METHOD FOR PREPARING DIOXYHETEROCYCLE-BASED ELECTROCHROMIC

POLYMERS

CROSS-REFERENCE TO RELATED APPLICATION The present application claims the benefit of of U.S. Provisional Application Serial No. 61/836,206, filed June 18, 2013, which is hereby incorporated by reference herein in its entirety, including any figures, tables, or drawings.

This invention was made with government support under FA9550-09- 1-0320, N00014-1 1-1-0245, and DE-FG0203ER15484 awarded by the United States Air Force, United States Navy and the United States Department of Energy. The government has certain rights in the invention.

BACKGROUND OF INVENTION

The organic electronics community has benefited tremendously from the development of palladium-catalyzed cross-coupling reactions, which offer facile access to a wide range of chemical structures that would otherwise be challenging to achieve. This capability has enabled structure -property relationship studies that provide design parameters for useful organic materials. Improved processability of organic materials encourages these routes because replacement of inorganic semiconductors with organic surrogates has the potential to decrease device fabrication costs significantly. The Pd catalyzed direct arylation of halides or pseudo-halides or their derivatives has been rapidly developing to the point where only minute amounts of undesired side products are generated upon coupling. While the mechanistic details of the Pd insertion to the activated C-H bond are not fully understood, successful protocols have been developed for the coupling of thienyl-based molecules to a wide variety of organic halides.

Dehydrogenative cross-coupling is an attractive method to carry out the synthesis of thiophene-based conjugated polymers. This direct heteroarylation polymerization (DHAP) leads to more easily prepared conjugated polymers than those from standard Suzuki and Stille polymerizations. The absence of phosphine in the reaction mixture avoids any phosphine incorporation into the polymer backbone, which complicates polymer purification. The residual contaminants left in conjugated polymers are associated with poor performances of electronic devices therefrom. Impurities from catalysts, such as those comprising Sn, Pd, and Br, can act as charge trapping sites that hamper efficient charge transport processes. Therefore, minimization or avoidance of such impurities is critical for many applications of these polymers. To this end, the preparation of electrochromic polymers including donor- acceptor DA copolymers by the DHAP method is attractive.

BRIEF SUMMARY

Embodiments of the invention are directed to the preparation of conjugated polymer by the transition metal catalyzed direct arylation of halides or pseudo-halides. The conjugated polymers are formed from the condensation of a first monomer that can be at least one of a 3,4-dioxythiophene, 3,4-dioxyselenophene, 3,4-dioxytellurophene, 3,4-dioxyfuran, or 3,4-dioxypyrrole and, optionally, one or more second conjugated monomers. The polymerization is carried out temperatures in excess of 120 °C, for example, 150 °C and can be carried out without ligands or additives that are often employed in direct arylation reactions. The resulting conjugated polymers display relatively narrow molecular weight dispersities with molecular weights that are equivalent to or higher than the same polymers prepared by other methods, generally having significantly fewer amounts of impurities in the polymers than those by other methods. The monomers employed can be those that provide a single repeating unit to the resulting polymer or can be oligomeric in nature and provide a sequence of repeating units to the resulting polymer.

BRIEF DESCRIPTION OF DRAWINGS

Figure 1 shows a reaction scheme for the preparation of ECP-Magenta with Figure 1A showing a pair of complementary monomers and Figure IB showing a self-complementary monomer, according to an embodiment of the invention.

Figure 2 shows a plot of polymer molecular weight (M _n ) growth■ and dispersity (£>M) growth o vs. polymerization time for ECP-Magenta, according to an embodiment of the invention.

Figure 3 shows gel permeation chromatography (GPC) traces vs. polymerization time for ECP-Magenta, according to an embodiment of the invention. Figure 4 shows a plot of monomer concentrations vs. time for polymerization of complementary monomers to ECP-Magenta, as shown in Figure la), according to an embodiment of the invention.

Figure 5 shows a bar graph for selected impurities after purification by the DHAP method, according to an embodiment of the invention, and comparative OxP, and GRIM methods.

Figure 6 shows a bar graph for selected impurities after purification by the DHAP method using various solvents, according to an embodiment of the invention.

Figure 7A shows absorption and Figure 7B shows emission spectra for ECP-Magenta prepared by comparative OxP and GRIM methods and the DHAP method before and after purification, according to an embodiment of the invention.

Figure 8 shows plots of optical densities vs. fluorescence intensities for ECP-Magenta prepared, according to an embodiment of the invention, before (BP) and after (AP) purification at probe wavelengths: 605-610 (PI), 660-666 (P2), and 725-734 (P3) nm.

Figure 9 shows a reaction scheme for the preparation of ECP-Yellow from a pair of complementary monomers, according to an embodiment of the invention.

Figure 10 shows a reaction scheme for the preparation of ECP-Blue from a pair of complementary monomers, according to an embodiment of the invention.

Figure 11 shows a reaction scheme for the preparation of ECP-Cyan from a pair of complementary monomers, according to an embodiment of the invention.

Figure 12 shows a reaction scheme for the preparation of ECP-Black from a pair of complementary dioxythiophene monomers and 4,7-dibromo-2,l,3-benzothiadiazole 5, according to an embodiment of the invention. DETAILED DISCLOSURE

Embodiments of the invention are directed to an improved method of preparing electrochromic homopolymers and copolymers. The method decreases the number of steps required for the synthesis of 3,4-dioxythiophene-based electrochromic polymers or other dioxyheterocyclic based conjugated polymers, and reduces the amount of many impurities that potentially affect the performance of the polymers. The method involves a direct (hetero)arylation polymerization (DHAP) between an aromatic monomer in a hydrogen form and a halogen substituted aromatic monomer, where at least one of the aromatic monomers is a dioxyheterocyclic aromatic monomer, for example, a 3,4-propylenedioxythiophene comprising monomer. The method involves the use of a transition metal catalyst, such as Pd or Ni catalyst, for example, palladium acetate, and an acid scavenger, for example potassium carbonate, in an aprotic solvent, for example, the polar aprotic solvent dimethylacetamide (DM Ac). In an embodiment of the invention, the polymerization mixture is free of added ligand, for example, is free of a phosphine ligand. In an embodiment of the invention, the polymerization is carried out at a temperature in excess of 120 °C, for example, 140 °C. Advantageously, the method affords resulting polymers that display a narrower molecular weight distribution than does the equivalent polymer prepared at lower temperatures and distributions that are equivalent or lower than the equivalent polymer prepared by alternative synthetic routes, such as Grignard metathesis (GRIM), Stille coupling, Suzuki coupling, or oxidative polymerization (OxP). Therefore, a quality polymer can be prepared with few impurities, particularly metallic impurities, without extensive, costly, and time-consuming purification steps.

Advantageously, the catalyst is used at a level that is less than 5 mole percent of the monomer concentration, for example, less than 4 mole percent, less than 3 mole percent, less than 2 mole percent, or less than 1 mole percent. The catalyst must be present in at least 0.0001 mole percent. The Pd catalyst can be provided in the form of palladium diacetate, palladium di-trifluoroacetate, bis(dibenzylideneacetone)palladium(0), or other source of Pd known as a catalyst or precatalyst for a cross-coupling reaction such as a Negishi, Suzuki, Stille, Heck, Sonogashira, or Buchwald-Hartwig reaction, in addition to direct aromatic coupling reactions. _^ Ni catalyst can be provided in the form of nickel acetate, bis(dibenzylideneacetone)nickel(0), nickel acetylacetonate, or other source of Ni known as a catalyst or precatalyst for a cross-coupling reaction such as Kumada or Grignard metathesis reaction, in addition to direct aromatic coupling reactions. -In an embodiment of the invention, the transition metal source is free of a phosphine ligand. The reaction is performed in the presence of pivalic acid or other aliphatic carboxylic acid. The reaction is carried out in an aprotic solvent, generally, but not necessarily a polar solvent, for example, a solvent with a dielectric constant in excess of 25. Furthermore, the solvent has a boiling point in excess of the polymerization temperature, for example, above 150 °C, at the pressure that the polymerization is carried out. For example, the solvent can have a boiling point in excess of 150 °C for a reaction carried out at one atmosphere of pressure, such that the reaction can be carried out without a significant build in pressure up to 150 °C. Solvents that can be employed include, but are not limited to dimethylformamide (DMF), DMAc, N- methylpyrolidone (ΝΜΡ), hexamethylphosporamide (HMPA), dimethylsulfoxide (DMSO), and propylene carbonate.

In embodiments of the invention, the monomer mixture comprises at least one first monomer that is a 3 ,4-dioxythiophene, 3,4-dioxyselenophene, 3,4-dioxytellurophene, 3,4- dioxyfuran, or 3,4-dioxypyrrole of the structure:

where x is 0 to 3; L is independently H, CI, Br, I, OTs, OTf, CN, OCN, SCN, or any other pseudohalide, X is S, Se, Te, O, or NR; R is independently H, alkyl, aryl, substituted alkyl, or substituted aryl, oligoether, aminoalkyl, bydroxyalkyl, alkoxyalkyl, acyloxyalkyl, HOS(0) ₂ alkyl, HOC(0)alkyl, (HO) ₂ P(0)alkyl, aminoaryl, hydroxyaryl, alkoxyaryl, acyloxyaryl, HOS(0) ₂ aryl, HOC(0)aryl or (HO) ₂ P(0)aryl, -(CH ₂ ) _m -YC(0)R ² , -(CH ₂ ) _m - C(0)YR ² , -(CH ₂ ) _m -0-(CH ₂ ) _v YC(0)R ² , -(CH ₂ ) _m -0-(CH ₂ ) _v C(0)YR ² , -(CH ₂ ) _m - OCH _z (CH ₃ ) _y [(CH ₂ ) _w YC(0)R ] _3-z , · -(CH ₂ ) _m -OCH _z (CH ₃ ) _y [(CH ₂ ) _w C(0)YR ² ] ₃ . _z , or two R groups on adjacent carbons in combination are alkylene, arylene, substituted alkylene, or substituted arylene; m is 1 to 8; y is 0 to 2; z is 0 to 2; y+z is 0 to 2; w is 1 to 8; v is 2 to 8; Y is O, S, or NR ³ , R ² is a straight chained, branched chain, cyclic or substituted cyclic alkyl group of 1 to 12 carbons; and R is a straight chained, branched chain, cyclic or substituted cyclic alkyl group of 1 to 6 carbons.

Alkyl is a straight or branched chain of, for example, 1-24 carbon atoms and is, for example, methyl, ethyl, n-propyl, n-butyl, sec butyl, tert-butyl, n-hexyl, n-octyl, 2-ethylhexyl, n-nonyl, n-decyl, n-undecyl, n-dodecyl, n-tridecyl, n-tetradecyl, n-hexadecyl, n-octadecyl or dodecanyl and the like. Alkylene is a chain of, for example, 1-12 carbon atoms and is, for example, methylene, ethylene, propylene, butylene, pentalene, hexylene, octylene, 2- ethylhexyl, n-nonyl, n-decylene or dodecylene and the like; for example, methylene, ethylene, propylene or butylene. The alkyl or alkylene may be interrupted, one or more times, by one or more oxygen atoms, sulfur atoms, -SO-, -S0 ₂ -, carbonyl, -COO-, -CONH-, - NH-,-CON(Ci-8 alkyl)- or -N(Ci.g alkyl)- and the like. For example, the alkyl group may be interrupted, one or more times, by one or more oxygen atoms, sulfur atoms, carbonyl, -COO-, -NH- or -N(Ci-8 alkyl)-. The uninterrupted or interrupted alkyl or alkylene may also be substituted, one or more times, by one or more C3.6 cycloalkyl groups, halogen, -OR, -COOR, -COOM, -SO3M, -SO ₃ H, phosphonic acid, halogen, -CONR ⁸ ₂ , -NR ⁸ ₂ , phosphonate salt, ammonium salt or group of the formulae -Z-Ar or -C(0)-Z-Ar wherein M is a nitrogen cation or metal cation, R ⁸ is independently hydrogen; a group -Z-Ar, -C(0)-Z-Ar, or -C(O)- O-Z-Ar; C _1-2 4 alkyl, C _3-2 4 alkenyl, C3. cycloalkyl or C _1-2 4 alkylcarbonyl which is uninterrupted or interrupted, one or more times, by one or more oxygen atoms, sulfur atoms, carbonyl, -COO-, -CONH-, -NH-, -CON(Ci. _g alkyl)- or -N(Ci _-g alkyl)-, where uninterrupted or interrupted alkyl, alkenyl, cycloalkyl or alkylcarbonyl are unsubstituted or substituted, one or more times, by one or more halogen, -OH, C7 2 aralkyl, C ₂ . ₁₂ alkylcarbonyl, Ci _-24 alkoxy, C ₂ -24 alkylcarboxy, -COOM, -CONH ₂ , -CON(H)(Ci _-8 alkyl), -CON(C _1-8 alkyl) ₂ , -NH ₂ , - N(H)(Ci_8 alkyl), -N(Cj _-8 alkyl) ₂ , -S0 ₃ M, phenyl, phenyl substituted, one or more times, by one or more C _]-8 alkyl, naphthyl, naphthyl substituted, one or more times, by one or more Q-s alkyl ammonium salt, phosphonic acid or phosphonate salt or when attached to a nitrogen atom, R and R', together with the nitrogen atom to which they are attached, form a 5-, 6- or 7-membered ring that is uninterrupted or interrupted by -0-, -NH- or -N(Cj. ₁₂ alkyl)-; Z is a direct bond or Ci _-12 alkylene that is uninterrupted or interrupted by one or more oxygen atoms and is unsubstituted or substituted, one or more times, by one or more -OH, halogen, Ci- ₈ alkyl, C _1-24 alkoxy, C _2-2 4alkylcarboxy, -NH ₂ , -N(H)(Ci_ ₈ alkyl), -N(Ci _-8 alkyl) ₂ or ammonium salt; Ar is C _6-1 o aromatic or C1-9 saturated or unsaturated heterocycle that is unsubstituted or substituted, one or more times, by one or more halogen, -OH, Ci _-24 alkoxy, C2-24 alkylcarboxy, -COOQ -CONH ₂ , -CON(H)(Ci _-8 alkyl), -CON(C _1-8 alkyl) ₂ , -NH ₂ , N(H)(C _1-8 alkyl), -N(Ci _-8 alkyl) ₂ , -SO ₃ M, SO ₃ H, ammonium salt, phosphonic acid, phosphonate salt, , ₂ 4 alkyl that is unsubstituted or substituted, one or more times, by one or more halogen, wherein Q is hydrogen, metal cation, glycol ether, phenyl or benzyl, or phenyl or benzyl substituted, one or more times, by one or more halogen, hydroxy, C _1-24 alkoxy or Ci _-12 alkyl.

Additionally, alkylene or interrupted alkylene may also be substituted by a group -Z- Ar, -C(0)-Z-Ar, or -C(0)-0-Z-Ar; C _1-24 alkyl, C _3-6 cycloalkyl or C _1-2 4 alkylcarbonyl that is uninterrupted or interrupted, one or more times, by one or more oxygen atoms, sulfur atoms, carbonyl, -COO-, -CONH-, -NH-,-CON(C _{] -8} alkyl)- or -N(Ci _-g alkyl)- that is uninterrupted or interrupted alkyl, cycloalkyl or alkylcarbonyl and is unsubstituted or substituted, one or more times, by one or more halogen, -OH, C ₇ . ₁₂ aralkyl, C _2-12 alkylcarbonyl, Ci. ₂₄ alkoxy, C ₂ _24 alkylcarboxy, -COOM, -CONH ₂ , -CON(H)(C _]-8 alkyl), -CON(Ci- ₈ alkyl) ₂ , -NH ₂ , -N(H)(C _]-8 alkyl), -N(Ci-s alkyl) ₂ , -S0 ₃ M, phenyl, phenyl substituted, one or more times, by one or more Ci-8 alkyl, naphthyl, naphthyl substituted, one or more times, by one or more Ci-g alkyl, ammonium salt, phosphonic acid or phosphonate salt or when attached to a nitrogen atom, R and R\ together with the nitrogen atom to which they are attached, form a 5-, 6- or 7- membered ring that is uninterrupted or interrupted by -0-, -NH- or -N(Ci_i ₂ alkyl)-.

In embodiments of the invention, the 3,4-dioxythiophene, 3,4-dioxyselenophene, 3,4- dioxytellurophene, 3 ,4-dioxyfuran, or 3,4-dioxypyrrole first monomer is co-polymerized with one or more second monomers. The second monomer is a substituted or unsubstituted conjugated monomer or oligomer bearing a pair of L = H, CI, Br, I, OTs, OTf, CN, OCN, SCN, or any pseudohalides at appropriate positions. The second monomer can be, for example but not limited to, ethene, carbazole, fluorene, benzothiadiazole, thiadiazoloquinoxaline, quinoline, quinoxaline, thienothiadiazole, thienopyrazine, pyrazinoquinoxaline, benzobisthiadiazole, thiadiazolothienopyrazine, thiophene, pyrrole, furan, selenophene, telurophene, thieno[3,2-6 thiophene, dithieno[3,2-0:2\3'-</Jthiophene, benzo[c][l,2,5]thiadiazole, benzo[c][l,2,5]-oxadiazole, benzo[d][l,2,3]triazole, pyrido[3,4- b]pyrazine, cyanovinylene, thiazolo[5,4-d]thiazole, 1,3,4-oxadiazole, 1,3,4-thiadiazole, 1,3,4- triazole, pyrrolo[3,4-c]pyrrole-l,4-dione, 2,2'-bithiazole, [l,2,5]thiadiazole-[3,4-c]pyridine, thieno[3,4-b]pyrazine, [l,2,5]oxadiazolo[3,4-c]pyridine, dicyanovinylene, benzo[l,2-c;4,5- c']bis[ 1 ,2,5]thiadiazole, [ 1 ,2,5]thiadiazolo-[3 ,4-g]quinoxaline, cyclopentadithiophene-4-one, 4-dicyano-methylenecyclopentadithiolene, benzo[c]thiophene, isoindigo, indigo, 4,4'- bis(alkyl)-[6,6'-bithieno[3,2-b]pyrrolylidene]-5,5'(4H,4'H)- dione (a.k.a. dithienoketopyrrole or thienoisoindigo), phenanthrene, phenanthrene-9,10-dione, benzo[l,2-b:6,5-b']dithiophene- 4,5-dione, napthalenediimide, perylenediimide, any aromatic of the structure:

where: L is independently H, CI, Br, I, OTs, OTf, CN, OCN, SCN, or other pseudohalide; X is NR\ PR', S, O, Se, Te, CR ₂ , SiR' ₂ , GeR' ₂ , BR', or SO _x where x = 1 or 2; Z is NR', PR', S, O, Se, or Te; R' is independently H, Ci-C ₃₀ alkyl, C ₂ -C ₃₀ alkenyl, C ₂ -C ₃ o alkynyl, C6-Ci ₄ aryl, C7-C30 arylalkyl, C ₈ -C ₃₀ arylalkenyl, C ₈ -C ₃ o arylalkynyl, Ci-C ₃₀ hydroxyalkyl, C6-Q ₄ hydroxyaryl, C ₇ -C30 hydroxyarylalkyl, C3-C30 hydroxyalkenyl, C3-C30 hydroxyalkynyl, Cs-C ₃ o hydroxyarylalkenyl, Q-C30 hydroxyarylalkynyl, C3-C30 polyether, C3-C30 polyetherester, C ₃ - C30 polyester, C3-C30 polyamino, C3-C30 polyaminoamido, C3-C30 polyaminoether, C3-C30 polyaminoester, C3-C30 polyamidoester, C3-C ₃ oalkylsulfonic acid, C ₃ -C ₃ oalkylsulfonate salt, C1-C30 alkylcarboxylate salt, C1-C30 alkylthiocarboxylate salt, C1-C30 alkyldithiocarboxylate salt or C3-C30 alkyl C1-C4 trialkyammonium salt; and R is independently H, C1-C30 alkyl, C ₂ - C30 alkenyl, C ₂ -C ₃ o alkynyl, C6-Ci ₄ aryl, C7-C30 arylalkyl, C ₈ -C ₃ o arylalkenyl, Q-C30 arylalkynyl, hydroxy, C0 ₂ H, C2-C30 alkylester, C7-C15 arylester, Cg-Cso alkylarylester, C3-C30 alkenylester, C3-C30 alkynylester, NH ₂ , C1-C30 alkylamino, C6-C ₁₄ arylamino, C7-C30 (arylalkyl)amino, C ₂ -C3o alkenylamino, C ₂ -C ₃₀ alkynylamino, C8-C30 (arylalkenyl)amino, Cg- C30 (arylalkynyl)amino,C ₂ -C3o dialkylamino, C12-C28 diarylamino, C4-C30 dialkenylamino, C ₄ - C ₃ 0 dialkynylamino, C ₇ -C ₃₀ aryl(alkyl)amino, C7-C30 di(arylalkyl)amino, C8-C30 alkyl(arylalkyl)amino, C ₁₅ -C ₃ o aryl(arylalkyl)amino, Cs-C ₃ o alkenyl(aryl)amino, C8-C30 alkynyl(aryl)amino C(0)NH ₂ (amido), C ₂ -C o alkylamido, C7-C14 arylamido, C ₈ -C ₃ o (arylalkyl)amido, C ₂ -C3o dialkylamido, Ci ₂ -C ₂₈ diarylamido, C8-C30 aryl(alkyl)amido, C15-C30 di(arylalkyl)amido, C9-C30 alkyl(arylalkyl)amido, C _lf j-C ₃ o aryl(arylalkyl)amido, thiol, C1-C30 hydroxyalkyl, C ₆ -C)4 hydroxyaryl, C7-C30 hydroxyarylalkyl, C3-C30 hydroxyalkenyl, C3-C30 hydroxy alkynyl, C8-C30 hydroxyarylalkenyl, C ₈ -C ₃₀ hydroxyarylalkynyl, C3-C30 polyether, C3-C30 polyetherester, C3-C30 polyester, C3-C30 polyamino, C3-C30 polyaminoamido, C3-C30 polyaminoether, C3-C30 polyaminoester, C3-C30 polyamidoester, C3-C30 alkylsulfonic acid, C3-C ₃ oalkylsulfonate salt, C1-C30 carboxylate salt, Ci-C3o thiocarboxylate salt, C1-C30 dithiocarboxylate salt, or C3-C30 alkylC]-C ₄ trialkyammonium salt.

In an embodiment of the invention, L = hydrogen is, to the extent possible by normal methods of preparing polymerization mixtures, half of all L substituents of the first and/or optional second monomers combined into the polymerization mixture. In other embodiments of the invention a desired stoichiometric excess of hydrogen or non-hydrogen L substituents are included in the polymerization mixture to define the maximum degree of polymerization that can be achieved or to promote specific L substituents on as many of the polymer chain ends as possible. For purposes of the invention, a polymer has at least four repeating units, at least six repeating units, at least 10 repeating units, at least 15 repeating units, at least 20 repeating units, or at least 25 repeating units. For example, in a homopolymerization, the first monomer can be a single first monomer that has one hydrogen and one non-hydrogen L substituent. For example, in a homopolymerization, the first monomer can be a pair of monomers, one where both L groups are hydrogen and one where both L groups are non- hydrogen. For example, in a random copolymerization two different first monomers can have one hydrogen and one non-hydrogen L substituent. For example, in an alternating copolymerization a first monomer can have two hydrogen L substituents and an additional first monomer can have two non-hydrogen L substituents. In a quasi-random copolymerization, a portion of a first monomer can have two hydrogen L substituents and a portion of the first monomer can have two non-hydrogen L substituents, and an additional first monomer can have two hydrogen L substituents such that isolated monades of the additional first monomer are dispersed between random length sequences of the first monomer.

In an embodiment of the invention, a copolymerization of at least one first monomer and at least one second monomer can be carried out. For example, a regular copolymer with alternating first and second monomers can be carried out where, for example, the first monomer has hydrogen L substituents and the second monomer has non-hydrogen L substituents. For example, in a random copolymerization, the first monomer and second monomer each have one hydrogen and one non-hydrogen L substituents; or a mixture of first monomers, one with two hydrogen L substituents and another with two non-hydrogen L substituents, is copolymerized with a mixture of second monomers, one with two hydrogen L substituents and another with two non-hydrogen L substituents. In a quasi-random copolymerization, a portion of a first monomer can have two hydrogen L substituents and a portion of the first monomer can have two non-hydrogen L substituents, and second monomer can have two hydrogen or two non-hydrogen L substituents such that isolated monades of the second monomer are dispersed between random length sequences of the first monomer.

In an embodiment of the invention, a copolymerization may be carried out with a plurality of additions of monomers or by the combination of a plurality of polymerization mixtures to bias the repeating unit sequences of the first monomers and/or second monomers in the resulting copolymers. For example, a polymerization mixture of a first monomer with a stoichiometric excess of hydrogen L substituents to yield oligomers with only hydrogen L substituents can be combined with a polymerization mixture of a second monomer with a stoichiometric excess of non-hydrogen L substituents to yield oligomers with only non- hydrogen L substituents. In this manner, the sequence length of first monomers and sequence length of second monomers can be different from that of a copolymer with the same proportion of first and second monomers made by a single polymerization of the total mixture of first and second monomers in a single charge of monomers.

In an embodiment of the invention, the temperature of the polymerization is in excess of 120 °C. The temperature can be maintained at or above, for example, 120 °C, 125 °C, 130 °C, 135 °C, 140 °C, 145 °C, or 150 °C. Not only do these higher temperature promote a more rapid polymerization, but, surprisingly, the molecular weight distribution (dispersity) was observed to be narrower than that of lower temperatures with the achievement of higher degrees of polymerization. For example, at a degree of polymerization (DP) of 23, the polymer ECP-Magenta achieved a dispersity of 1.64 with an isolated yield of 87%, whereas the normal Flory-Schultz distribution for that dispersity is 1.96, and a structurally similar poly(3,3-Bis(hexyloxymethyl)-3,4-dihydro-2H-thieno[3,4-b][l ,4]-dioxepine prepared at 100 °C achieved a DP of 25 with a D _M of 1.80, as reported in Zhao et al , Macromolecules 2012, 45, 7783-90.

In an embodiment of the invention, no additive, for example a phosphine ligand or a phase transfer reagent is included in the polymerization mixture. The use of a ligand or phase transfer reagent, particularly phosphine comprising ligands, has been shown to produce low £> with moderate DP at temperatures of 100 °C for 3,4-dioxythiophenes with solubilizing substituents; however, this occurs with the increase in impurities in the final polymer.

Homopolymerizations of ECP-Magenta, as shown in Figure 1 , were employed for exemplary polymerizations by the cross-condensation of 3,3-bis((2-ethylhexyloxy) methyl)- 3,4-dihydro-2H-thieno[3,4-b][l ,4]dioxepine (1) and 6,8-dibromo-3,3-bis((2- ethylhexyloxy)methyl)-3,4-dihydro-2H-thieno[3,4-b][l ,4]dioxepine (2) or the self- condensation of 6-bromo-3,3-bis((2-ethylhexyloxy)methyl)-3,4-dihydro-2H-thie no[3,4- b] [l ,4] dioxepine (3), according to an embodiment of the invention, to compare with oxidative polymerization (OxP) and Grignard metathesis (GRIM), polymerization. OxP yields ECP-Magenta with the number average molecular weight (M _n ) of 30 kDa, where large amounts of FeCl ₃ (>4 equivalents) are necessary to achieve high M _n . The purification of the OxP produced ECP-Magenta was complicated by the large amount of residual Fe/Fe(II)/Fe(lII) in the composition. Grignard metathesis (GRIM) polymerization provides high M _n (M _n = 10-48 kDa), where the removal of impurities requires multiple days of Soxhlet extraction. The synthesis and purification of ECP-Magenta by DHAP, according to an embodiment of an invention, is easily completed in less than one day. Temperature has a significant influence on the product in addition to the rate of polymerization. Polymerization is slow at 80-100 °C, and is rapid at 140 °C, according to an embodiment of the invention.

To evaluate the evolution of molecular weight, M _n , and monomer consumption during DHAP, small aliquots (1-2 mL) of the reaction mixture were removed and precipitated in a 1 : 1 cone. HChMeOH mixture, extracted with DCM, and concentrated. The resulting polymers were analyzed by GPC and ¹ HNMR. The plot of M _n and DM, versus polymerization time is shown in Figure 2. The data indicates that the polymer grows rapidly, and then remains at a nearly constant DP with a relatively narrow dispersity. GPC traces, as shown in Figure 3, display rapid oligomer formation with nearly complete monomer consumption, as indicated in Figure 4, followed by slower oligomer coupling over about 24 hours. Good isolated yields (80- 90 %) of the polymer aliquots were achieved after precipitating the polymers in 1 : 1 MeOH/1 N aqueous HC1 solution with vigorous stirring followed by filtration and washing with copious amounts of water (until AgCl test is negative) and a final washing with MeOH. An M _n > 10 kDa against polystyrene standards with a narrow dispersity (f½ - 1.6) was achieved within 3 to 15 hours, where after 3 hours, an M _n of 10.0 kDa, with a D _M of 1.59 progressed to an M _n of 10.6 kDa and a £ ⁾ _M of 1.64 after 15 hours. Other polar aprotic solvents such as NMP and HMPA also provide narrow molecular weight distributions but provided higher DPs, as shown in Table 1, below.

Table 1 Preparation of ECP-Magenta via DHAP in various solvents.

Solvent ε Time (h) Yield (%) M _n (kDa) D _M

DMAc 38 15 87 10.6 1.64

NMP 32 24 82 23.0 1.74

HMPA 31 24 80 26.3 2.52

ε = Dielectric constant

Additional purifications of ECP-Magentas prepared by DHAP, OxP, and GRIM, were carried out by dissolving the precipitated polymers in chlorobenzene at 50 °C, treating with a Pd-scavenger, diethylammonium diethyldithiocarbamate, and 18-crown-6 to remove residual potassium salts, followed by precipitating in MeOH, filtering, washings with MeOH and hexanes, and drying under vacuum overnight. The rigorous purification provides little differences in M _n values or H NMR spectra from the polymers prior to precipitation; however, the ability to achieve a polymer with few metal ion impurities was superior for DHAP under this precipitation procedure, as indicated if Figure 5. Similar analysis was carried out for ECP-Magentas prepared by DHAP prepared in DMAc, NMP and HMPA, where, as shown in Figure 6, the residual Pd and P was significantly higher in HMPA, as indicated in Table 2, below.

Table 2 Elemental concentrations (ppm) for ECP-Magenta samples prepared in various solvents

NMP DMAc HMPA

Element BP AP BP AP BP AP

Li 3.5 1.4 7.0 1.3 5.4 0.7

B 23.6 7.8 6.7 6.8 8.1 5.4

Na 82.2 17.9 98.1 37.9 844.8 566.3

Mg 7.49 9.75 bdl 56.08 9.83 48.93

Al bdl 5.57 2.65 141.13 bdl 26.17

Si 401 1826 1072 15487 1446 13884

P 6.2 2.5 21.4 22.8 17764 88.3

K 1109 277 33694 442 25967 406

Ca 357.2 217.9 162.6 383.1 254.1 320.6

Ti 0.25 0.96 bdl 1.52 bdl 2.15

Cr 45.59 40.96 25.31 59.76 15.87 26.41

Mn 1.89 1.82 1.43 3.14 1.42 2.19

Fe 0.73 10.64 35.76 91.95 44.98 50.68

Ni 1.21 2.37 6.42 6.09 6.43 4.02

Cu 3.35 1.82 7.36 3.23 6.65 2.09

Zn 36.24 14.53 42.44 10.99 1510 24.90

Ge 6.49 8.26 5.53 11.52 6.29 8.83

Rb 0.70 0.60 1.64 0.83 1.55 0.60

Sr 3.14 3.38 2.50 5.01 4.39 4.71

Y 0.43 0.47 0.30 1.12 0.36 0.76

Pd 756.0 9.3 1132.4 11.4 2924.6 528.4

Ag 5.3 4.0 2.7 4.9 3.1 4.2

Sn 4.13 2.10 1.64 3.36 2.32 2.97

Te 13.24 14.27 9.30 17.48 10.99 15.15

Ba 1.79 3.44 1.67 6.07 9.08 10.20 bdl: below detection limit.

Figure 7 shows UV-Vis absorption and emission spectra of toluene solutions of ECP- Magentas synthesized by different methods. Absorption spectra are nearly identical, except for the low energy maximum localized at 595. However, the solution fluorescence differs more noticeably; the OxP and DHAP polymer before purification presented the reddest shifted spectra relative to the GRIM and DHAP after purification polymers. The lower fluorescence yield of the DHAP sample before purification appears to indicate non-radiative decay paths due to residual Pd content, as shown in Figure 8.

Table 3, below, gives the results of DHAP polymerizations, according to embodiments of the invention, where various electrochromic polymers that are alternating copolymers or quasi-random copolymers, with isolated non-dioxyhetereocycle repeating units, were performed using a common dioxythiophene donor in NMP, as indicated in Figures 9 through 12. All DHAP polymerizations afforded high molecular weight in good yields, where only ECP-Blue did not meet or exceed DPs achieved by other polymerization methods. Although EPC-Cyan was not characterized by GPC due to its insolubility in THF, its insolubility in DHAP suggests a higher M„ than that prepared by OxP, which does permit GPC characterization in THF.

Table 3 Synthesis of ECPs by DHAP in NMP

Polymer Yield (%) M„ (kDa) DM DP

ECP-Magenta 82 23.0 1.74 52

ECP-Yellow 76 27,5 1.19 53

ECP-Blue 81 9,41 1.54 16

ECP-Cyan 89 - - -

ECP-Black 76 11.0 2.03 - Toluene solutions of the ECPs were sprayed onto ITO slides, which were characterized by UV-Vis spectrophotometry. The ECP-Magenta film exhibits good color purity and excellent contrast (Δ% T = 79% at 530 nm) which was similar to the best performing ECP-Magenta prepared by other methods (Δ% T = 80% at 609 nm). Upon comparison of spectroelectrochemical curves of the DHAP prepared EPC polymers with that reported in the literature, no significant differences in performance is discernible, except for ECP-Blue, which displays a smaller contrast than that prepared with a higher M _n . This implies that the contrast is a function that depends on the polymer's M _n whether or not the polymer contains residual impurities. Nevertheless, because of its mass efficiency, shorter production times, and simpler purification procedures, the DHAP method according to an embodiment of the invention, is a cost effective method for the synthesis of the full color palette of ECPs. The resulting polymers are often of narrow dispersity and can be of relatively high Degree of Polymerization (DP) where the DP is at least 10 and typically in excess of 15. METHODS AND MATERIALS

Commercially available reagents were used as received from the chemical suppliers. Reactions that required anhydrous conditions were carried out under an inert atmosphere of argon in flame-dried glassware. Toluene and THF were dried using a solvent purification system (MBraun MB Auto-SPS). The rest of solvents used for synthetic purposes were purified using conventional protocols, except glacial acetic acid which was used as received. All reactions were monitored using F250 silica gel 60 M analytical TLC plates, with UV detection (λ = 254 and 365 nm). Silica gel (60A, 40-63 μιτι) was used as stationary phase for column chromatography. NMR experiments were acquired with working frequencies of 300 MHz for Ή, and 75.5 MHz for ¹³ C experiments. The shifts were reported in parts per million (ppm) and referenced to the residual resonance signals of commercially available deuterated chloroform: δΗ = 7.26 ppm, 5C = 77.0 ppm. High-resolution mass spectra were recorded on a quadrupole mass analyzer instrument equipped with a direct insertion probe (ionization 70 eV) and an electron spray ionizer. Gel permeation chromatography (GPC) was performed using a Waters Associates GPCV2000 liquid chromatography with is internal differential refractive index detector at 40 °C, using two Waters Styragel HR-5E column (10 mm PD, 7.8 mm i.d., 300 mm length) with HPLC grade THF as the mobile phase at flow rate of 1.0 mL/min. The polymer was dissolved initially in THF (2 mg/mL), and allowed to solubilize for 24-48 hour period, in which the solution was filtered through a Millipore 0.5 μιη filter. Injections of ~200 μΐ _^ were performed and retention times were calibrated against narrow molecular weight polystyrene standards.

All reagents used for ICP-MS elemental analyses were Optima-grade and the sample preparation was done under a clean lab environment in the Department of Geological Sciences at the University of Florida. Polymer samples were digested in pre-cleaned Savillex PFA vials with aqua regia (3 mL HC1 and 1 mL HNO3) overnight on a hot plate at 120°C. During the aqua regia digestion the polymer samples turn into a yellowish transparent mass. Although no complete dissolution of the polymer is achieved, it is expected that the elements of interest will be transferred quantitatively in solution. After digestion, part of the aqua regia solution is further diluted with 5% HNO ₃ and loaded in the ICP-MS for analysis. Elemental analyses were performed on a ThermoFinnigan Element2 HR-ICP-MS in medium resolution mode. Quantification of results was perfoimed with external calibration using a combination of commercially available standards gravimetrically diluted to appropriate concentrations. All concentrations are reported in ppm in the polymer. Electrochemistry was carried out in 0.1 M TBAPF ₆ /propylene carbonate solutions, using a standard 3-electrode system: the reference electrode was Ag|Ag+ (10 mM AgNO ₃ /0.5 M TBAPF ₆ /ACN solution) calibrated against the Fc|Fc+ (VF _C/ F _C + ⁼ 1 mV), the counter electrode was a Pt-wire, and the working electrode was an ITO-coated glass slide (7 ^χ 50 ^χ 0.7 mm3, 20 Ω/sq) from Delta Technologies Ltd. Propylene carbonate was dried using a Vacuum Atmospheres SPS. All electrochemical measurements were carried out using an EG&G PAR galvanostat/potentiostat PC-controlled using Scribner Associates 169 CorrWare II software. Absorption spectra were recorded in a double-beam Varian Cary 5000 UV-Vis-NIR spectrophotometer; the baseline correction included solution, ITO-slide, and glass cuvette. Fluorescence spectra were recorded in a Fluorolog-1057 from Horiba-Jovin-Yvon: the samples were excited using a standard 450 W xenon CW lamp and the fluorescence was detected using a multialkali PMT (250-850 nm). Correction factors for lamp signal and detector dark counts were applied using the FluorEssence® software from HJY.

6,8-dibromo-3,3-bis((2-ethylhexyloxy)methyl)-3,4-dihydro-2H- thieno[3,4-b] [l,4] dioxepine (2) and 6-bromo-3,3-bis((2-ethyIhexyloxy)niethyl)-3,4-dihydro-2H-thi eno[3,4- b] [1,4] dioxepine (3) : 3 ,3 -bis((2-ethylhexyloxy)methyl)-3 ,4-dihydro-2H-thieno [3 ,4-b] [ 1 ,4] dioxepine (1, 12.1 g, 27.5 mmol) was dissolved in chloroform (50 mL) and covered from light using aluminum foil. After cooling the mixture in an ice/water bath, N- bromosuccinimide (5.4 g, 30.2 mmol) was added in small portions. The bath was removed, and the mixture was kept for 8 hours at room temperature. Water (25 mL) was added and the heterogeneous mixture was transferred to a separation funnel. After shaking, the layers separated and the aqueous layer was further extracted with DCM (3 x50 mL). The organic mixtures were combined, dried over MgS04, filtered, and evaporated to dryness. The residual light yellow oil was purified via column chromatography in hexanes. (2): Light yellow oil. 6.4 g, 39% yield. (MS, Ή NMR) >H NMR (300 MHz, CDC13, δ): 4.09 (s, 4H), 3.47 (s, 4H), 3.24 (d, 4H), 1.2-1.6 (m,18H), 0.8-1.0 (m, 12H). LRMS: [Μ·+] 598.51, expected for C25H4204SBr2: 598.47. (3): Light yellow oil. 4.7 g, 33% yield. 1H NMR (300 MHz, CDC13, δ):6.44 (s, 1H), 3.98-4.10 (d, J = 2.4 Hz, 4H), 3.47 (s, 4H), 3.24-3.30 (d, J = 0.6 Hz, 4H), 1.15-1.55 (m, 18H), 0.80-0.95 (m, 12H). HRMS: [Μ·+] 518.2052, expected for C ₂ 5H430 ₄ SBr: 518.2065.

3,3,3',3 ^, -tetrakis(((2-ethylhexyl)oxy)methyl)-3,3',4,4'-tetrahy dro-2H,2'H-6,6'- bithieno[3,4 -b] [1,4] dioxepine (6): Compound 1 (2.0 g, 4.5 mmol) was dissolved in anhydrous THF (25 mL) under argon. The mixture was cooled in a dry ice/acetone bath followed by dropwise addition of «-BuLi (2.89 M in hexanes, 1.6 mL, 0.5 mmol). The yellow mixture was warmed in an ice/water bath and slowly transferred to a suspension of Fe(acac) ₃ in THF at room temperature via a cannula. The mixture was heated to gentle reflux and stirred overnight. The resulting suspension was filtered through silica gel and eluted with hexanes until no product was observed in the filtrate by TLC. The resulting organic solution was evaporated to dryness and purified via flash chromatography using hexanes as eluent. Colorless oil was obtained (1.35 g, 68 % yield). Ή NMR (300 MHz, CDC13, δ):6.36 (s, 2H), 4.00-4.12 (d, J - 2.4 Hz, 8H), 3.50 (s, 8H), 3.25-3.31 (d, J = 0.6 Hz), 1.42-1.54 (m, 4H), 1.20-1.42 (m, 36H), 0.80-1.00 (m, 24H). HRMS: [Μ·+] 878.5743, expected for C ₅ oH ₈₆ 0 ₈ S ₂ : 878.5764.

ECP-Magenta (A), as schematically illustrated in Figure la): To an oven dried Schlenk tube fitted with a magnetic stir bar Pd(OAc) ₂ (2.25 mg, 2 mol%), K ₂ C0 ₃ (173 mg, 1.3 mmol), and Pivalic Acid (0.01 g, 0.15 mmol) were added sequentially. The reaction flask was evacuated for a total of ten minutes, and purged with anhydrous argon. The evacuation/gas filling sequence was repeated three times. A vial was loaded with 6,8- dibromo-3 ,3-bis((2-ethylhexyloxy)methyl)-3,4-dihydro-2H-thieno[3,4- b] [1 ,4]dioxepine (2, 299 mg, 0.5 mmol), and 3,3-bis((2-ethylhexyloxy)methyl)-3,4-dihydro-2H-thieno[3,4- b][l,4]dioxepine (1, 220mg, 0.5 mmol). After evacuating for 10 minutes, argon saturated solvent (2 mL), either DMAc, NMP, or HMPA, was added via argon flushed syringe. The resulting solution was transferred to a Schlenk tube via a syringe. The vial was washed twice with 2 mL of Ar-saturated solvent, with each washing being transferred to the reaction flask. The combined reagents were put into a 140 °C oil bath and allowed to stir for three hours. Upon cooling to room temperature, the mixture was poured into 50 mL of a 1 : 1 MeOH/lM HC1 aqueous solution with vigorous stirring. The resulting precipitate was filtered, washed with water (5 ^χ 10 mL), then MeOH (3* 10 mL), and dried for 15 minutes by an air stream through the filter cake. The resulting solid was suspended in 50 mL of chlorobenzene and heated to 60 °C. Once the solids dissolved completely, diethyl dithiocarbamic acid diethylammonium salt (Pd-scavenger, 2.0 mg, ~ 4 eq of Pd content) and 18-crown-6 (1.3 g, 5 mmol) were added. The solution was stirred for four hours. The reaction mixture was cooled to room temperature and precipitated into MeOH. The precipitate was filtered by gravity filtration, washed with MeOH (5x 10 mL), and hexanes (3 x 5 mL) and dried under vacuum overnight. A total of 388 mg of dark maroon powder was obtained (88% yield). *H NMR (300 MHz, CDCI ₃ , δ): 4.15 (bs, 4H), 3.60 (bs, 4H), 3.33 (bs, 4H), 1.52 (bs, 4H), 1.20-1.45 (m, 18H), 0.82-0.94 (m, 12H). GPC (THF, PS): M _n = 9,980 g/mol, D _M = 1.42. ECP-Magenta (B), as schematically illustrated in Figure lb): This material was prepared following the procedure described for ECP-Magenta with the following modifications: all solid materials were loaded into the over dried Schlenk. In a separate vial, 6-bromo-3,3-bis((2-ethylhexyloxy)methyl)-3,4-dihydro-2H-thie no[3,4-b][l,4]dioxepine (3, 299 mg, 0.5 mmol) was weighed. The sequences of evacuation/purging, plus reactant mixing was carried out as the general procedure for ECP-Magenta. Once all reactants were mixed altogether, the tube was inserted into the oil bath preheated at 140 °C. After 3 hours, the resulting yellow mixture was worked up and the resulting polymer was isolated as previously described for ECP-Magenta. A total of 210 mg of dark purple-colored powder was obtained (95% yield). All characterization data matched that for ECP-Magenta from 1 and 2. GPC (THF, PS): M„ - 9,440 g/mol, £> _M = 1.42.

ECP- Yellow, as schematically illustrated in Figure 9: This material was prepared following the procedure described for ECP-Magenta using NMP with the following modifications: all solid materials were loaded into the oven dried Schlenk tube including 1,4- dibromobenzene (4, 118 mg, 0.5 mmol). In a separate vial, 3,3-bis((2- ethylhexyloxy)methyl)-3,4-dihydro-2Hthieno[ 3,4-b][l,4]dioxepine (1, 220 mg, 0.5 mmol) was weighed. The sequences of evacuation/purging, plus reactant mixing is as the general procedure for ECP-Magenta. Once all reactants were mixed, the tube was inserted into the oil bath preheated at 140 °C. After 3 hours, the resulting yellow mixture was worked up and the resulting polymer was isolated, as described, above, for ECP-Magenta. A total of 210 mg of dark orange-colored powder was obtained (76% yield). 1H NMR (300 MHz, CDC1 ₃ , δ): 7.75 (bs, 4H), 4.19 (bs, 4H), 3.60 (bs, 4H), 1.52 (bs, 4H), 1.22-1.44 (m, 18H), 0.82-0.98 (m, 12H). GPC (THF, PS): M _n = 27,500 g/mol, £» _M = 1.19.

ECP-Blue, as schematically illustrated in Figure 10: This material was prepared following exactly the procedure described for ECP-Magenta using NMP with the following modifications: all solid materials were loaded into the oven dried Schlenk tube including 4,7- dibromo-2,l ,3-benzothiadiazole (5, 147 mg, 0.5 mmol). In a separate vial, 3,3-bis((2- ethylhexyloxy)methyl)-3,4-dihydro-2H-thieno[3,4-b][l,4]dioxe pine (1, 220 mg, 0.5 mmol) was weighed. The sequences of evacuation/purging, plus reactant mixing is as the general procedure. Once all reactants were mixed, the tube was inserted into the oil bath preheated at 140 °C. After 3 hours, the resulting dark blue mixture was worked up and the resulting polymer was isolated as described, above, for ECP-Magenta. A total of 375 mg of dark blue- colored (almost black) powder was obtained (81% yield). ^J H NMR (300 MHz, CDC1 ₃ , δ): 8.42 (bs, 2H), 4.33 (bs, 4H), 3.65 (bs, 4H), 3.35 (bs, 4H), 1.20- 1.60 (m, 22H), 0.85-0.98 (m, 12H). GPC (THF, PS): M _n = 9,440 g/mol, £> _M = 1.54.

ECP-Cyan, as schematically illustrated in Figure 1 1 : This material was prepared following exactly the procedure described for ECP-Magenta using NMP with the following modifications: all solid materials were loaded into the oven dried Schlenk tube including 4,7- dibromo-2,l ,3-benzothiadiazole (5, 147 mg, 0.5 mmol). In a separate vial, 3,3,3',3'- tetrakis(2-ethylhexyloxymethyl)- 3,3',4 ₎ 4'-tetrahydro-2H _;( 2'H-6,6 ^, -bithieno[3,4- b][l ,4]dioxepine (6, 440 mg, 0.5 mmol) was weighed. The sequence of evacuation/purging, plus reactant mixing is as the general procedure for ECP-Magenta. Once all reactants were mixed, the tube was inserted into the oil bath preheated to 140 °C. After 3 hours, the resulting dark cyan mixture was worked up and the resulting polymer was isolated as described, above, for ECP-Magenta. A total of 410 mg of dark blue-colored powder was obtained (89 % yield). ^l H NMR (300 MHz, CDC1 ₃ , δ): 8.38 (bs, 2H), 4.26 (bs, 8H), 3.62 (bs, 8H), 3.36 (bs, 8H), 1.16-1.60 (m, 44H), 0.90-0.99 (m, 24H). The sample was sparingly soluble in THF, which precluded its characterization via GPC.

ECP-Black, as schematically illustrated in Figure 12: This material was prepared following the procedure described for ECP-Magenta using NMP with the following modifications: all solid materials were loaded into the oven dried Schlenk tube including 4,7- dibromo-2,l,3-benzothiadiazole (5, 74 mg, 0.25 mmol). In a separate vial, 6,8-dibromo-3,3- bis((2-ethylhexyloxy)methyl)-3,4-dihydro-2H-thieno[3,4-b][l, 4]dioxepine (2, 150 mg, 0.25 mmol), and 3 ,3 -bis((2-ethylhexyloxy)methyl)-3 ,4-dihydro-2H-thieno [3 ,4-b] [1,4] dioxepine (1, 220 mg, 0.50 mmol) were combined. The sequence of evacuation/purging, plus reactant mixing is as the general procedure for ECP-Magenta. Once all reactants were mixed, the tube was inserted into the oil bath preheated at 140 °C. After 3 hours, the resulting black mixture was worked up and the resulting polymer was isolated as described, above, for ECP-Magenta. A total of 395 mg of black-colored powder was obtained (78 % yield). 1H NMR (300 MHz, CDC1 ₃ , δ): 8.38 (bs, 2H), 4.20 (bs, 8H), 3.62 (bs, 8H), 3.36 (bs, 8H), 1.16-1.60 (m, 44H), 0.90-0.99 (m, 24H). GPC (THF, PS): M _n = 11 ,000 D _M = 2.03.

It should be understood that the examples and embodiments described herein are for illustrative purposes only and that various modifications or changes in light thereof will be suggested to persons skilled in the art and are to be included within the spirit and purview of this application.