXXXI, which can then then be halogenated to form halogen pyridines of formula 11, as described above for compounds of formula XXXX (L4 = halogen).

The reaction temperatures for this transformation reaction generally lie within the range of -30°C to 80°C. By analogy with Tetrahedron 37,187 (1981), antimony pentachloride (Katada reaction) presents itself as a further variant for the above transformation reaction.

The method described in the invention for the preparation of compounds of formula 11 wherein R, and R2 are as defined under formula 1, W is a W, to W, o group, and L4 is a Cl- C4alkyl or phenylsulfonyl group, is carried out starting from a compound of formula 11, wherein Ri, R2 and W have the meanings indicated and L4 is halogen, by means of reaction with a Ci-C4a ! ky) or phenyl thiol in the presence of a suitable base, followed by oxidation of the resulting thioether with an oxidizing agent such as hydrogen peroxide or m- chloroperbenzoic acid.

The starting compounds of formula XXXIX used in reaction scheme 12 can be prepared in a manner analogous to the methods described for compounds of formula la to Ik (R3=hydrogen) under reaction schemes 2 to 11.

The compounds of formulae III and Vi are known or can be prepared according to known methods, as described in DE-A-3 917 469; WO 97/07114; WO 92/00976; JP-A-58-213 776; EP-A-0 012 117; EP-A-0 306 547; EP-A-0 030 215; EP-A-0 272 824; EP-A-0 500 209; US-A-4 996 323; US-A-5 017 705; WO 97/05112; J. Het. Chem. 11,889 (1974); J. Het. Chem 21,97 (1984); Tetrahedron 41,4057 (1985); Heterocycles 22,117; Synth. 1988,938; J. Med.

Chem. 25,96.

The 2-aminopyridines of formula VI can in addition be prepared by Curtius, Hofmann or Lossen reactions from corresponding pyridine derivatives with carboxylic acid, carboxylic acid chloride, carboxylic acid azide, carboxylic acid ester or carboxylic acid amide functions in Position 2.

The reagents of formulae V, VII, X, XII, XIII, XV, XVa, XVI, XVIII, XIX, XXI, XXII, XXIVa, XXIVb, XXV, XXVa, XXVb, XXVc, XXXIV, XXVIII, XXVllla, XXIX, XXXI, XXXII, XXXIV, XXXV, XXXVI and XXXVII as used in reaction schemes 1 to 10 are either known or can be prepared in a manner analogous to disclosed methods.

The heterocycles of formulae Wo, to Wolo are either known or can be prepared in a manner analogous to known standard methods of heterocyclic chemistry.

The reactions for obtaining the compounds of formula I are advantageously carried out in aprotic inert organic solvents. Such solvents are hydrocarbons such as benzene, toluene, xylene or cyclohexane, chlorinated hydrocarbons such as dichloromethane, trichloro- methane, tetrachloromethane or chlorobenzene, ethers, including diethyl ether, 1,2- dimethoxyethane, diglyme, tetrahydrofuran or dioxane, nitriles such as acetonitrile or propionitrile, amides such as N, N-dimethyl formamide, diethyl formamide or N-methyl- pyrrolidinone. The reaction temperatures are preferably in the range from-20° to +120°C.

The reactions are usually slightly exothermic and can as a rule be carried out at room temperature. The reaction mixture can be heated for a brief time to boiling point to shorten the reaction time or also to initiate the reaction. The reaction times can also be shortened by addition of a few drops of a base as reaction catalyst. Particularly suitable bases are tertiary amines such as trimethylamine, triethylamine, quinuclidine, 1,4-diazabicyclo [2.2.2] octane, 1,5-diazabicyclo [4.3.0] non-5-ene or 1,5-diazabicyclo [5.4.0] undec-7-ene. Further suitable bases are also inorganic bases, typically hydrides such as sodium or calcium hydride, hydroxides such as sodium and potassium hydroxide, carbonates such as sodium and potassium carbonate, or hydrogencarbonates such as potassium and sodium hydrogencarbonate.

The compounds of formula I can be isolated in conventional manner by concentrating the reaction mixture and/or removing the solvent by evaporation and by recrystallizing or triturating the solid residue in a solvent in which it is not readily soluble, typically an ether, an aromatic hydrocarbon or a chlorinated hydrocarbon, or by means of column chromatography and a suitable eluent.

The compounds of formula I or compositions containing them may be used according to this invention by all standard methods of application used in agriculture, including preemergence application, postemergence application and seed dressing, as well as by different methods and techniques such as controlled release. For controlled release, a solution of the herbicide is applied to mineral granular carriers or to polymerized granules (urea/formaldehyde) and then dried. A coating can then be additionally applied (coated granules) that allows the herbicide to be released at a controlled rate over a specific period of time.

The compounds of formula I may be used as herbicides in unmodified form, i. e. as obtained in the synthesis. Preferably they are processed in conventional manner with the auxiliary agents customarily employed in formulation technology, e. g. to emulsifiable concentrates, directly sprayable or dilutable solutions, dilute emulsions, wettable powders, soluble powders, dusts, granulates or microcapsules. Such formulations are described, for example, in WO 97/34485 on pages 9 to 13. As with the type of agents, the methods of application such as spraying, atomizing, dusting, wetting, scattering or pouring, are selected in accordance with the intended objectives and the prevailing circumstances.

The formulations, i. e. the agents, preparations, or compositions containing the compound of formula I or at least one compound of formula I and usually one or more than one liquid or solid formulation assistant, are prepared in known manner, e. g. by homogeneously mixing and/or grinding the herbicide with said formulation auxiliaries, typically solvents or solid carriers. Surface-active compounds (surfactants) may additionally be used for preparing the formulations. Examples of solvents and solid carriers are described in WO 97/34485 on page 6.

Depending on the herbicide of formula I to be formulated, suitable surface-active compounds are nonionic, cationic and/or anionic surfactants and surfactant mixtures having good emulsifying, dispersing and wetting properties.

Examples of suitable anionic, non-ionic, and cationic surfactants are listed in WO 97/34485 on pages 7 and 8. <BR> <BR> <BR> <BR> <P>Also the surfactants customarily employed in the art of formulation and described, inter alia, in"McCutcheon's Detergents and Emulsifiers Annual"MC Publishing Corp., Ridgewood New Jersey, 1981, Stache, H.,"Tensid-Taschenbuch" (Handbook of Surfactants), Carl Hanser Verlag, Munich/Vienna, 1981, and M. and J. Ash,"Encyclopedia of Surfactants", Vol 1-111, Chemical Publishing Co., New York, 1980-81 are suitable for manufacture of the herbicides according to the invention.

The herbicidal compositions will as a rule contain from 0.1 to 99 % by weight, preferably from 0.1 to 95% by weight, of herbicide, from 1 to 99.9% by weight, preferably from 5 to 99.8 % by weight, of a solid or liquid adjuvant, and from 0 to 25% by weight, preferably from 0.1 to 25% by weight, of a surfactant. Whereas it is preferred to formulate commercial products as concentrates, the end user will normally use dilute formulations. The compositions may also contain further ingredients, such as: stabilisers, e. g. where appropriate epoxidized vegetable oils (epoxidized coconut oil, rapeseed oil, or soybean oil); antifoams, typically silicone oil; preservatives; viscosity regulators; binders; and tackifiers; as well as fertilizers or other chemical agents.

The compounds of formula I are usually applied with success to the plants or the locus thereof in concentrations of 0.001 to 4 kg/ha, especially 0.005 to 2 kg/ha. The concentration required to achieve the desired action can be determined by experimentation. It will depend on the type of action, the development stage of the cultivated plant and of the weed, as well as on the application (locus, time, method), and as a result of these variables can vary over a wide range.

The compounds of formula I have excellent herbicidal and growth inhibiting properties, which make them suitable for application in crops of cultivated plants, especially in cereals, cotton, soybeans, sugar beet, sugar cane, plantations, rape, maize, and rice, and for the non-selective control of weeds. Crops will also be understood as meaning those crops that have been made tolerant to herbicides or classes of herbicides by conventional breeding or genetic engineering methods. The weeds to be controlled may be monocot as well as dicot weeds, typically Stellaria, Nasturtium, Agrostis, Digitaria, Avena, Setaria, Sinapis, Lolium, Solanum, Echinochloa, Scirpus, Monochoria, Sagittaria, Bromus, Alopecurus, Sorghum halepense, Rottboellia, Cyperus, Abutilon, Sida, Xanthium, Amaranthus, Chenopodium, Ipomoea, Chrysanthemum, Galium, Viola, and Veronica.

The invention is illustrated by the following non-limitative Examples.

Preparative Examples: Example H1: Preparation of 2-N-ethoxicarbonylamino-3-fluoro-5-chloropyridine 294 g 2-Amino-3-fluoro-5-chloropyridine is dissolved in 1 I dry pyridine and cooled to 0°C, then 220 g ethyl chloroformate is stirred in drop by drop and stirring continued at 22°C until the reaction is complete. The reaction mixture is then poured onto ice water, adjusted to pH 4-5 with 2N hydrochloric acid and extracted with ethyl acetate. The combined extracts are washed with water, dried over sodium sulfate, concentrated by evaporation and crystallized by the addition of n-hexane. The precipitate obtained is filtered off, washed with n-hexane and dried in a vacuum. The title compound is obtained with a melting point of 132°C. Example H2: Preparation of 1- (3-fluoro-5-chloropyridin-2-yl)-3-methyl-4-trifluoromethyl- pyrimidin-2, 6-dione Under a nitrogen atmosphere, while cooling and stirring, a solution of 22.7 g 4,4,4-trifluoro- 3-amino-2-butenoic acid ethyl ester is added dropwise to 5.1 g of a sodium hydride dispersion (60%) in 60 ml N-methylpyrrolidine at 0-5°C and stirred at 22°C until hydrogen evolution is complete. Then 23.7 g 2-ethoxicarbonylamino-3-fluoro-5-chloropyridine (Example H1) is added and the reaction mixture heated for about 5 hours to 120°C. The mixture is then cooled, 16.7 g methyl iodide is added dropwise and stirring is continued overnight at 22°C. After the reaction mixture has been taken up in ethyl acetate, it is washed with ice water, dried over sodium sulfate, filtered, and concentrated by evaporation.

The residue obtained is recrystallized from ethyl acetate/n-hexane. The title compound is obtained with a melting point of 133-134°C.

Example H3: Preparation of 1- (3-fluoro-5-chloro-2-pyridyl-N-oxide)-3-methyl-4-trifluoro- methylpyrimidin-2,6-dione 24 g 1- (3-Fluoro-5-chloropyridin-2-yl)-3-methyl-4-trifluoromethylpy rimidin-2, 6-dione (Example H2) in 150 mi dichloromethane is cooled to-5°C, and 2 g hydrogen peroxide-urea adduct is added. Then 2.7 ml trifluoracetic acid anhydride, dissolved in 2 ml dichloromethane, is added dropwise and the reaction mixture is stirred overnight after the exothermic reaction has subsided. Within 3 hours another 5 g of hydrogen peroxide-urea adduct and 3 ml trifluoracetic acid anhydride are added in 2 portions and, after the exothermic reaction has subsided, the mixture is heated to 25-35°C until the reaction is complete. The mixture is then cooled and, at-5°C, is adjusted to pH 7.5 first with 2N sodium hydroxide solution, then with saturated sodium hydrogencarbonate solution, distributed between dichloromethane and ice water, and the separated organic phase dried over sodium sulfate, filtered and concentrated by evaporation. The remaining solid residue is recrystallized from ethyl acetate/n-hexane. The desired title compound is obtained with a melting point of 142-143°C.

Example H4: Preparation of 1- (3-fluoro-5.6-dich loro-2-pyridyl)-3-methyl-4-trif luoromethyl- pyrimidin-2.6-dione To a solution of 2.4 ml phosphorus oxytrichloride in 20 ml 1,2-dichloroethane, heated to 70°C, portions of 6.8 g 1- (3-fluoro-5-chloro-2-pyridyl-N-oxide)-3-methyl-4-trifiuorome thyl- pyrimidin-2,6-dione (Example H3) are added, maintained at this temperature overnight, before a further 4.0 ml phosphorus oxytrichloride is added and heated for 20 hours. The mixture is then cooled, poured over ice water, extracted with dichloroethane, and the combined extracts are washed with 2N sodium hydroxide solution and water, dried over sodium sulfate and evaporated by concentration. The residue is purified by means of silica gel chromatography (eluent: hexane/ethyl acetate 9/1). The title compound is obtained with a melting point of 113-115°C.

Example H5: Preparation of 1- (2-hydroxy-3-chloro-5-fluoropyridin-6-yl-3-methyl-4- trifluoromethylpyrimidin-2,6-dione and 1- 3-hydroxy-2-chloro-5-fluoropyridin-6-yl)-3-methyl-4- trifluoromethylpyrimidin-2,6-dione To a solution of 29.6 g 1- (3-fluoro-5-chloro-2-pyridyl-N-oxide)-3-methyl-4-trifluorome thyl- pyrimidin-2,6-dione (Example H3) in 400 ml dimethylformamide, cooled to-30°C, 182 g trifluoracetic acid anhydride is added dropwise, and the mixture is then stirred overnight at -30°C, and on the next day at 22°C. In a vacuum, the mixture is then liberated from surplus trifluoracetic acid anhydride, cooled to-5°C and carefully neutralized first with diluted sodium hydroxide solution and then with sodium hydrogencarbonate solution. After the addition of ice water, the mixture is extracted with ethyl acetate, and the combined extracts are washed with water and dried over sodium sulfate. This is then filtered, the filtrate concentrated by evaporation and the resulting residue purified over a silica gel column (eluent: n-hexane/ethyl acetate 8/2) with an ascending gradient in respect of ethyl acetate. The title compound is obtained with a melting point of 200-202°C.

In addition, a fraction is obtained which, besides 1-(2-hydroxy-3-chloro-5-fluoropyridin-6-yl)- 3-methyl-4-trifluoromethylpyrimidin-2, 6-dione, comprises also the isomer 1- (3-hydroxy-2- chloro-5-fluoropyridin-6-yl)-3-methyl-4-trifluoromethylpyrim idin-2,6-dione. The latter isomeric compound is obtained by a further rearrangement reaction. The ratio of the two isomers 1- (2-hydroxy-3-chloro-5-fluoropyridin-6-yl)-3-methyl-4-trifluo romethylpyrimidin-2,6-dione and 1- (3-hydroxy-2-chloro-5-fluoropyridin-6-yl)-3-methyl-4-trifluo romethylpyrimidin-2,6-dione varies (at approx. 3: 1) depending on reaction conditions.

The isomeric mixture of the fraction can either be used directly for the next reaction step or separated by means of HPLC (Li-Chrospher Si60; eluent: ethyl acetate/hexane 15/85 to 30/70, ascending gradient of ethyl acetate). Pure 1- (3-hydroxy-2-chloro-5-fluoropyridin-6- yl)-3-methyl-4-trifluoromethylpyrimidin-2, 6-dione is obtained with a melting point of 189- 192°C.

Example H6: Preparation of 1- (6-Ethoxicarbonyl-5-chloro-3-fluoropyridin-2-yl)-3-methyl-4- trifluoromethylpyrimidin-2,6-dione A mixture of 4 g 1- (3-fluoro-5, 6-dichloro-2-pyridyl)-3-methyl-4-trifluoromethyipyrimidin-2, 6- dione (Example H4), 3.4 g triethylamine and 2 g dichloro-bis (triphenylphosphine) palladium in 50 ml ethanol is pressurized in an autoclave with carbon monoxide at 180 bar and the mixture heated for about 30 hours to 101°C, leading to a pressure build-up of max. 228 bar.

The heating is then switched off, the reaction mixture left to stand at 22°C over the weekend and filtered; the filtrate is then concentrated by evaporation in a vacuum, and the residue obtained is purified over a silica gel column (eluent: n-hexane/ethyl acetate 9/1).

The desired title compound is obtained as a yellowish resin; Example H7: Preparation of 1- (2-trifluoromethyl-3-chloro-5-fluoropyridin-6-yl)-3-methyl-4 - trifluoromethylpyrimidin-2,6-dione To a solution of 0.848 g of a mixture of 2-hydroxy-3-chloro-5-fluoropyridin-6-yl)-3-methyl-4- trifluoromethylpyrimidin-2,6-dione and 3-hydroxy-2-chloro-5-fluoropyridin-6-yl)-3-methyl-4- trifluoromethylpyrimidin-2,6-dione (Example H5), 0.938 g triphenylphosphine, 0.22 ml 2,2,2- trifluoroethanol and 0.58 ml diethylazodicarboxylate are added at 22°C, and the mixture is stirred for 14 hours at 22°C. The same quantities of triphenylphosphine, diethylazo- dicarboxylate and trifluoroethanol are added and the mixture is stirred for a further 4 hours.

Ice water is then added, distributed between dichloromethane and water, the extracts washed with water, dried and concentrated by evaporation. The residue is first filtered via silica gel (hexane/ethyl acetate 2/1) and then separated by means of HPLC (Li-chrospher Si 60; hexane-ethyl acetate 15-30%, ascending gradient).

After the separation of 1- (2-trifluoroethoxy-3-chloro-5-fluoro-6-pyridyl)-3-methyl-4- trifluoromethylpyrimidin-2, 6-dione and 1- (3-trifluoroethoxy-2-chloro-5-fluoro-6-pyridyl)-3- methyl-4-trifluoromethylpyrimidin-2,6-dione, the desired title compound is obtained with a melting point of 112-113°C.

By analogy, these and analogous trifluoromethyl compounds are obtainable as described in JP-A-58 206 563 or by the reaction of corresponding carboxylic acid derivatives with sulfur tetrafluoride or by the reaction of corresponding trichloromethyl compounds with hydrogen fluoride.

Example H8: Preparation of tetrahydroimidazofl, 5-alpyridin-1,3-dione A reaction vessel containing 260 mi water is prepared with 34.6 g (0.193 mol) 2-piperidine- carboxylic acid methyl ester hydrochloride, to which 17.4 g (0.216 mol) potassium cyanate is then added. Then 30 ml glacial acetic acid is added and the resulting homogeneous solution is stirred for 4.5 hours at 22°C. The reaction solution is subsequently saturated with saline (NaCI) and extracted twice with 200 ml tert-butyl methyl ether each time. The organic fractions are combined, dried over sodium sulfate and concentrated. As residue, 11 g of a viscous oil is obtained, from which crystals precipitate out overnight. Decanting off the remaining oil enables the crystals to be separated off and isolated by trituration (digestion) in diethyl ether. The desired title compound is obtained with a melting point of 122-123°C in a yield of 5. 75 g.

Example H9: Preparation of 2- (3-fluoro-6-chloro-5-cyano-2-pyridyl) tetrahydroimidazo [1, 5- a] pyridin-1,3-dione A reaction vessel is prepared with 0.77 g (0.005 mol) of the hydantoin derivative from Example H8 in 50 ml acetonitrile. To this solution, 0.95 g (0.00688 mol) finely pulverized potassium carbonate and 0.96 g (0.00503 mol) 2,6-dichloro-3-cyano-4-fluoropyridine are added consecutively, and the mixture is stirred and heated to reflux temperature for 5 hours. At the end of this time, no further starting compound is detectable (TLC analysis).

The reaction mixture is cooled, filtered, and the solvent evaporated off. The dark brown, viscous oil obtained is chromatographed under pressure over a silica gel column (30 g) (eluent: hexane/ethyl acetate 2/1). The fractions comprising product with an Rf value of 0.26 are combined and liberated from the solvent. The desired product is obtained as white crystals with a melting point of 192-193°C. MS (FD): [M+, 40%] 308.

Example H10: Preparation of 2- (5-chloro-3-fluoropyridin-2-yl)-7-hydroxytetrahydroimidazo- (1.5-a)-pyridin-1,3-dione A reaction mixture comprising 100 ml dioxan, 50 ml N, N-dimethylformamide, 8 mi propylene oxide, 6 ml 0)-undec-7-en and 8.0 g 4-hydroxypiperidine-2-carboxylic acid ethyl ester hydrochloride is stirred overnight at 20°C. Then 4.4 g potassium tert- butylate and 50 ml N, N-dimethylformamide are added and the resulting suspension is heated for about 4 hours to 95°C. The reaction mixture is then cooled, adjusted to pH 6.5- 7.0 with cold, aqueous 2N hydrochloric acid solution and extracted with ehyl acetate. The combined extracts are washed with saline solution and water, concentrated by evaporation and the solid residue purified by means of silica gel chromatography (eluent: hexane/ethyl acetate). The title compound is obtained as a mixture of two separable diastereomers with a melting point of 183-185°C and 184-186°C.

Example H11: Preparation of 2- (5-Chloro-3-fluoro-pyridine-2-yl)-7-fluoro-tetrahydroimidazo - (1.5-a)-pyridine-1,3-dione 2.6 g of 2- (5-Chloro-3-fluoro-pyridine-2-yl)-7-hydroxi-tetrahydroimidaz o- (1.5-a)-pyridine-1,3- dione (isomer B) in 80 mi dichlorromethane is treated at-55°C--65°C with 1.9 ml of diethylaminosulfur trifluoride (DAST) and stirred at the same temperature for 1 hr. The vessel is then allowed to stirr at room temperature over night. The resulting brownish solution is treated with ice and water and extracted with ethyl acetate. The extracts are washed with water, dried, filtered through a small siligcagel column and evaporated to give the desired product with m. p. 154-157°C.

Example H12: Preparation of 2- (6-ethoxycarbonyl-5-chloro-3-fluoro-pyridin-2-yl)-5- trifluoromethyl-2. H.-pyridazin-3-one (compound 35.004) A mixture of 1.7 g 2- (5, 6-dichloro-3-fluoropyridin-2yl)-5-trifluoromethyl-2. H.-pyridazin-3-one, 1 g of bis- (triphenylphosphine)-palladium (Il)-dichloride, and 2.3 ml triethylamine in 35 ml ethanol was placed in an autoclave and heated under a pressure of 180-235 bar of carbon monoxide at 100°C for 24 hrs. Then, the reaction mixture was cooled down, filtered end evaporated. Purification of the residue by HPLC-chromatography (ethyl acetate-hexane) led to the desired product. 'H-NMR (CDCI3): 8. 11 ppm (s, 1 H); 7.80 ppm (d, 1 H); 7.35 ppm (s, 1 H); 4.46 ppm (q, 2H); 1.41 ppm (t, 3H).

In an analogous manner, 2- (6-ethoxycarbonyl-5-chloro-3-fluoro-pyridin-2-yl)-4-methyl-5 - trifluoromethyl-2. H.-pyridazin-3-one (39.004) was obtained.

Example H13: Preparation of 2-(5, 6-dichloro-3-fluoro-pyridin)-2-yl-4-methyl-5-trifluoromethyl - 2. H.-pyridazine-3-one A mixture of 1.6g 2- (5-chloro-3-fluoro-l-oxy-pyridin-2-yl)-4-methyl-5-trifluorom ethyl-2H- pyridazin-3-one and 2 ml of phenyl dichlorophosphate was heated in a sealed tube at 140°C for 3 hrs. The reaction was then cooled, poured into ice and water, neutralised with aqueous sodium hydrogen carbonate, extracted with ethyl acetate, washed with water and dried over sodium sulfate. After dilution with hexane, the extract was filtered through silicagel and evaporated to give the desired product with m. p. 96-98°C.

Example H14: Preparation of 2- (5-chloro-3-fluoro-1-oxy-pyridin-2-yl)-4-methyl-5- trifluoromethyl-2H-pyridazin-3-one (compound 625.001) 5.01 g of 2- (5-chloro-3-fluoro-pyridin-2-yl)-4-methyl-5-trifluoromethyl- 2H-pyridazin-3-one in 150 ml of 1,2-dichloroethane was treated at 0°C with 2.1g hydrogen peroxide-urea adduct and 2.7 mi of trifluoroacetic anhydride and allowed to stir at 20°C until conversion was complete. Then the solution was poured into ice and water, neutralised with aqueous sodium hydrogen carbonate and extracted with dichloromethane. The extracts were combined, washed with water, dried, filtered and evaporated to give the desired product with m. p. 140-143°C.

Example H15: Preparation of 2-(5-chloro-3-fluoro-pyridin-2-yl)-4-methyl-5-trifluoromethy l- 2H-pyridazin-3-one (608.001) A solution of 8.09g 3 ( luoro-pyridine-2-yl)-hydrazono)-1,1,1-trif luoro-propan-2- one and 11.5 g 1-carbomethoxyethylidene triphenylphosphine in 200 ml dioxane was stired for 30 min. at 20 °C and then heated until complete conversion at 50°C. The reaction mixture was diluted with hexane, filtered from solid triphenylphosphine oxide through silicagel and evaporated. Further purification of the residue on silicagel (ethyl acetate- hexane 3: 7) led to the desired product with m. p. 91-93°C.

Example H16: Preparation of 3- ( 5-chloro-3-fluoro-pyridin-2-yl)-hydrazono)-1, 1, 1-trifluoro- propan-2-one (intermediate) 6.75 g 1,1-dibromo-3,3,3-trifluoroacetone were stirred for 30 min. at 80°C in a solution of 9. Og sodium acetate in 250 ml water. Then the solution was cooled at 0°C and 4.0 g 2- hydrazino-3-fluoro-5-chloropyridin were added.. Stirring was continued for 3.5 hrs. Then the reaction mixture was extracted with ethyl acetate, the extracts were washed with water and dried. After evaporation, the remaining residue was purified on silcagel (hexane-ethyl acetate 8: 2) to give the title compound as brownish residue which was directly used for the next step. MS: (M-H)-=268.

In analogous manner, 3- ((6-chloro-5-cyano-3-fluoro-pyridin-2-yl)-hydrazono)-1, 1,1-trifluoro- propan-2-one with m. p. 174-176°C was obtained.

The preferred compounds listed in the following tables can also be obtained in an analogous manner and according to the methods illustrated in the general reaction schemes 1-11 and described in the cited references.

Table 1: A preferred group of compounds of formula I corresponds to the general formula (11), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 11.

Table 2: A further preferred group of compounds of formula I corresponds to the general formula (12), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 12.

Table 3: A further preferred group of compounds of formula I corresponds to the general formula (13), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 13.

Table 4: A further preferred group of compounds of formula I corresponds to the general formula (14), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 14.

Table 5: A further preferred group of compounds of formula I corresponds to the general formula (15), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 15.

Table 6: A further preferred group of compounds of formula I corresponds to the general formula (16), wherein substituents R1 and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 16.

Table 7: A further preferred group of compounds of formula I corresponds to the general formula (tu), wherein substituents R1 and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula i7.

Table 8: A further preferred group of compounds of formula I corresponds to the general formula (18), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 18.

Table 9: A further preferred group of compounds of formula I corresponds to the general formula (I9), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 19.

Table 10: A further preferred group of compounds of formula I corresponds to the general formula (11o), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 11o.

Table 11: A further preferred group of compounds of formula I corresponds to the general formula (111), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula in.

Table 12: A further preferred group of compounds of formula # corresponds to the general formula (112), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 112.

Table 13: A further preferred group of compounds of formula I corresponds to the general formula (113), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 113.

Table 14: A further preferred group of compounds of formula I corresponds to the general formula (114), wherein substituents Ri and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 114.

Table 15: A further preferred group of compounds of formula I corresponds to the general formula (115), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 115.

Table 16: A further preferred group of compounds of formula I corresponds to the general formula (116), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula! ie.

Table 17: A further preferred group of compounds of formula I corresponds to the general formula (il7), wherein substituents R1 and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula tiy.

Table 18: A further preferred group of compounds of formula I corresponds to the general formula (1, 8), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula I18.

Table 19: A further preferred group of compounds of formula I corresponds to the general formula (I19), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula! in.

Table 20: A further preferred group of compounds of formula I corresponds to the general formula (120), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 120.

Table 21: A further preferred group of compounds of formula I corresponds to the general formula (121), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 121.

Table 22: A further preferred group of compounds of formula I corresponds to the general formula (122), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 122.

Table 23: A further preferred group of compounds of formula I corresponds to the general formula (123), wherein substituents R1 and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 123 Table 24: A further preferred group of compounds of formula I corresponds to the general formula (124), wherein substituents R1 and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 124.

Table 25: A further preferred group of compounds of formula I corresponds to the general formula (125), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 125.

Table 26: A further preferred group of compounds of formula I corresponds to the general formula (126), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 126.

Table 27: A further preferred group of compounds of formula I corresponds to the general formula (127), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 127.

Table 28: A further preferred group of compounds of formula I corresponds to the general formula (128), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 128.

Table 29: A further preferred group of compounds of formula I corresponds to the general formula (129), wherein substituents R1 and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 129.

Table 30: A further preferred group of compounds of formula I corresponds to the general formula (130), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 130.

Table 31: A further preferred group of compounds of formula I corresponds to the general formula (131), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 131.

Table 32: A further preferred group of compounds of formula I corresponds to the general formula (132), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 132.

Table 33: A further preferred group of compounds of formula I corresponds to the general formula (133), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula tas.

Table 34: A further preferred group of compounds of formula I corresponds to the general formula (134), wherein substituents R1 and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 134.

Table 35: A further preferred group of compounds of formula I corresponds to the general formula (135), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula tas.

Table 36: A further preferred group of compounds of formula I corresponds to the general formula (136), wherein substituents Ri and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 136.

Table 37: A further preferred group of compounds of formula I corresponds to the general formula (137), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula i37.

Table 38: A further preferred group of compounds of formula I corresponds to the general formula (138), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 138.

Table 39: A further preferred group of compounds of formula I corresponds to the general formula (139), wherein substituents R1 and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula tsg.

Table 40: A further preferred group of compounds of formula I corresponds to the general formula (i40), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 140.

Table 41: A further preferred group of compounds of formula I corresponds to the general formula (141), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 141.

Table 42: A further preferred group of compounds of formula I corresponds to the general formula (142), wherein substituents R1 and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 142.

Table 43: A further preferred group of compounds of formula I corresponds to the general formula (143), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula i43.

Table 44: A further preferred group of compounds of formula I corresponds to the general formula (144), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 144.

Table 45: A further preferred group of compounds of formula I corresponds to the general formula (145), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula test Table 46: A further preferred group of compounds of formula I corresponds to the general formula (146), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula las.

Table 47: A further preferred group of compounds of formula I corresponds to the general formula (147), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 14,.

Table 48: A further preferred group of compounds of formula I corresponds to the general formula (1axe) wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 148.

Table 49: A further preferred group of compounds of formula I corresponds to the general formula (149), wherein substituents Ri and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 149.

Table 50: A further preferred group of compounds of formula I corresponds to the general formula (iso, wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 150.

Table 51: A further preferred group of compounds of formula I corresponds to the general formula (151), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 151.

Table 52: A further preferred group of compounds of formula I corresponds to the general formula (152), wherein substituents Pi and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 152.

Table 53: A further preferred group of compounds of formula I corresponds to the general formula (tus), wherein substituents R1 and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 153.

Table 54: A further preferred group of compounds of formula I corresponds to the general formula (154), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 154.

Table 55: A further preferred group of compounds of formula I corresponds to the general formula (ils), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 155 Table 56: A further preferred group of compounds of formula I corresponds to the general formula (156), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 156.

Table 57: A further preferred group of compounds of formula I corresponds to the general formula (157), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula i57 Table 58: A further preferred group of compounds of formula I corresponds to the general formula (18), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 158.

Table 59: A further preferred group of compounds of formula I corresponds to the general formula (tsg), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 159.

Table 60: A further preferred group of compounds of formula I corresponds to the general formula (160), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula iso.

Table 61: A further preferred group of compounds of formula I corresponds to the general formula (161), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 161.

Table 62: A further preferred group of compounds of formula I corresponds to the general formula (162), wherein substituents Ri and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 162.

Table 63: A further preferred group of compounds of formula I corresponds to the general formula (163), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 163.

Table 64: A further preferred group of compounds of formula I corresponds to the general formula (164), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 164.

Table 65: A further preferred group of compounds of formula I corresponds to the general formula (165), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 165.

Table 66: A further preferred group of compounds of formula I corresponds to the general formula (166), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula tes.

Table 67: A further preferred group of compounds of formula I corresponds to the general formula (167), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 167.

Table 68: A further preferred group of compounds of formula I corresponds to the general formula (168), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 168.

Table 69: A further preferred group of compounds of formula I corresponds to the general formula (i69), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula tes.

Table 70: A further preferred group of compounds of formula I corresponds to the general formula (tao), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula I, o.

Table 71: A further preferred group of compounds of formula I corresponds to the general formula (tri), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 171.

Table 72: A further preferred group of compounds of formula I corresponds to the general formula (172), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula I72.

Table 73: A further preferred group of compounds of formula I corresponds to the general formula (173), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1, 3.

Table 74: A further preferred group of compounds of formula I corresponds to the general formula ( (74), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 174- Table 75: A further preferred group of compounds of formula I corresponds to the general formula (175), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 175.

Table 76: A further preferred group of compounds of formula I corresponds to the general formula (176), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 176.

Table 77: A further preferred group of compounds of formula I corresponds to the general formula (177), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula i77.

Table 78: A further preferred group of compounds of formula I corresponds to the general formula (I78), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 178.

Table 79: A further preferred group of compounds of formula I corresponds to the general formula (i79), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 179.

Table 80: A further preferred group of compounds of formula I corresponds to the general formula (180), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 180.

Table 81: A further preferred group of compounds of formula I corresponds to the general formula (181), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 181.

Table 82: A further preferred group of compounds of formula I corresponds to the general formula (182), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 182 Table 83: A further preferred group of compounds of formula I corresponds to the general formula (183), wherein substituents R1 and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 183.

Table 84: A further preferred group of compounds of formula I corresponds to the general formula (184), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 184 Table 85: A further preferred group of compounds of formula I corresponds to the general formula (185), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 185 Table 86: A further preferred group of compounds of formula I corresponds to the general formula (186), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 186.

Table 87: A further preferred group of compounds of formula I corresponds to the general formula (187), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 187 Table 88: A further preferred group of compounds of formula I corresponds to the general formula (188), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 188 Table 89: A further preferred group of compounds of formula I corresponds to the general formula (189), wherein substituents Ri and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 189.

Table 90: A further preferred group of compounds of formula I corresponds to the general formula (Igo), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula Igo.

Table 91: A further preferred group of compounds of formula I corresponds to the general formula (191), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 191.

Table 92: A further preferred group of compounds of formula I corresponds to the general formula (192), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 192.

Table 93: A further preferred group of compounds of formula I corresponds to the general formula (193), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 193.

Table 94: A further preferred group of compounds of formula I corresponds to the general formula (194), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula i94.

Table 95: A further preferred group of compounds of formula I corresponds to the general formula (195), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 195.

Table 96: A further preferred group of compounds of formula I corresponds to the general formula (196), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 196.

Table 97: A further preferred group of compounds of formula I corresponds to the general formula (197), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 197.

Table 98: A further preferred group of compounds of formula I corresponds to the general formula (198), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 198.

Table 99: A further preferred group of compounds of formula I corresponds to the general formula (I99), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 199.

Table 100: A further preferred group of compounds of formula I corresponds to the general formula (hou), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula! zoo.

Table 101: A further preferred group of compounds of formula I corresponds to the general formula (11o1), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1101.

Table 102: A further preferred group of compounds of formula I corresponds to the general formula (ho2), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 11o2.

Table 103: A further preferred group of compounds of formula I corresponds to the general formula (I103), wherein substituents R1 and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula hots.

Table 104: A further preferred group of compounds of formula I corresponds to the general formula () io4), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula tin4.

Table 105: A further preferred group of compounds of formula I corresponds to the general formula I105), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula tics.

Table 106: A further preferred group of compounds of formula I corresponds to the general formula (i106), wherein substituents R1 and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula houe.

Table 107: A further preferred group of compounds of formula I corresponds to the general formula (1107), wherein substituents R1 and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula tioy.

Table 108: A further preferred group of compounds of formula I corresponds to the general formula (ties), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula tiers.

Table 109: A further preferred group of compounds of formula I corresponds to the general formula (I109), wherein substituents R1 and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula lion.

Table 110: A further preferred group of compounds of formula I corresponds to the general formula (111o) wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula tno.

Table 111: A further preferred group of compounds of formula I corresponds to the general formula (1111), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1111.

Table 112: A further preferred group of compounds of formula I corresponds to the general formula (1112), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula ton2.

Table 113: A further preferred group of compounds of formula I corresponds to the general formula (I113), wherein substituents R1 and R3 are defined in Table-A, constituting the disclosure of 448 specific compounds of formula ins.

Table 114: A further preferred group of compounds of formula I corresponds to the general formula (1114), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1114.

Table 115: A further preferred group of compounds of formula I corresponds to the general formula (1115), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula tus.

Table 116: A further preferred group of compounds of formula I corresponds to the general formula (1"6), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula I116.

Table 117: A further preferred group of compounds of formula I corresponds to the general formula (1117), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula iny.

Table 118: A further preferred group of compounds of formula I corresponds to the general formula (tut), wherein substituents R, and R3 are defined in Table-A, constituting the disclosure of 448 specific compounds of formula ng.

Table 119: A further preferred group of compounds of formula I corresponds to the general formula (1119), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1119.

Table 120: A further preferred group of compounds of formula I corresponds to the general formula (i120), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1120.

Table 121: A further preferred group of compounds of formula I corresponds to the general formula (1121), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1121.

Table 122: A further preferred group of compounds of formula I corresponds to the general formula (1122), wherein substituents Ri and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1122.

Table 123: A further preferred group of compounds of formula I corresponds to the general formula (1123), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1123.

Table 124: A further preferred group of compounds of formula I corresponds to the general formula (1124), wherein substituents R1 and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1, 24.

Table 125: A further preferred group of compounds of formula I corresponds to the general formula (1, 25), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1, 25.

Table 126: A further preferred group of compounds of formula I corresponds to the general formula (1126), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1126.

Table 127: A further preferred group of compounds of formula I corresponds to the general formula (1127), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1, 27.

Table 128: A further preferred group of compounds of formula I corresponds to the general formula (1, 28), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1, 28.

Table 129: A further preferred group of compounds of formula I corresponds to the general formula (1, 29), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula I129.

Table 130: A further preferred group of compounds of formula I corresponds to the general formula (1, 30), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1130.

Table 131: A further preferred group of compounds of formula I corresponds to the general formula (113,), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1131.

Table 132: A further preferred group of compounds of formula I corresponds to the general formula (1132), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1132.

Table 133: A further preferred group of compounds of formula I corresponds to the general formula (has), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula hss.

Table 134: A further preferred group of compounds of formula I corresponds to the general formula (1134), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1134.

Table 135: A further preferred group of compounds of formula I corresponds to the general formula (1135), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1135.

Table 136: A further preferred group of compounds of formula I corresponds to the general formula (1136), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1136.

Table 137: A further preferred group of compounds of formula I corresponds to the general formula (1137), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1137.

Table 138: A further preferred group of compounds of formula I corresponds to the general formula (has), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1138.

Table 139: A further preferred group of compounds of formula I corresponds to the general formula (1139), wherein substituents R1 and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1139.

Table 140: A further preferred group of compounds of formula I corresponds to the general formula (1140), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 114o.

Tabie 141: A further preferred group of compounds of formula I corresponds to the general formula (1, 41), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1141.

Table 142: A further preferred group of compounds of formula I corresponds to the general formula (1142), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1142.

Table 143: A further preferred group of compounds of formula I corresponds to the general formula (1143), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1143.

Table 144: A further preferred group of compounds of formula I corresponds to the general formula (1144), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1144.

Table 145: A further preferred group of compounds of formula I corresponds to the general formula (1145), wherein substituents Ri and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1145.

Table 146: A further preferred group of compounds of formula I corresponds to the general formula (I146), wherein substituents R1 and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1146.

Table 147: A further preferred group of compounds of formula I corresponds to the general formula (1147), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1147.

Table 148: A further preferred group of compounds of formula I corresponds to the general formula (1148), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1148.

Table 149: A further preferred group of compounds of formula I corresponds to the general formula (1149), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula I149.

Table 150: A further preferred group of compounds of formula I corresponds to the general formula (1150), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1150 Table 151: A further preferred group of compounds of formula I corresponds to the general formula (ti5i), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula I151.

Table 152: A further preferred group of compounds of formula I corresponds to the general formula (1, 52), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1, 52.

Table 153: A further preferred group of compounds of formula I corresponds to the general formula (1153), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula hsa.

Table 154: A further preferred group of compounds of formula I corresponds to the general formula ( ! i54), wherein substituents Ri and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula I154.

Table 155: A further preferred group of compounds of formula I corresponds to the general formula (hss), wherein substituents R1 and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula i155.

Table 156: A further preferred group of compounds of formula I corresponds to the general formula (1156), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1156.

Table 157: A further preferred group of compounds of formula I corresponds to the general formula (1157), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1157.

Table 158: A further preferred group of compounds of formula I corresponds to the general formula (1158), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1158.

Table 159: A further preferred group of compounds of formula I corresponds to the general formula (1159), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula tisg.

Table 160: A further preferred group of compounds of formula I corresponds to the general formula (1, 60), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1160.

Table 161: A further preferred group of compounds of formula I corresponds to the general formula (1, 61), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1161.

Table 162: A further preferred group of compounds of formula I corresponds to the general formula (1162), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1162.

Table 163: A further preferred group of compounds of formula I corresponds to the general formula (1163), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1163.

Table 164: A further preferred group of compounds of formula I corresponds to the general formula (1164), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1164.

Table 165: A further preferred group of compounds of formula I corresponds to the general formula (1165), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1165.

Table 166: A further preferred group of compounds of formula I corresponds to the general formula (1, 66), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1166.

Table 167: A further preferred group of compounds of formula I corresponds to the general formula (1167), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1167.

Table 168: A further preferred group of compounds of formula I corresponds to the general formula (I168), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1168.

Table 169: A further preferred group of compounds of formula I corresponds to the general formula (1169), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1, 69.

Table 170: A further preferred group of compounds of formula I corresponds to the general formula (117o) wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula tiyo.

Table 171: A further preferred group of compounds of formula I corresponds to the general formula (1171), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1171.

Table 172: A further preferred group of compounds of formula I corresponds to the general formula (tri72), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula I, 72.

Table 173: A further preferred group of compounds of formula I corresponds to the general formula (1173), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1173.

Table 174: A further preferred group of compounds of formula I corresponds to the general formula (I174), wherein substituents R, and R3-are defined in Table A, constituting the disclosure of 448 specific compounds of formula I174.

Table 175: A further preferred group of compounds of formula I corresponds to the general formula (I175), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula I175.

Table 176: A further preferred group of compounds of formula I corresponds to the general formula (1, 76), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1176.

Table 177: A further preferred group of compounds of formula I corresponds to the general formula (tu77), wherein substituents R1 and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula hyy.

Table 178: A further preferred group of compounds of formula I corresponds to the general formula (I178), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1, 78.

Table 179: A further preferred group of compounds of formula I corresponds to the general formula (1179), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula i179.

Table 180: A further preferred group of compounds of formula I corresponds to the general formula (118o) wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula tigo.

Table 181: A further preferred group of compounds of formula I corresponds to the general formula (1181), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula I181.

Table 182: A further preferred group of compounds of formula I corresponds to the general formula 1182), wherein substituents R1 and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1182.

Table 183: A further preferred group of compounds of formula I corresponds to the general formula (1183), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1, 83.

Table 184: A further preferred group of compounds of formula I corresponds to the general formula (1184), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1184.

Table 185: A further preferred group of compounds of formula I corresponds to the general formula (1185), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1185.

Table 186: A further preferred group of compounds of formula I corresponds to the general formula (1, su), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1186.

Table 187: A further preferred group of compounds of formula I corresponds to the general formula (1187), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula I187, Table 188: A further preferred group of compounds of formula I corresponds to the general formula (1188), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1188.

Table 189: A further preferred group of compounds of formula I corresponds to the general formula (1189), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1189.

Table 190: A further preferred group of compounds of formula I corresponds to the general formula (i190), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula igo.

Table 191: A further preferred group of compounds of formula I corresponds to the general formula (1, 91), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula l, 9,.

Table 192: A further preferred group of compounds of formula I corresponds to the general formula (tri92), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1192.

Table 193: A further preferred group of compounds of formula I corresponds to the general formula (has), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1193.

Table 194: A further preferred group of compounds of formula I corresponds to the general formula (1194), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1194.

Table 195: A further preferred group of compounds of formula I corresponds to the general formula (1195), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1195.

Table 196: A further preferred group of compounds of formula I corresponds to the general formula (1196), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1196.

Table 197: A further preferred group of compounds of formula I corresponds to the general formula (1197), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1197.

Table 198: A further preferred group of compounds of formula I corresponds to the general formula (1198), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1198.

Table 199: A further preferred group of compounds of formula I corresponds to the general formula (1199), wherein substituents Ri and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula ring.

Table 200: A further preferred group of compounds of formula I corresponds to the general formula (1200), wherein substituents R1 and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1200.

Table 201: A further preferred group of compounds of formula I corresponds to the general formula (12o1) wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 12o1 Table 202: A further preferred group of compounds of formula I corresponds to the general formula (1202), wherein substituents Pi and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1202.

Table 203: A further preferred group of compounds of formula I corresponds to the general formula (1203), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1203.

Table 204: A further preferred group of compounds of formula I corresponds to the general formula (1204), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1204.

Table 205: A further preferred group of compounds of formula I corresponds to the general formula (1205), wherein substituents Ri and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1205.

Table 206: A further preferred group of compounds of formula I corresponds to the general formula (tsoe), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1206.

Table 207: A further preferred group of compounds of formula I corresponds to the general formula (1207), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1207.

Table 208: A further preferred group of compounds of formula I corresponds to the general formula (12os) wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1208.

Table 209: A further preferred group of compounds of formula I corresponds to the general formula (1209), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1209.

Table 210: A further preferred group of compounds of formula I corresponds to the general rmula (1210), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula I210.

Table 211: A further preferred group of compounds of formula I corresponds to the general formula (1211), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1211.

Table 212: A further preferred group of compounds of formula I corresponds to the general formula (1212), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1212.

Table 213: A further preferred group of compounds of formula I corresponds to the general formula (1213), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1213.

Table 214: A further preferred group of compounds of formula I corresponds to the general formula (1214), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1214.

Table 215: A further preferred group of compounds of formula I corresponds to the general formula (1215), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1215.

Table 216: A further preferred group of compounds of formula I corresponds to the general formula (1216), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula) 216.

Table 217: A further preferred group of compounds of formula I corresponds to the general formula (1217), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1217, Table 218: A further preferred group of compounds of formula I corresponds to the general formula ( ! zi8), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula i 218.

Table 219: A further preferred group of compounds of formula I corresponds to the general formula (tri9), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 12, 9.

Table 220: A further preferred group of compounds of formula I corresponds to the general formula (122o), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1220.

Table 221: A further preferred group of compounds of formula I corresponds to the general formula (1221), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 122,.

Table 222: A further preferred group of compounds of formula I corresponds to the general formula (1222), wherein substituents R, and R3 are defined in Table A, constituting the disclosure of 448 specific compounds of formula 1222.

Table A Cmpd no. R, R3 .001 F CN .002 F CHO .003 F COCH3 .004 F COOCH2CH3 .005 F COOCH2C6H5 . 006 F COCI . 007 F COCH2CH2CI .008 F COOH .009 F COOCH3 .010 F COOCH2CH3 . 011 F COOCH (CH3) 2 .012 F COOCH2CH=CH2 . 013 F COO (CH2) 5CH3 Cmpd no. R, R3 . 014 F COOCH (CH3) CH=CH2 .015 F COOCH2 (2-F-C6H5) .016 F COOC6H5 .017 F COOCH2CH20CH2CH3 . 018 F COOCH (CH3) CH2SCH3 .019 F COO (oxetanyl) .020 F COOCH2 (oxiranyl) .021 F COO (cylopentyl) .022 F COSCH3 . 023 F COSCH (CH3) 2 .024 F COSCH2C6H5 .025 F CONH2 .026 F CONH (CH2CH=CH2) .027 F CONHCH2C6H5 . 028 F CON (CH2CH=CH2) 2 . 029 F CON (CH3) OCH3 .030 F COOCH2CH2COOH . 031 F COOCH (CH3) COOCH3 . 032 F COOCH (CH3) COOCH2C6H5 . 033 F COOCH (CH3) CH2COOCH2CH3 . 034 F (S)-COOCH (CH3) CH2COOCH2CH=CH2 . 035 F (R)-COOCH (CH3) CH2COOCH2CH=CH2 . 036 F COOCH (CH3) CH2CONHCH2CH3 . 037 F COOCH (CH3) CH2CON (CH3) 2 . 038 F (R)-COOCH (CH3) CH2COOCH3 . 039 F COOCH (CH3) CH2COOCH2CH=CH2 . 040 F COOC (CH3) 2COCH3 . 041 F COOC (CH3) 2COOH . 042 F COOC (CH3) 2COOCH3 . 043 F COOC (CH3) 2COOCH2CH3 . 044 F COOC (CH3) 2COOCH (CH3) 2 . 045 F COOC (CH3) 2COO (CH2) 4CH3 . 046 F COOC (CH3) 2COOCH2C6H5 . 047 F COOC (CH3) 2COOCH2 (2-F-C6H5) . 048 F COOC (CH3) 2COOCH2CH=CH2 . 049 F (R)-COOCH (CH3) COOCH2CH3 . 050 F-COOC (CH3) 2COOCH2C=-CH R1R3Cmpdno. COO(CH3)2COOCH2CH2OCH2CH3.051F . 052 F COOC (CH3) 2COSCH3 . 053 F COOC (CH3) 2COSCH (CH3) 2 . 054 F COOC (CH3) 2COSCH2C6H5 . 055 F COOC (CH3) 2CONH2 . 056 F COOC (CH3) 2CONHCH2CH=CH2 . 057 F COOC (CH3) 2CON (CH2CH3) 2 . 058 F COOC (CH3) 2CON (CH3) CH2CH2 OCH3 . 059 F COSCH (CH3) COOH . 060 F COSCH (CH3) COOCH3 . 061 F COSCH (CH3) CONHCH2CH=CH2 . 062 F CON (CH3) CH2COOH . 063 F CON (CH3) C (CH3) 2COOCH2CH3 . 064 F CON (CH3) OCH2COOCH3 . 065 F CON (CH3) OH .066 F CH3 .067 F CH2CH3 . 068 F CH (OH) CH3 . 069 F CH (OCH2CH=CH2) CH3 . 070 F CH2CI .071 F CH20H .072 F CH20COCH3 . 073 F CHCICH3 .074 F CH2CH2CF3 .075 F CH=CHCF3 .076 F CH2CH=CH2 .077 F CH=CHCH3 .078 F C=-CH .079 F CCCH20H .080 F CH2CHCICOOH .081 F (R)-CH2CHCICOOH .082 F (S)-CH2CHCICOOH . 083 F CH2CH (CH3) COOH . 084 F CH2CH (CH3) COOCH2CH3 . 085 F CH (CI) CH2COOCH3 . 086 F CH (CI) C (CI) 2COOH . 087 F-CH (CI) CH (CI) COOCH2CH3 Cmpd no. R1 R3 . 088 F CH2CH (CH3) COOH . 089 F CH2CH (CH3) COCH2CH=CH2 . 090 F CH2CH (CH3) CONH (CH2CH=CH2) . 091 F CH2CH (CH3) CON (CH3) 2 . 092 F CH2CH (CH3) COSCH (CH3) 2 . 093 F CH2CHCICOOC (CH3) 3 .094 F CH2CHCICOOCH3 . 095 F CH2CHCICOOCH2CH3 . 096 F CH2CHCICOOCH (CH3) 2 . 097 F CH2CHCICOOCH2CH=CH2 .098 F CH2CHCICOOCH2C6H5 . 099 F CH2CHCICOSCH3 . 100 F CH2CHCICOSCH (CH3) 2 . 101 F CH2CHCICOSCH2C6H5 . 102 F CH2CHCICONH2 . 103 F CH2CHCICONH (CH2CH=CH2) . 104 F CH2CHCICON (CH2CH3) 2 . 105 F CH2CHCICONH (CH2C6H5) . 106 F CH2CHCICON (CH3) CH2C6H5 . 107 F CH=CHCOOH . 108 F (E)-CH=CHCOOH . 109 F (Z)-CH=CHCOOH .110 F CH=CHCOOCH3 .111 F CH=CHCOOCH2C6H5 .112 F CH=CHCONH2 .113 F CH=CHCONH (CH2CH=CH2) . 114 F CH=C (CI) COOH . 115 F CH=C (CI) CONH2 . 116 F CH=C (CI) CONH (CH2CH3) . 117 F CH=C (CI) CON (CH2CH3) 2 . 118 F CH=C (CI) CONH (CH2C6H5) . 119 F CH=C (CI) COSCH3 . 120 F CH=C (CI) COSCH (CH3) 2 . 121 F CH=C (CH3) COOH . 122 F CH=C (CH3) CONH (CH2CH=CH2) . 123 F CH=C (CH3) CON (CH3) 2 . 124 F-CH=C (CH3) COSCH2CH3 R1R3Cmpdno. . 125 F CH=C (CN) COOH . 126 F CH=C (CN) COOC (CH3) 3 . 127 F CH=C (CN) CON (CH2CH=CH2) 2 . 128 F CH=C (COOH) 2 . 129 F CH=C (C6H5) COOH .130 F CH=CHCH20H . 131 Cl CN .132 Cl CHO . 133 Cl COCH3 . 134 Cl COOCH2CH3 . 135 Cl COOCH2C6H5 . 136 Cl COCI . 137 Cl COCH2CH2CI . 138 Cl COOH . 139 Cl COOCH3 COOCH2CH3.140Cl . 141 Cl COOCH (CH3) 2 . 142 ci COOCH2CH=CH2 . 143 Cl COO (CH2) 5CH3 . 144 Cl COOCH (CH3) CH=CH2 . 145 CI COOCH2 (2-F-C6H5) . 146 Cl COOC6H5 . 147 Cl COOCH2CH20CH2CH3 . 148 Cl COOCH (CH3) CH2SCH3 . 149 Cl COO (oxetanyl) . 150 Cl COOCH2 (oxiranyl) . 151 Cl COO (cylopentyl) . 152 Cl COSCH3 . 153 Cl COSCH (CH3) 2 . 154 Cl COSCH2C6H5 . 155 Cl CONH2 . 156 Cl CONH (CH2CH=CH2) . 157 Cl CONHCH2C6H5 . 158 Cl CON (CH2CH=CH2) 2 .159 CON(CH3)OCH3 . 160 Cl COOCH2CH2COOH . 161! COOCH (CH3) COOCH3 Cmpd no. R1 R3 . 162 Cl COOCH (CH3) COOCH2C6H5 COOCH(CH3)CH2COOCH2CH3.163Cl . 164 Cl (S)-COOCH (CH3) CH2COOCH2CH=CH2 . 165 Cl (R)-COOCH (CH3) CH2COOCH2CH=CH2 . 166 Cl COOCH (CH3) CH2CONHCH2CH3 . 167 Cl COOCH (CH3) CH2CON (CH3) 2 . 168 Cl COOCH (CH3) CH2COSCH2CH3 . 169 Cl COOCH (CH3) CH2COOCH2CH=CH2 . 170 Cl COOC (CH3) 2COCH3 . 171 Cl COOC (CH3) 2COOH . 172 Cl COOC (CH3) 2COOCH3 . 173 Cl COOC (CH3) 2COOCH2CH3 . 174 Cl COOC (CH3) 2COOCH (CH3) 2 . 175 Cl COOC (CH3) 2COO (CH2) 4CH3 . 176 ci COOC (CH3) 2COOCH2C6H5 . 177 Cl COOC (CH3) 2COOCH2 (2-F-C6H5) . 178 Cl COOC (CH3) 2COOCH2CH=CH2 . 179 Cl COOC (CH3) 2COOCH (CH3) CH=CH2 . 180 CI COOC (CH3) 2COOCH2C=-CH . 181 Cl COO (CH3) 2COOCH2CH20CH2CH3 . 182 Cl COOC (CH3) 2COSCH3 . 183 Cl COOC (CH3) 2COSCH (CH3) 2 . 184 Cl COOC (CH3) 2COSCH2C6H5 . 185 Cl COOC (CH3) 2CONH2 . 186 Cl COOC (CH3) 2CONHCH2CH=CH2 . 187 Cl COOC (CH3) 2CON (CH2CH3) 2 . 188 Cl COOC (CH3) 2CON (CH3) CH2CH20CH3 . 189 Cl COSCH (CH3) COOH . 190 Cl COSCH (CH3) COOCH3 . 191 Cl COSCH (CH3) CONHCH2CH=CH2 . 192 Cl CON (CH3) CH2COOH . 193 Cl CON (CH3) C (CH3) 2COOCH2CH3 . 194 Cl CON (CH3) OCH2COOCH3 . 195 Cl CON (CH3) OH . 196 Cl CH3 CH2CH3.197Cl . 198 CH (OH) CH3 Cmpd no. R1 R3 . 199 Cl CH (OCH2CH=CH2) CH3 CH2Cl.200Cl .201 Cl CH20H . 202 Cl CH20COCH3 . 203 Cl CHCICH3 . 204 CI CH2CH2CF3 . 205 Cl CH=CHCF3 CH2CH=CH2.206Cl . 207 Cl CH=CH (CH3) .208 C#CH . 209 Cl C=CCHzOH . 210 Cl CH2CHCICOOH . 211 Cl (R)-CH2CHCICOOH . 212 Cl (S)-CH2CHCICOOH . 213 Cl CH2CH (CH3) COOH . 214 Cl CH2CH (CH3) COOCH2CH3 . 215 Cl CH (CI) CH2COOCH3 . 216 Cl CH (CI) C (CI) 2COOH . 217 Cl CH (CI) CH (CI) COOCH2CH3 . 218 Cl CH2CH (CH3) COOH . 219 Cl CH2CH (CH3) COCH2CH=CH2 . 220 Cl CH2CH (CH3) CONH (CH2CH=CH2) . 221 Cl CH2CH (CH3) CON (CH3) 2 . 222 Cl CH2CH (CH3) COSCH (CH3) 2 . 223 Cl CH2CHCICOOC (CH3) 3 .224 Cl CH2CHCICOOCH3 . 225 Cl CH2CHCICOOCH2CH3 . 226 Cl CH2CHCICOOCH (CH3) 2 . 227 Cl CH2CHCICOOCH2CH=CH2 . 228 Cl CH2CHCICOOCH2C6H5 . 229 Cl CH2CHCICOSCH3 . 230 Cl CH2CHClCOSCH (CH3) 2 . 231 Cl CH2CHCICOSCH2C6H5 . 232 Cl CH2CHCICONH2 . 233 Cl CH2CHCICONH (CH2CH=CH2) . 234 Cl CH2CHCICON (CH2CH3) 2 CH2CHClCONH(CH2C6H5).235Cl R1R3Cmpdno. . 236 ci CH2CHCICON (CH3) CH2C6H5 . 237 Cl CH=CHCOOH . 238 Cl (E)-CH=CHCOOH . 239 Cl (Z)-CH=CHCOOH . 240 Cl CH=CHCOOCH3 . 241 CI CH=CHCOOCH2C6H5 . 242 Cl CH=CHCOONH2 CH=CHCONH(CH2CH=CH2).243Cl . 244 Cl CH=C (CI) COOH . 245 Cl CH=C (CI) CONH2 . 246 Cl CH=C (CI) CONH (CH2CH3) . 247 Cl CH=C (CI) CON (CH2CH3) 2 . 248 Cl CH=C (CI) CONH (CH2C6H5) . 249 Cl CH=C (CI) COSCH3 . 250 Cl CH=C (CI) COSCH (CH3) 2 . 251 Cl CH=C (CH3) COOH . 252 Cl CH=C (CH3) CONH (CH2CH=CH2) . 253 Cl CH=C (CH3) CON (CH3) 2 . 254 Cl CH=C (CH3) COSCH2CH3 . 255 Cl CH=C (CN) COOH . 256 Cl CH=C (CN) COOC (CH3) 3 .257 Cl CH=C (CN) CON (CH2CH=CH2) 2 . 258 Cl CH=C (COOH) 2 . 259 Cl CH=C (C6H5) COOH . 260 Cl CH=CHCH20H CH2OCOCH3.261H .262 H COOH . 263 H COCI .264 H COOCH3 . 265 H COOCH (CH3) 2 .266 H COOCH2C6H5 . 267 H COSCH (CH3) 2 .268 H CONH2 .269 H CONHCH2C6Hs .270 H CON (CH2CH=CH2) 2 . 271 H CON (CH3) OCH3 . 272 H-COOCH (CH3) CH2COOH Cmpd no. R, R3 . 273 H COOCH (CH3) COOCH2CH3 . 274 H COOCH (CH3) CH2COOCH2CH=CH2 .275 H COOCH (CH3) CH2COSCH2CH3 . 276 H COOCH (CH3) CH2CONH2 . 277 H COOCH (CH3) CH2CONH (CH2CH=CH2) . 278 H COOCH (CH3) COOH . 279 H COOC (CH3) 2COOH . 280 H COOC (CH3) 2COOCH3 . 281 H COOC (CH3) 2COOCH (CH3) 2 . 282 H COOC (CH3) 2COOCH2CH3 . 283 H COOC (CH3) 2COOCH2CH=CH2 . 284 H COOC (CH3) 2COOCH2CH20CH2CH3 . 285 H Cyclopropyl . 286 H COOC (CH3) 2CON (CH3) 2 . 287 H COOC (CH3) 2CONH (CH2CH=CH2) . 288 H COSCH (CH3) COOH . 289 H CON (CH3) C (CH3) 2COOH .290 H CH3 .291 H CH2CH3 . 292 H CH (OH) CH3 .293 H CH2CI .294 H CH20H .295 H CH20COCH3 .296 H CH=CHCF3 .297 H CH2CH2CF3 .298 H CH2CH=CH2 .299 H CH2CHCICOOH .300 H CH2CHCICOOCH2CH3 .301 H CH2CHCICOOCH2C6H5 .302 H CH2CHCICOOCH2CH=CH2 . 303 H CH2CHCICOOC (CH3) 3 .304 H CH2CHCICOSCH (CH3) 2 . 305 H CH2CHCICONH2 .306 H CH2CHCICONH (CH2CH3) . 307 H CH2CHCICON (CH3) 2 . 308 H CH (CI) CH (CI) COOH . 309 H-CH2C (CH3) CICOOH Cmpd no. R1 R3 . 310 H CH2C (CH3) CICOOCH2CH3 . 311 H CH2C (CH3) CICOSCH3 . 312 H CH2C (CH3) CICONH (CH2CH=CH2) .313 H Cyclopropyl .314 H CH=CHCOOH . 315 H CH=C (CH3) COOH . 316 H CH=C (CI) COOH . 317 H CH=C (CN) COOH . 318 H CH=C (CN) COOCH2CH=CH2 . 319 H CH=C (CI) COOCH2CH3 .320 H CCCH3 . 321 H CH=C (CI) COSCH2CH3 . 322 H CH=C (CI) CON (CH3) 2 .323 CH3 CH20COCH3 .324 CH3 COOH . 325 CH3 COCI .326 CH3 COOCH3 . 327 CH3 COOCH (CH3) 2 .328 CH3 COOCH2C6H5 . 329 CH3 COSCH (CH3) 2 .330 CH3 CONH2 .331 CH3 CONHCH2C6H5 . 332 CH3 CON (CH2CH=CH2) 2 . 333 CH3 CON (CH3) OCH3 . 334 CH3 COOCH (CH3) CH2COOH .335 F CCH . 336 CH3 COOCH (CH3) CH2COOCH2CH=CH2 . 337 CH3 COOCH (CH3) CH2COSCH2CH3 . 338 CH3 COOCH (CH3) CH2CONH2 . 339 CH3 COOCH (CH3) CH2CONH (CH2CH=CH2) . 340 CH3 COOCH (CH3) COOH . 341 CH3 COOC (CH3) 2COOH . 342 CH3 COOC (CH3) 2COOCH3 . 343 CH3 COOC (CH3) 2COOCH (CH3) 2 . 344 CH3 COOC (CH3) 2COOCH2CH3 . 345 CH3 COOC (CH3) 2COOCH2CH=CH2 . 346 CH3 COOC (CH3) 2COOCH2CH20CH2CH3 Cmpd no. R, R3 . 347 CH3 COOC (CH3) 2CONH2 . 348 CH3 COOC (CH3) 2CON (CH3) 2 . 349 CH3 COOC (CH3) 2CONH (CH2CH=CH2) . 350 CH3 COSCH (CH3) COOH . 351 F CCC (CH3) 20H . 352 F CF3 .353 CH3 CH2CH3 . 354 CH3 CH (OH) CH3 .355 CH3 CH2CI .356 CH3 CH20H .357 CH3 CH20COCH3 .358 CH3 CH=CHCF3 .359 CH3 CH2CH2CF3 .360 CH3 CH2CH=CH2 .361 CH3 CH2CHCICOOH .362 CH3 CH2CHCICOOCH2CH3 .363 CH3 CH2CHCICOOCH2C6H5 .364 CH3 CH2CHCICOOCH2CH=CH2 . 365 CH3 CH2CHCICOOC (CH3) 3 . 366 CH3 CH2CHCICOSCH (CH3) 2 . 367 CH3 CH2CHCICONH2 . 368 ci CCC (CH3) 20CH3 . 369 F CCC (CH3) 20CH3 . 370 CH3 CH (CI) CH (CI) COOH . 371 CH3 CH2C (CH3) CICOOH . 372 CH3 CH2C (CH3) CICOOCH2CH3 . 373 CH3 CH2C (CH3) CICOSCH3 . 374 CH3 CH2C (CH3) CICONH (CH2CH=CH2) . 375 CH3 CH2C (CH3) CICON (CH3) (CH2CH=CH2) .376 CH3 CH=CHCOOH . 377 CH3 CH=C (CH3) COOH . 378 CH3 CH=C (CI) COOH . 379 CH3 CH=C (CN) COOCH2CH=CH2 . 380 CH3 CH=C (CN) COOH . 381 CH3 CH=C (CI) COOCH2CH3 . 382 CH3 CH=C (CH3) CONH (CH2CH=CH2) . 383 CH3 CH=C (CI) COSCH2CH3 R1R3Cmpdno. CH=C(Cl)CON(CH3)2.384CH3 . 385 H COOCH2CH3 . 386 CH3 COOCH2CH3 . 387 F CH=CH2 . 388 F COSCH2CH3 . 389 F COO~ +NH2 (CH (CH3) 2) 2 . 390 F COO-+NH (CH2CH20H) 3 . 391 F COO-+K . 392 F COOCH2CH (CH3) CF3 . 393 F COOCH (CH3) COOCH2CH3 . 394 F CON (CH2CH2CH3) 2 .395 F COOCH2CH2CH2CH2CH3 .396 F COOCH2CH2SCH2CH2CH2CH3 .397 F COOCH2CH2CN . 398 F COOCH2CH2SCH (CH3) 2 . 399 F COOCH2CH2CH2C6H5 . 400 F COOCH (CH3) CH2CH2CH3 COO(CH2)5COOCH2CH3.401F . 402 F COOC (CH3) 3 . 403 F CH=C (CH3) COOCH2CH3 .404 F COO-cyclopropyl .405 F COO-cyclohexyl . 406 F COOCH2-cyclopropyl .407 F COOCH2C6H5 .408 F COOCH2CH20CH3 .409 F COOCH2CH2CH3 . 410 F COOCH2CH (CH3) 2 .411 F COOCH2CH2CH2CH3 . 412 F COOCH2CH (CH3) CH2CH3 . 413 F COOCH2 (p-CI-C6H4) . 414 F COOCH (CH3) C6H5 . 415 F COSCH2 (o-F-C6H4) . 416 F COSCH (CH3) CH2CH3 . 417 F COSCH (CH3) C6H5 .418 F COSCH2CH2CH3 .419 F COSCH2CH=CH2 . 420 F-CON (CH2CH=CH2) CH2CH3 Cmpd no. R1 R3 CON(SO2CH3)CH3.421F . 422 F CON (S02CH3) CH2CH=CH2 . 423 Cl COO-cyclopropyl . 424 CI COO-cyclohexyl . 425 CI COOCH2-cyclopropyl . 426 CI COOCH2C6H5 .427 COOCH2CH2OCH3 COOCH2CH2CH3.428Cl . 429 Cl COOCH2CH (CH3) 2 . 430 ci COOCH2CH2CH2CH3 . 431 Cl COOCH2CH (CH3) CH2CH3 .432 COOCH2(p-Cl-C6H4) . 433 Cl COOCH (CH3) C6H5 . 434 Cl COOCH (CH3) C6H5 .435 COSCH2(o-F-C6H4) . 436 Cl COSCH (CH3) CH2CH3 . 437 Cl COSCH (CH3) C6H5 COSCH2CH2CH3.438Cl . 439 ci COSCH2CH=CH2 . 440 Cl CON (CH2CH=CH2) CH2CH3 .441 CON(SO2CH3)CH3 .442 CON(SO2CH3)CH2CH=CH2 . 443 H COOC (CH3) 2COCI . 444 F CH=C (F) COOCH2CH3 (E/Z) . 445 F CH=C (CI) COOCH2CH3 (E/Z) Cl.446F .447 F Br .448 F I The intermediate products of formulae XXXIX and XXXX (e. g. in reaction scheme 12) are new and likewise comprise part of the invention. The following tables 600 to 647 exemplify preferred compounds of formulae XXXIX and XXXX.

Table 600: A preferred group of compounds of formula XXXIX corresponds to the general formula (XXXIX600), wherein substituents R, and R2 are defined in Table B, constituting the disclosure of 34 specific compounds of formula XXXIX 600- Table 601: A further preferred group of compounds of formula XXXIX corresponds to the general formula (XXXIX601), wherein substituents R, and R2 are defined in Table B, constituting the disclosure of 34 specific compounds of formula XXXIX601.

Table 602: A further preferred group of compounds of formula XXXIX corresponds to the general formula (XXXIX602), wherein substituents R, and R2 are defined in Table B, constituting the disclosure of 34 specific compounds of formula XXXIX6o2.

Table 603: A further preferred group of compounds of formula XXXIX corresponds to the general formula (XXXIX603), wherein substituents R1 and R2 are defined in Table B, constituting the disclosure of 34 specific compounds of formula XXXIX603.

Table 604: A further preferred group of compounds of formula XXXIX corresponds to the general formula (XXXIX604), wherein substituents R, and R2 are defined in Table B, constituting the disclosure of 34 specific compounds of formula XXXIXso4.

Table 605: A further preferred group of compounds of formula XXXIX corresponds to the general formula (XXXIX605), wherein substituents R, and R2 are defined in Table B, constituting the disclosure of 34 specific compounds of formula XXXIX605.

Table 606: A further preferred group of compounds of formula XXXIX corresponds to the general formula (XXXIX6o6), wherein substituents R, and R2 are defined in Table B, constituting the disclosure of 34 specific compounds of formula XXXIX606 Table 607: A further preferred group of compounds of formula XXXIX corresponds to the general formula (XXXIX607), wherein substituents R, and R2 are defined in Table B, constituting the disclosure of 34 specific compounds of formula XXXIX607.

Table 608: A further preferred group of compounds of formula XXXIX corresponds to the general formula (XXXIX608), wherein substituents R, and R2 are defined in Table B, constituting the disclosure of 34 specific compounds of formula XXXIX6o8.

Table 609: A further preferred group of compounds of formula XXXIX corresponds to the general formula (XXXIX609), wherein substituents R, and R2 are defined in Table B, constituting the disclosure of 34 specific compounds of formula XXXtXeog.

Table 610: A further preferred group of compounds of formula XXXIX corresponds to the general formula (XXXIX610), wherein substituents R, and R2 are defined in Table B, constituting the disclosure of 34 specific compounds of formula XXXIX610 Table 611: A further preferred group of compounds of formula XXXIX corresponds to the general formula (XXXIX611), wherein substituents R, and R2 are defined in Table B, constituting the disclosure of 34 specific compounds of formula XXXIX611.

Table 612: A further preferred group of compounds of formula XXXIX corresponds to the general formula (XXXIX612), wherein substituents R, and R2 are defined in Table B, constituting the disclosure of 34 specific compounds of formula XXXIX612.

Table 613: A further preferred group of compounds of formula XXXIX corresponds to the general formula (XXXIX613), wherein substituents R, and R2 are defined in Table B, constituting the disclosure of 34 specific compounds of formula XXXIX613.

Table 614: A further preferred group of compounds of formula XXXIX corresponds to the general formula (XXXIX614), wherein substituents R1 and R2 are defined in Table B, constituting the disclosure of 34 specific compounds of formula XXXIX614.

Table 615: A further preferred group of compounds of formula XXXIX corresponds to the general formula (XXXIX615), wherein substituents R, and R2 are defined in Table B, constituting the disclosure of 34 specific compounds of formula XXXIX615.

Table 616: A further preferred group of compounds of formula XXXIX corresponds to the general formula (XXXIX616), wherein substituents R, and R2 are defined in Table B, constituting the disclosure of 34 specific compounds of formula XXXIX616.

Table 617: A preferred group of compounds of formula XXXX corresponds to the general formula (XXXX617), wherein substituents R, and R2 are defined in Table A, constituting the disclosure of 34 specific compounds of formula XXXX617 Table 618: A further preferred group of compounds of formula XXXX corresponds to the general formula (XXXX618), wherein substituents R, and R2 are defined in Table B, constituting the disclosure of 34 specific compounds of formula XXXX618.

Table 619: A further preferred group of compounds of formula XXXX corresponds to the general formula (XXXX619), wherein substituents R, and R2 are defined in Table B, constituting the disclosure of 34 specific compounds of formula XXXX619 Table 620: A further preferred group of compounds of formula XXXX corresponds to the general formula (XXXX620), wherein substituents R, and R2 are defined in Table B, constituting the disclosure of 34 specific compounds of formula XXXX620.

Table 621: A further preferred group of compounds of formula XXXX corresponds to the general formula (XXXX621), wherein substituents R1 and R2 are defined in Table B, constituting the disclosure of 34 specific compounds of formulaXXXX621.

Table 622: A further preferred group of compounds of formula XXXX corresponds to the general formula (XXXX622), wherein substituents R1 and R2 are defined in Table B, constituting the disclosure of 34 specific compounds of formula XXXX622.

Table 623: A further preferred group of compounds of formula XXXX corresponds to the general formula (XXXX623), wherein substituents R, and R2 are defined in Table B, constituting the disclosure of 34 specific compounds of formula XXXX623.

Table 624: A further preferred group of compounds of formula XXXX corresponds to the general formula (XXXX624), wherein substituents R, and R2 are defined in Table B, constituting the disclosure of 34 specific compounds of formula XXXX624.

Table 625: A further preferred group of compounds of formula XXXX corresponds to the general formula (XXXX625), wherein substituents R, and R2 are defined in Table B, constituting the disclosure of 34 specific compounds of formula XXXX625.

Table 626: A further preferred group of compounds of formula XXXX corresponds to the general formula (XXXX626), wherein substituents R, and R2 are defined in Table B, constituting the disclosure of 34 specific compounds of formula XXXX626- Table 627: A further preferred group of compounds of formula XXXX corresponds to the general formula (XXXX627), wherein substituents R, and R2 are defined in Table B, constituting the disclosure of 34 specific compounds of formula XXXX627- Table 628: A further preferred group of compounds of formula XXXX corresponds to the general formula (XXXX628), wherein substituents R, and R2 are defined in Table B, constituting the disclosure of 34 specific compounds of formula XXXX628- Table 629: A further preferred group of compounds of formula XXXX corresponds to the general formula (XXXX629), wherein substituents R, and R2 are defined in Table B, constituting the disclosure of 34 specific compounds of formula XXXX629.

Table 630: A further preferred group of compounds of formula XXXX corresponds to the general formula (XXXX630), wherein substituents R, and R2 are defined in Table B, constituting the disclosure of 34 specific compounds of formula XXXX630 Table 631: A further preferred group of compounds of formula XXXIX corresponds to the general formula (XXXIX631), wherein substituents R, and R2 are defined in Table B, constituting the disclosure of 34 specific compounds of formula XXXIX631.

Table 632: A further preferred group of compounds of formula XXXX corresponds to the generalformula (XXXX632), wherein substituents R, and R2 are defined in Table B, constituting the disclosure of 34 specific compounds of formula XXXX632.

Table 633: A further preferred group of compounds of formula XXXX corresponds to the general formula (XXXX633), wherein substituents R, and R2 are defined in Table B, constituting the disclosure of 34 specific compounds of formula XXXX633.

Table 634: A further preferred group of compounds of formula XXXX corresponds to the general formula (XXXX634), wherein substituents R, and R2 are defined in Table B, constituting the disclosure of 34 specific compounds of formula XXXX634.

Table 635: A further preferred group of compounds of formula XXXX corresponds to the general formula (XXXX635), wherein substituents R, and R2 are defined in Table B, constituting the disclosure of 34 specific compounds of formula XXXX635 Table 636: A further preferred group of compounds of formula XXXX corresponds to the general formula (XXXX636), wherein substituents R, and R2 are defined in Table B, constituting the disclosure of 34 specific compounds of formula XXXX636.

Table 637: A further preferred group of compounds of formula XXXX corresponds to the general formula (XXXX637), wherein substituents R, and R2 are defined in Table B, constituting the disclosure of 34 specific compounds of formula XXXX637 Table 638: A further preferred group of compounds of formula XXXX corresponds to the general formula (XXXX638), wherein substituents R, and R2 are defined in Table B, constituting the disclosure of 34 specific compounds of formula XXXX638 Table 639: A further preferred group of compounds of formula XXXX corresponds to the general formula (XXXX639), wherein substituents R, and R2 are defined in Table B, constituting the disclosure of 34 specific compounds of formula XXXX639 Table 640: A further preferred group of compounds of formula XXXX corresponds to the general formula (XXXX640), wherein substituents R, and R2 are defined in Table B, constituting the disclosure of 34 specific compounds of formula XXXX640- Table 641: A preferred group of compounds of formula XXXIX corresponds to the general formula (XXXIX641), wherein substituents R, and R2 are defined in Table A, constituting the disclosure of 34 specific compounds of formula XXXIX64 1 Table 642: A further preferred group of compounds of formula XXXIX corresponds to the general formula (XXXIX642), wherein substituents R, and R2 are defined in Table B, constituting the disclosure of 34 specific compounds of formula XXXIX642 Table 643: A further preferred group of compounds of formula XXXIX corresponds to the general formula (XXXIX643), wherein substituents R, and R2 are defined in Table B, constituting the disclosure of 34 specific compounds of formula XXXIX643.

Table 644: A further preferred group of compounds of formula XXXIX corresponds to the general formula (XXXIX644), wherein substituents R, and R2 are defined in Table B, constituting the disclosure of 34 specific compounds of formula XXXIX644.

Table 645: A further preferred group of compounds of formula I corresponds to the general formula (XXXIX645), wherein substituents R, and R2 are defined in Table A, constituting the disclosure of 34 specific compounds of formula XXXIX645- Table 646: A further preferred group of compounds of formula I corresponds to the general formula (XXXIX646), wherein substituents R, and R2 are defined in Table A, constituting the disclosure of 34 specific compounds of formula XXXIX646 Table 647: A further preferred group of compounds of formula I corresponds to the general formula (XXXIX647), wherein substituents R, and R2 are defined in Table A, constituting the disclosure of 34 specific compounds of formula XXXIX647 Table B Cpmd no. R 1 R2 .001F C ! . 002 F CN Cpmd no. R R2 .003 F OCH3 .004 F OCF3 .005 F CF3 .006 F Br .007 F NO2 .008 F CH3 .010 F OCH2C=-CH .011CON . 012 ci OCH3 . 013 CI OCF3 . 014 ci CF3 . 015 ci Br . 016 CI N02 . 017 Cl CH3 Cl.018Cl . 019 Cl CF2H . 020 H F Cl.021H Br.022H . 023 H CF3 . 024 H OCF3 . 025 H N02 . 026 H CN . 027 H i-Pr . 028 F C2H5 . 029 F OCH2CF3 . 030 H OCH2CF3 . 031 H t-Bu . 032 F t-Bu t-Bu.033Cl J.034H Table C: Physicochemical data for prepared compounds from the above tables. The figure before the point indicates the number of the table, e. g. 1.004 means in Table 1 compound no. 004 of Table A and 634.001 means in Table 634 compound no. 001 of Table B.

Cmpd no. physic, data 1.004 nD (40°C) 1.5159 1.038 aD (20°C) + 10. 1 ° 1.352 m. p. 110-112°C 35. 004'H-NMR (CDCI3): 8. 11 ppm (s, 1H); 7.80 ppm (d, 1H); 7.35 ppm (s, 1 H); 4.46 ppm (q, 2H); 1.41 ppm (t, 3H) 600.001 m. p. 133-134°C 608.001 m. p. 91-93°C 609.001 m. p. 114-116°C 617.001 m. p. 143-145°C 625.001 m. p. 140-143°C 626.001 m. p. 143-145°C 631.001 m. p. 154-157°C 634.001 m. p. 162-164°C Examples of specific formulations for active ingredients of formula 1, such as emutsifiabte concentrates, solutions, wettable powders, coating granules, extruder granulates, dusts and suspension concentrates, are described in WO 97/34485 on pages 9-13.

BiologicalExamples Example B1: Preemergence herbicidal action Monocot and dicot test plants are sown in standard soil in plastic pots. Immediately after sowing, the plants are sprayed at a concentration of 2 kg active ingredient/ha with an aqueous suspension of the test compound prepared from a 25% wettable powder (Example F3, b)) according to WO 97/34485) or an emulsion of the test compound prepared from a 25% emulsifiable concentrate (Example F1 c)) according to WO 97/34485) (500 1 of water/ha). The test plants are then cultivated in the greenhouse under optimum conditions.

The test is evaluated 3 weeks later on a rating scale of 1-9 (1 = total damage, 9 = no action). Ratings of 1 to 4 (especially of 1 to 3) denote good to very good herbicidal action.

Test plants: Lolium, Setaria, Sinapis, Solanum, Ipomea.

The compounds of the invention show good herbicidal action.

An example of good herbicidal efficacy of compounds of formula I is given in Table B1.

Table B1: Pre-emergent action: Test plant: Lolium Setaria Sinapis Solanum Ipomea Dose [g a. i./ha] Cmpd No.

1.004 2 1 1 1 1 2000 1.038 7 1 1 2 3 2000 1.352 1 1 1 1 1 2000 The same results are obtained by formulating the compounds of formula I in accordance with Examples F2 and F4 to F8 as described in WO 97/34485.

Example B2: Post-emergent herbicidal action In a greenhouse, monocot and dicot test plants are sown in standard soil in plastic pots and sprayed in the 4-to 6-leaf stage with an aqueous suspension of the test compounds of formula I prepared from a 25 % wettable powder (Example F3, b) according to WO 97/34485) or with an emulsion of the test compound prepared from a 25 % emulsifiable concentrate (Example F1 c)) according to WO 97/34485) at a concentration of 2 kg a. i./ha (500 I of water/ha). The test plants are then further cultivated in the greenhouse under <BR> <BR> <BR> <BR> optimum conditions. The test is evaluated about 18 days later on a rating scale of 1-9 (1 = total damage, 9 = no action). Ratings of 1 to 4 (especially of 1 to 3) denote good to very good herbicidal action. In this test the compounds of formula I exhibit a pronounced herbicidal action.

Test plants: Lolium, Setaria, Sinapis, Solanum, Ipomea.

In this test too the compounds of formula I exhibit a pronounced herbicidal action.

An example of good herbicidal efficacy of compounds of formula I is given in Table B2.

Table B2: Post-emergente action: Test plant: Lolium Setaria Sinapis Solanum Ipomea Dose [g a. i./ha] Cmpd No.

1.004 1 1 1 1 1 2000 1.038 1 1 1 1 1 2000 1.352 1 1 1 1 1 2000 The same results are obtained by formulating the compounds of formula I in accordance with Examples F2 and F4 to F8 as described in WO 97/34485.

The active ingredients of formula I can also be used for weed control by mixing with known herbicides as co-herbicides, for example as ready-for-use formulations or as tank mix.

Suitable compounds for mixing with active ingredients of formula I are for example the following co-herbicides: compound of formula I + acetochlor; compound of formula I + acifluorfen; compound of formula I + aclonifen; compound of formula I + alachlor; compound of formula I + ametryn; compound of formula I + aminotriazol; compound of formula I + amidosulfuron; compound of formula I + asulam; compound of formula I + atrazine; compound of formula I + BAY FOE 5043; compound of formula I + benazolin; compound of formula I + bensulfuron; compound of formula I + bentazone; compound of formula I + bifenox; compound of formula I + bispyribac sodium; compound of formula I + bialaphos; compound of formula I + bromacil; compound of formula I + bromoxynil; compound of formula I + bromophenoxim; compound of formula I + butachlor; compound of formula I + butylate; compound of formula I + cafenstrole; compound of formula I + carbetamide; compound of formula I + chloridazone; compound of formula I + chlorimuron ethyl; compound of formula I + chlorbromuron; compound of formula I + chlorsulfuron; compound of formula I + chlortoluron; compound of formula I + cinosulfuron; compound of formula I + clethodim; compound of formula I + clodinafop; compound of formula I + clomazone; compound of formula I + clopyralid; compound of formula I + cloransulam; compound of formula I + cyanazine; compound of formula I + cyhalofop; compound of formula I + dalapon; compound of formula I + 2,4-D; compound of formula I + 2,4-DB; compound of formula I + desmetryn; compound of formula I + desmedipham; compound of formula I + dicamba; compound of formula I + diclofop; compound of formula I + difenzoquat methyl sulfate; compound of formula I + diflufenican; compound of formula I + dimefuron; compound of formula I + dimepiperate; compound of formula I + dimethachlor; compound of formula I + dimethametryn; compound of formula I + dimethenamid; compound of formula I + S-dimethenamid; compound of formula I + dinitramine; compound of formula I + dinoterb; compound of formula I + dipropetryn; compound of formula I + diuron; compound of formula I + diquat; compound of formula I + DSMA; compound of formula I + EPTC; compound of formula I + esprocarb; compound of formula I + ethalfluralin; compound of formula I + ethametsulfuron; compound of formula I + ethephon; compound of formula I + ethofumesate; compound of formula I + ethoxysulfuron; compound of formula I + fenclorim; compound of formula I + flamprop; compound of formula I + fluazasulfuron; compound of formula I + fluazifop; compound of formula I + flumetralin; compound of formula I + flumetsulam; compound of formula I + fluometuron; compound of formula I + flurchloridone; compound of formula I + fluoxaprop; compound of formula I + fluroxypyr; compound of formula I + fluthiacet-methyl; compound of formula I + fluxofenim; compound of formula I + fomesafen; compound of formula I + glufosinate; compound of formula I + glyphosate; compound of formula I + halosulfuron; compound of formula I + haloxyfop; compound of formula I + hexazinone; compound of formula I + imazamethabenz; compound of formula I + imazapyr; compound of formula I + imazaquin; compound of formula I + imazethapyr; compound of formula I + imazosulfuron; compound of formula I + ioxynil; compound of formula I + isoproturon; compound of formula I + isoxaben; compound of formula I + isoxaflutole; compound of formula I + karbutylate; compound of formula I + lactofen; compound of formula I + lenacil; compound of formula I + linuron; compound of formula I + MCPP; compound of formula I + metamitron; compound of formula I + metazachlor; compound of formula I + methabenzthiazuron; compound of formula I + methazole; compound of formula I + metobromuron; compound of formula I + metolachlor; compound of formula I + S-metolachlor; compound of formula I + metosulam; compound of formula I + metribuzin; compound of formula I + metsulfuron methyl; compound of formula I + molinate; compound of formula I + MCPA; compound of formula I + MSMA; compound of formula I + napropamide; compound of formula I + NDA-402989; compound of formula I + n; compound of formula I + nicosulfuron; compound of formula I + norflurazon; compound of formula I + oryzalin; compound of formula I + oxadiazon; compound of formula I + oxasulfuron; compound of formula I + oxyfluorfen; compound of formula I + paraquat; compound of formula I + pendimethalin; compound of formula I + phenmedipham; compound of formula I + phenoxaprop-P-ethyl (R); compound of formula I + picloram; compound of formula I + pretilachlor; compound of formula I + primisulfuron; compound of formula I + prometon; compound of formula I + prometryn; compound of formula I + propachlor; compound of formula I + propanil; compound of formula I + propazine; compound of formula I + propaquizafop; compound of formula I + propyzamide; compound of formula I + prosulfuron; compound of formula I + pyrazolynate; compound of formula I + pyrazosulfuron ethyl; compound of formula I + pyrazoxyphen; compound of formula I + pyridate; compound of formula I + pyriminobac methyl; compound of formula I + pyrithiobac sodium; compound of formula I + quinclorac; compound of formula I + quizalofop; compound of formula I + rimsulfuron; compound of formula I + sequestren; compound of formula I + sethoxydim; compound of formula I + simetryn; compound of formula I + simazin; compound of formula I + sulcotrione; compound of formula I + sulfosate; compound of formula I + sulfosulfuron methyl; compound of formula I + tebutam; compound of formula I + tebuthiuron; compound of formula I + terbacil; compound of formula I + terbumeton; compound of formula I + terbuthylazin; compound of formula I + terbutryn; compound of formula I + thiazafluron; compound of formula I + thiazopyr; compound of formula I + thifensulfuron methyl; compound of formula I + thiobencarb; compound of formula I + tralkoxydim; compound of formula I + triallate; compound of formula I + triasulfuron; compound of formula I + trifiuralin; compound of formula I + tribenuron methyl; compound of formula I + triclopyr; compound of formula I + triflusulfuron; compound of formula I + trinexapac ethyl, as well as esters and salts of these compounds for mixing with a compound of formula 1, which named for example in The Pesticide Manual, Eleventh Edition, 1997, BCPC.