DESCRIPTION

FIELD OF THE INVENTION

This invention relates to electrolytes comprising linear organic copolymers containing alkyl pyridinium and/ or alkyl imidazolium units and methacrylic units, as gelling agents. The electrolytes so obtained take the form of gels suitable for use in photoelectrochemical devices, such as photoelectrochemical cells, in particular Dye Sensitized Solar Cells.

PRIOR ART Liquid electrolytes have been used in photoelectrochemical devices, as for example reported in Nature, 353, 737-740 (1991) and in US 4927721, but there have been problems with the reliability of their functioning because of the evaporation which takes place in long-term use, with a consequent drop in conversion efficiency. Various approaches have been developed to prevent or reduce the deterioration in the photoelectric properties of the device. These include the use of solid electrolytes, comprising for example cross-linked polyethylene oxide. Nevertheless solid polymer electrolytes have many problems such as short service life and insufficient current density, and the photoelectrochemical cells using them show low conversion levels. In order to overcome these problems the use of polymer gel electrolytes has been considered because of some advantageous properties, such as ease of preparation of the polymers, low cost of the starting products, thermal stability, low vapour pressure, good filling and contact properties between the nano structure electrolyte and the counterelectrode, and good ion conductibility. Polymer gel electrolytes are obtained by trapping the liquid electrolyte (based on plasticizing organic solvents with high boiling point and organic and inorganic salts) within the polymer matrix. In a polymer gel electrolyte, inorganic salts with a low reticular energy interact with the polymer matrix through coordination between the metal ion and polar groups (ethers, esters, amides). For example polymer gel electrolytes containing units with carbonate groups, nitrogen-containing heterocyclic groups or quaternary ammonium salts are described in EP-A-91 1841. EP-A-1507307 and Nat. Mater. 2, 402-407, 2003 describe the preparation of a quasi-solid electrolyte (gel electrolyte) by adding poly(vinylidenefluide-co-hexafluoropropylene) to a liquid electrolyte based on 3-methoxypropionitrile; the system provides high stability if combined with a special amphiphilic dye based on ruthenium. Electrochimica Acta 52, 5334—5338, 2007 describes the use of a polymer gel based on polyvinylpyrrolidone/ polyethylene glycol, the polyvinylpyrrolidone being a polymer containing a nitrogen-heterocycle capable of coordinating with iodine and the polyethylene glycol being a photochemically- stable straight chain polymer capable of holding the organic solvents of the electrolyte solution within the polymer chains; the gel formation, brought about using the polymer blending technique, requires a precise combination of specific polymers and electrolytes, thus restricting the versatility of the process.

A greater freedom in choice of the starting polymer occurs in the case of gels produced by cross-linking, wherein the cross-linking brings about a stiffening of the polymer matrix, with consequent gelling of the solution. For example EP-A-986080 describes gel electrolytes obtainable by reacting a nitrogen-containing polymer with a bi- or multi-dentate electrophilic reagent; the latter binds to an equivalent number of nitrogen atoms in the polymer, bringing about the cross-linking. However the cross- linking/ gelling directly induced by heating within the photochemical device makes the control of the process problematical. In J. Photochem. and Photobiol. A., 148, 33-39, 2002, electrolyte solutions based on polyvinylpyridine are gelled via a reaction with suitable polyalkylating halides (cross-linkers) forming bridges between the nitrogen atoms in the polymer; here again the cross-linking brought about by heating in situ within the device makes it difficult to control the uniformity of the medium during the cross-linking/ gelling process. Uniformity of the gel is however fundamental to cell performance since changes in gel viscosity result in a modified mobility of the electrical charges; this alters the level of response of the device, reducing reproducibility. Electrochimica Acta, 52, 4858- 4863, 2007 reports the preparation of a gel electrolyte polymer via an in situ cross-linking/gelling process involving the copolymer poly(vinylpyridine-co-acrylonitrile) and a bi-dentate cross-linking agent (hexyl diiodide). Nevertheless the problem of controlling the uniformity of the medium, with consequent discontinuity in the conversion values of the photoelectrochemical cells, still remains a problem even with these electrolyte gels.

In the light of the prior art mentioned above the need remains largely unsatisfied for gel electrolytes obtainable from a wide range of polymers, using an easily-controllable process, especially during the gelling stage; these gels should also be highly homogeneous, and capable of providing a reproducible high-intensity response, both when new and after prolonged use.

SUMMARY It has now been unexpectedly found that it is possible to produce electrolyte gels with the abovementioned favourable properties without resorting to the cross-linking reactions used in the state of the art. This has been made possible through use of a wide range of linear copolymers as the gel precursors; when subjected to quarternisation, these provide highly-efficient gel electrolytes which are stable over time. The copolymers in question are characterised in that they contain alkyl methacrylate monomer units combined with alkyl pyridine and/ or alkyl imidazole monomer units, where the said units are present in appropriate ratios; quaternisation, brought about by a non-cross-linking alkylating agent, allows to obtain gels with excellent efficiency values, which are thus highly useful for application in photoelectrochemical devices.

Object of this invention is therefore a method for producing polymer gel electrolytes based on linear copolymers containing alkyl pyridinium and/or alkyl imidazolium units and alkyl methacrylates. A further object of this invention is a method for producing photoelectrochemical devices with excellent efficiency and stability characteristics over time, characterised by using of the aforesaid gel electrolytes. The invention also extends to the gel electrolytes as such, comprising one or more quaternised copolymers as indicated above, their use in the preparation of photoelectrochemical devices, and devices containing them, for example photovoltaic cells.

DETAILED DESCRIPTION OF THE INVENTION The quaternised copolymer containing alkyl pyridinium units and /or alkyl imidazolium units and methaciylic ester units according to this invention is described by the following formula (I)

(I) where Ri represents a straight or branched Ci-Cs alkyl, optionally substituted by one or more fluorine atoms. Preferably Ri is a straight or branched C1-C4 alkyl, a -CH2CF3 group, a -CH2CF2CF3 group or a - CH2CH2CF3 group. Ri being methyl, butyl or trifluoroethyl is particularly preferred;

R2 is straight or branched d-Cs alkyl optionally substituted by one or more fluorine atoms. Preferably R2 is straight or branched C ₁ -C4 alkyl optionally substituted by one or more fluorine atoms; more preferably R2 is methyl, n-propyl, or trifluoropropyl;

Y- is an inorganic or organic anion, preferably Cl ^~ , Br, I", CF3COO-, CF3SO3- or (CF ₃ S0 ₂ ) ₂ N-, more preferably Y- is I-, CF3COO- or (CF ₃ SO ₂ )2N-; x, y, z each represent the molar ratios of the corresponding monomer units present in the copolymer, where (x+y) lies between > 0% and 90% with respect to the sum of (x+y+z); the lower limit of the range (> 0%) rules out the case where x and y are simultaneously = 0%; the upper limit of the range (< 90%) means that the copolymer in question always has methaciylic ester units, which can be copolymerised with alkyl pyridinium units, alkyl imidazolium units or both. It is important to note that the indices x,y,z do not represent the absolute number of units present in the copolymer, but their corresponding molar ratios. For example formula (I) in which x= l, y=2, z=9, identifies a copolymer in which overall 2 alkyl imidazolium units and 1 alkyl pyridinium unit are present for each 9 units of alkyl methacrylate; in this case the sum (x+y) = 3, represents 25% of (x+y+z) = 12; the value (x+y) = 25%, being comprised between > 0% and < 90%, falls within the range defined above.

It will also be noted that formula (I) is not limited to copolymers having constant repetitive monomer units, e.g. (A-B-C)-(A-B-C)-(A-B-C)..., nor is it restricted to a specific sequence of monomers, but includes any sequences of monomers, e.g. A-A-C-A-B-C-C-A-B..., provided that x, y, z satisfy the abovementioned molar proportions.

The overall molecular weight of copolymer (I) is not a determining factor for the purposes of the invention. However, this (which may be calculated indifferently as either M _n or M _w ) preferably lies between 15000 and 40000 Da.

The total number of monomer units (= methacrylic ester + alkyl pyridinium + alkyl imidazolium) present in copolymer (I) generally lies between 70 and 400, preferably between 100 and 350, and more preferably between 150 and 300.

The number of methacrylic ester units present in copolymer (I) generally lies between 50 and 350, preferably between 80 and 300, more preferably between 100 and 250. The number of alkyl pyridinium units present in copolymer (I) is generally between 0 and 80, preferably between 0 and 60, and more preferably between 0 and 50.

The number of alkyl imidazolium units present in the copolymer (I) is generally between 0 and 80, preferably between 0 and 70, more preferably between 0 and 60.

Copolymers of formula (I) have shown ideal gel electrolyte properties and, according to the invention, are used in the preparation of photoelectrochemical devices having excellent efficiency characteristics and stability over time. The invention relates to the said copolymers of formula (I) as such, the process of their preparation, their use as gel electrolytes, and in the production of the aforesaid devices. The process for preparing the copolymers of formula (I) comprises a quaternising reaction of copolymers of formula (II):

(II) where Ri, x, y and z have the meanings already described for formula (I).

The quaternising reaction takes place by reacting a solution of copolymer of formula (II) with one or more monoalkylating halides in a suitable electrolyte solution. In particular, for the quaternising reaction, the copolymers of formula (II) : (a): are dissolved in a suitable solvent or mixture of solvents;

(b): are added with the aforesaid monoalkylating halides and standard components of electrolyte solutions.

Steps (a) and (b) are not necessarily sequential in the process, but merely indicate the components which are necessary for preparing the gels; these may therefore be added separately and in any order: for example the monoalkylating halides can first be dissolved in the solvent, and then some of the standard components can be added, followed by the copolymers of formula (II), and then the remaining standard components, and so on. The solvents used in step (a) are in particular solvents having excellent ionic conductivity, . low viscosity and a high dielectric constant. Among these, which are provided by way of example and without any limitation, mention may be made of: - carbonic acid esters such as ethylene carbonate, propylene carbonate, vinylene carbonate, butylene carbonate, dimethyl carbonate, diethyl carbonate, methylethyl carbonate, dipropyl carbonate;

- lactones such as γ-butyrolactone, γ-valerolactone, γ-capryl lactone, crotolactone, γ-caprolactone and δ-valerolactone; - cyclic ethers such as tetrahydrofuran, methyl-tetrahydrofuran, 1,3-dioxolane and 1,4-dioxolane;

- nitriles such as acetonitrile, propionitrile, 3-methoxypropionitrile, glutaronitrile,

- heterocyclic compounds such as N-methyl pyrrolidone, 4-methyl- l,3- dioxan, 3-methyl-2-oxazolidinone.

The said solvents may be used either individually or as mixtures. Preferred solvents are the nitriles and the heterocyclic compounds. Particularly preferred are 3-methoxypropionitrile and 3-methyl-2-oxazolidinone, alone or as mixtures. A particularly preferred mixture is that formed by 3-methoxypropionitrile and 3-methyl-2-oxazolidinone in a 1 / 1 weight ratio.

The monoalkylating halides are compounds of formula R2-Hal where R2 has the meaning indicated in formula (I); Hal indicates a leaving group selected from chlorine, bromine and iodine atoms, preferably iodine. Preferred monoalkylating halides are CH ₃ I, C3H7I, CF3CH2CH2I. The term "monoalkylating" means that "Hal" is bound to a single carbon atom in R2; this carbon atom is therefore the only reactive site which is capable of alkylating the copolymer (II): the use of the compound R2-Hal thus allows quaternising the copolymer (II) without cross-linking it. The monoalkylating halides are added in equivalent quantity with respect to the quaternisable nitrogen-containing groups (cf. N-R2 in formula(I)), achieving complete quaternisation of the monomers in accordance with formula (I).

The quaternising reaction preferably takes place at a temperature of between 40 and 100°C over a period of between 15 and 25 hours, more preferably between 60 and 80°C over a period of between 18 and 22 hours.

The standard components of electrolyte solutions mentioned in paragraph (b) may be selected from those commonly used in the field: among these, mention may be made of alkaline or alkaline earth metal iodides such as for example Lil, Nal, KI, Csl, Cab, iodides of quaternary ammonium compounds and N-heterocyclic cations such as, for example, 1,2- dimethyl-3-propyl-imidazolium iodide. The abovementioned standard iodides may be added individually or as a mixture; preferably they are used at a concentration of between 0.05 M and 1 M, more preferably between 0.1 M and 0.7 M. In an advantageous variant the standard components further include elemental iodine, which forms a redox pair with the iodides in solution, improving electron transport; when used, the iodine is present at a concentration of preferably between 0.01 M and 0.3 M, more preferably between 0.05 M and 0.2 M. The iodide and iodine concentrations described above are meant to refer to the solvent used in step (a); in the case of mixtures, they are meant to relate to the overall number of moles of the components in the mixture.

The copolymers of formula (II), precursors of the gels according to the invention, can be prepared from the corresponding alkenyl monomers by free-radical polymerisation in bulk or in the presence of suitable solvents such as, for example, those reported in European Polymer Journal, 37 (2001) 2443-2451 , J. Polym. Sci. 43 (1960), 1899 and in J. Appl. Polym. Symp. 8 (1969) 227.

Azoisobutyronitrile, peroxides such as for example lauroyl peroxide, benzoyl peroxide, methylethyl ketone peroxide, hydroperoxides such as for example t-butyl hydroperoxide or pinane hydroperoxide are used as free radical polymerisation catalysts (initiators); azoisobutyronitrile is preferred. The solvents used for the polymerisation reaction are chlorinated solvents such as for example chloroform and carbon tetrachloride; aromatic solvents such as for example benzene, toluene, xylene and their isomers, mesitylene and its isomers; toluene is particularly preferred. The polymerisation reaction is performed at a temperature of between 50° and 100°C, preferably between 60° and 70°C.

The quantity of initiator is generally between 0.1% and 3% molar, preferably between 0.4% and 1% molar, more preferably between 0.4% and 0.6% molar, said percentages relating to the total number of moles of alkenyl monomers present. The copolymers of formula (II) so obtained are preferably separated from the reaction solution using an alcohol solvent such as methanol, ethanol, propanol or butanol, which may be straight or branched. Methanol is particularly preferred.

This invention provides a gel based on non-cross-linked linear copolymers with useful properties from the point of view of photoelectrochemical applications. In particular, quaternisation of the present copolymers provides gels with a viscosity adapted for photoelectrochemical applications, without this resulting in low efficiency products, as is often the case when electrolyte solutions are gelled. In particular, as documented experimentally, the gels have useful high photovoltaic conversion efficiency (η), open-circuit voltage (Voc), short-circuit current (Jsc) and fill factor (ff) values. Without wishing to be bound by theory, it is thought that charge transfer is kept high because of the linear structure of the copolymer (I) and the absence of cross-linking; it is also thought that these molecular properties contribute to the uniformity of the gel and the stability of response over the long term documented in the experimental part.

Taking advantage of the abovementioned excellent characteristics of the gel, the Applicant has produced high efficiency photoelectrochemical devices. This invention therefore includes a said device comprising a gel based on the copolymer of formula (I) having the abovementioned properties as a charge transfer medium. Typically the device is a photovoltaic cell, preferably a Dye Sensitized Solar Cell (DSSC). These devices can be constructed by using known procedures and, associated with the gel according to the invention, contain known constituent members: as a non-limiting example, the DSSC may comprise an electrically-conducting layer, a semiconducting layer adhesively bonded to the electrically-conducting layer for the transport of electrons, a suitable organic or organ ometallic dye capable of absorbing light radiation, a layer comprising the gel electrolyte for the transport of holes and a counterelectrode coated by a suitable catalyst metal. The gel of formula (I), containing suitable electrolytes, can be inserted into the cell using per se known techniques: e.g. it is possible to bring about the insertion into a preformed cell by passing the material through a suitable hole; alternatively the cell may be only partly formed, filled with the electrolyte material, and then finished off and sealed.

The invention will now be described in a non-restrictive way using the following Examples. INSTRUMENT MEASUREMENT TECHNIQUES

NMR

The ^l H NMR spectra were obtained using a Bruker Avance 400 NMR spectrometer at ambient temperature (the chemical shifts, 5H, being reported with respect to tetramethylsilane) . Viscosity meter

The viscosity of the gel electrolytes whose preparation is described in Examples 2, 4, 6, 8, 10, 12, 13 and 15 was determined using a Brookfield DV-II+Pro viscosity meter provided with a Small Sample Adapter (16 ml), SC4-27 Spindle of cylindrical geometry. Measurements were made at 25°C; in the case of the samples whose preparation is described in Examples 8, 12 and 15 viscosity was determined at 60°C, 40°C and 60°C respectively. Viscosity values were determined at a shear rate of 68 sec ^-1 for the samples in Examples 8, 12, 13 and at a shear rate of 10 sec ^-1 for the samples in Examples 2, 4, 6, 10, 15. Gel Permeation Chromatography (GPC)

The values of M _n and M _w for the copolymers whose synthesis is reported in Examples 1 , 3, 5, 7, 9, 1 1 and 14 were calculated using a gel permeation chromatography apparatus (also known as SEC, molecular exclusion chromatography). This apparatus comprises a GPC MXL column (internal diameter 5 mm, length 300 mm), a polystyrene-based EasyCal Vial calibration solution, and a refractive index detector. Measurements were performed under the following operating conditions: mobile phase tetrahydrofuran (THF), column temperature 20°C, flow 1 ml/min.

Element analyser

Carbon, hydrogen and nitrogen contents were determined using the EA3000 Series (Eurovector) automatic element analyser. EIS (Electrochemical Impedance Spectroscopy)

The impedance measurements on the electrolyte gels were made using an AUTOLAB potentiostat-galvanostat fitted with a small sample conductivity sensor with platinum electrodes in a frequency range between 1 MHz and 0.1 Hz, V BIAS 0 V, DVac 0.01 V) in the presence of illumination equivalent to 100 mW/cm ² (detected temperature 30°C). Impedance measurements allowed to determine the following parameters which are characteristic of individual electrolyte gels: Rs (resistance in series), Ret (resistance due to transfer of charge to the platinum electrode), a (ion conductivity). Solar Simulator

The determination of photovoltaic parameters required the use of a 1.5 AM Newport (Oriel® Product Line) solar simulator. The power of the lamp was calibrated so as to have an incident radiation power per unit surface area of 100 mWcm-2. The I-V (current-potential) graphs were obtained by scanning the applied potential and measuring the generated photo current using a "Keithley 2400 SourceMeter".

The photovoltaic parameters (efficiency {η), fill factor (FF), open circuit voltage (Vbc), short-circuit current {Jsc)) recorded over an active area of 0.27 cm ² for the devices containing the gel electrolytes obtained as described in Examples 8 and 13, as described in Examples 16 and 17 and for a device containing a liquid electrolyte as described in Example 18 are reported.

Example 1

Synthesis of 4-vinyl pyridine-methyl methacrylate copolymer (Copolymer according to formula (II) with x=l, y=0 and z=5)

6.70 ml (6.25 g, 62.43 mmol) of methyl methacrylate and 0.84 ml (0.82 g, 7.8 mmol) of 4-vinyl pyridine were placed in a 50 ml flask. Then 64 mg (0.39 mmol) of AIBN (azobisisobutyronitrile) dissolved in 17 ml of (previously de-aerated) toluene were added to the mixture of monomers de-aerated using a flow of dry nitrogen. The solution was heated under stirring to 65°C-70°C for 48 hours. After returning the reaction mixture to ambient temperature, the copolymer was precipitated out by pouring the toluene solution slowly into 150-200 ml of methanol which was kept stirred. The suspension containing the precipitate was filtered and the precipitate was further washed with methanol and dried under vacuum at 40°C/2 1 mbar, yielding 5.6 g of copolymer characterised as follows.

Element analysis:

Experimental C = 63.29%

H = 7.54% N = 2.28%

Calculated for x= 1 , y=0 and z=5

C = 63.47%

H = 7.77%

N = 2.31% H NMR δ _Η (400 MHz, CDC1 ₃ ) 8.55 (Ar, V), 6.97 (Ar, V) , 3.59 ((CH ₃ 0)- _M MM) , 2.98 ((CH ₃ 0)-MMV) , 1.94 (-(CH)- _V ) 1.81 (-(CH ₂ )-M), 1.40 (-(CH ₂ )-v), 1.25 (- (CH ₂ )- _M ), 1.00 (|CH ₃ )-M), 0.82 ((CH ₃ )-M) . GPC: M _n = 20.800 Da; M _w = 26.300 Da Example 2

Quaternisation of the copolymer in Example 1 and gelification (R ₂ = CH ₃ Y = I ) 1.8 g of the copolymer obtained according to Example 1 were dissolved in 5 g of the solvent mixture based on 3-methoxypropionitrile/ V-methyl oxazolidinone = 1 / 1 (w/w). 0.77 g (2.89 mmol) of l,2-dimethyl-3-propyl imidazolium iodide, 122 mg (0.48 mmol) of I2 and 0.41 g ( 2.9 mmol) of CH3I were added to the resulting mixture aerated with flow of dry nitrogen. The resulting mixture was kept stirred at 70°C for 20 hours in a nitrogen atmosphere; quaternisation/ gelification was confirmed by FT-IR:

N-CH3 (quaternised pyridine nitrogen) 1642 cm-'.

Viscosity: 630 cP at 25°C (shear rate, sec ¹ , 10)

EIS: Rs = 360 Ω; Ret = 1840 Ω; σ = 4.3 mS/cm. Example 3

Synthesis of 4-vinyl pyridine-2,2,2-trifluoroethyl methacrylate copolymer

(Copolymer according to formula (II) with x=l, y=0 and z=7)

Using the same procedure as described in Example 1, 2.93 ml (3.46 g, 20.58 mmol) of 2,2,2-trifluoroethyl methacrylate and 0.27 ml (0.27 g, 2.57 mmol) of 4-vinyl pyridine in 7.2 ml of toluene were caused to react in the presence of 21 mg (0. 13 mmol) of azoisobutyronitrile.

The solution was heated under stirring to 65°C-70°C for 48 hours in a nitrogen atmosphere. After returning the reaction mixture to ambient temperature, the organic solution was evaporated off under vacuum at 40°C/21 mbar, yielding 3.54 g of copolymer.

Element analysis:

Experimental C = 45.73% H = 4.31%

N = 1.08% Calculated for x= 1 , y=0 and z=7 C = 45.90% H = 4.37%

N = 1.09% NMR δ _Η (400 MHz, CDCls) 8.48 (Ar, V), 6.98 (Ar, V), 4.33 ((CH ₂ 0)-TTT), 2.03 (-(CH)-v), 1 -91 (-(CH ₂ )- _T ), 1.53 (-(CH ₂ )-v), 1.25 (-(CH ₂ )-x), 1.03 ((CH ₃ )-T), 0.89 ((CH ₃ )-T). GPC: Mn = 29.100 Da; M _w = 33.400 Da

Example 4

Quaternisation of the copolymer in Example 3 and gelification. (R ₂ = CH ₃ Y = I)

Using the same procedure as described in Example 2, 0.4 g of the copolymer obtained according to Example 3 was caused to react with 0.32 g (1.2 mmol) of 1 ,2-dimethyl-3-propyl imidazolium iodide, 50 mg (0.2 mmol) of I ₂ and 44 mg (0.31 mmol) of CH ₃ I in 1.25 g of a mixture comprising 3-methoxypropionitrile/jV-methyloxazolidinone = 1 / 1 (w/w). The resulting mixture was kept stirred at 70°C for 20 hours in a nitrogen atmosphere; quaternisation /gelification was confirmed by FT-IR: N-CH3 (quaternised pyridine nitrogen) 1642 cm- ¹ .

Viscosity: 60 cP at 25°C (shear rate, sec ¹ , 10)

EIS: i?s = 665 Ω; Ret = 640 Ω; σ = 2.3 mS/cm.

Example 5 Synthesis of 4-vinyl pyridine-n-butyl methacrylate copolymer (Copolymer according to formula (II) with x=l, y=0 and z=12) Using the same procedure as described in Example 1, 7.46 ml (6.66 g, 46.9 mmol) of n-butyl methacrylate and 0.54 ml (0.53 g, 5.05 mmol) of 4-vinyl pyridine were caused to react in 15 ml of toluene in the presence of 34 mg (0.21 mmol) of AIBN (azobisisobutyronitrile). The solution was heated under stirring at 65°C-70°C for 48 hours. After returning the reaction mixture to ambient temperature, the copolymer was precipitated out by gently pouring the solution into 150-200 ml of methanol, which was kept stirred. The suspension containing the precipitate was filtered, the precipitate was further washed with methanol and dried under vacuum at 40°C/21 mbar. 5.75 g of copolymer were obtained.

Element analysis:

Experimental C = 68. 16%

H = 9.55%

N = 0.75% Calculated for x= 1 , y=0 and z= 12

C = 68.32%

H = 9.67%

N = 0.77%

*H NMR δ _Η (400 MHz, CDC1 ₃ ) 8.42 (Ar, V), 6.96 (Ar, V), 3.93 ((CH ₂ 0)-BBB), 1.99 (-(CH)-v), 1.89 (-(CHa)-n), 1 -79 (-(CH ₂ )-B), 1.64 (-(CH ₂ )-v), 1.59 ( ² CH ₂ -) , 1.38 ( ³ CH ₂ -) , 1.01 (Q-(CH ₃ )B), 0.94 ( ⁴ CH ₃ ) , 0.86 (Q-(CH ₃ )B) .

GPC: M _n = 27.300 Da; M _w = 32.800 Da

Example 6 Quaternisation of the copolymer in Example 5 and gelification. (R ₂ = CH ₃ Y = / Using the same procedure as described in Example 2, 0.4 g of the copolymer in Example 5 was caused to react with 0.32 g (1.2 mmol) of 1,2- dimethyl-3-propyl imidazolium iodide, 50 mg (0.2 mmol) of I2 and 31 mg (0.22 mmol) of CH3I in 1.25 g of a mixture comprising 3- methoxypropionitrile/iV-methyl oxazolidinone = 1/ 1 (w/w). The resulting mixture was then held at 70°C for 20 hours with stirring in a nitrogen atmosphere; quaternisation/gelification was confirmed by FT-IR: N-CH ₃ (quaternised pyridine in nitrogen) 1642 cm" ¹ .

Viscosity: 6362 cP at 25°C (shear rate, sec ¹ , 10) EIS: #s = 142 Ω; Rct = 103 Ω; σ = 1 1.7 mS/cm.

Example 7

Synthesis of vinyl imid zole-methyl methacrylate copolymer

(Copolymer according to formula (Π) with y=l, x=0 and z=l l)

Using the same procedure as described in Example 1, 6.70 ml (6.32 g, 63.1 mmol) of methyl methacrylate and 0.71 ml (0.74 g, 7.84 mmol) of vinyl imidazole were caused to react in 15 ml of toluene, in the presence of 64 mg (0.39 mmol) of AIBN (azobisisobutyronitrile). The solution was heated under stirring to 65°C-70°C for 48 hours. After returning the reaction mixture to ambient temperature, the copolymer was precipitated out by slowly pouring the solution into 150-200 ml of methanol, which was kept stirring. The suspension containing the precipitate was filtered, the precipitate was further washed with methanol and dried under vacuum at 40°C/21 mbar, yielding 6.7 g of copolymer.

Element analysis: Experimental C = 60.19%

H = 7.82%

N = 2.33%

Calculated for y= 1 , x=0 and

C = 60.30% H = 7.87%

N = 2.34% H NMR δ _Η (400 MHz, CDCls) 7.25 (Ar, VI), 6.98 (Ar, VI), 6.73 (Ar, VI), 3.58 ((CH ₃ 0)-MMM), 2.02 (-(CH)-vi), 1.94 (-(CH ₂ )-M), 1.79 (-(CH ₂ )-M), 1.24 (- (CH ₂ )-vi), 1.00 (|CH ₃ )-M), 0.82 ((CH ₃ )-M) .

GPC: M _n = 17.300 Da; M _w = 21.400 Da

Example 8

Quatemisation of the copolymer in Example 7 and gelification. (R ₂ = CH ₃ Y = I ) Using the same procedure as described in Example 2, 0.4 g of the copolymer in Example 7 was caused to react with 0.32 g (1.2 mmol) of l,2-dimethyl-3-propyl imidazolium iodide, 50 mg (0.2 mmol) of I2 and 47 mg (0.33 mmol) of CH3I in 1.25 g of a mixture comprising 3-methoxypropionitrile/iV- methyl oxazolidinone = 1/ 1 (w/w). The resulting mixture was kept stirred at 70°C for 20 hours in a nitrogen atmosphere; quatemisation/gelification was confirmed by FT-IR: N-CH3 (quatemised imidazole nitrogen) 1550 cm ⁴ .

Viscosity: 565 cP at 60°C (shear rate, sec ¹ , 68)

EIS: i?s = 394 Ω; Ret = 576 Ω; σ = 4.5 mS/cm. Example 9

Synthesis of vinyl imidazole-n-butyl methacrylate copolymer

(Copolymer according to formula (Π) with y=l, x=0 and z=6)

Using the same procedure as described in Example 1, 6.22 ml (5.56 g, 39.1 mmol) of n-butyl methacrylate and 0.44 ml (0.46 g, 4.89 mmol) of vinyl imidazole in 15 ml of toluene were caused to react in the presence of 40 mg (0.24 mmol) of AIBN (azobisisobutyronitrile) . The solution was heated to 65°C-70°C with stirring for 48 hours. After returning the reaction mixture to ambient temperature, the copolymer was precipitated by slowly pouring the solution into 150-200 ml of methanol, which was kept stirred. The suspension containing the precipitate was filtered, the precipitate was further washed with methanol and dried under vacuum at 40°C/21 mbar, yielding 4.8 g of copolymer.

Element analysis: Experimental C = 67. 1 1%

H = 9.48%

N = 2.94%

Calculated for y= l, x=0 and z=6

C = 67.23% H = 9.51%

N = 2.96%

*H NMR δ _Η (400 MHz, CDCb) 7.24 (Ar, VI), 6.95 (Ar, VI), 6.72 (Ar, VI), 3.93 ((CH ₂ 0)-BBB), 1.98 (-(CH)-vi), 1.89 (-(CH ₂ )-B), 1.79 (-(CH ₂ )-B), 1.59 ( ² CH ₂ -), 1.38 ( ³ CH ₂ -), 1.25 (-(CH ₂ )-vi), 1.01 (a-(CH ₃ ) _B ), 0.94 ( ⁴ CH ₃ ), 0.85 ( ^Q -(CH ₃ )B) .

GPC: M _n = 30.600 Da; M _w = 35.400 Da

Example 10

Quatemisation of the copolymer in Example 9 and gelification. (R ₂ = CH ₃ Y = I ) Using the same procedure as described in Example 2, 0.4 g of the copolymer in Example 9 were caused to react with 0.32 g (1.2 mmol) of l ,2-dimethyl-3-propyl imidazolium iodide, 50 mg (0.2 mmol) of and 62 mg (0.44 mmol) of CH3I in 1.25 g of a mixture comprising 3-methoxypropionitrile/iV- methyl oxazolidinone = 1 / 1 (w/w). The resulting mixture was held at 70°C for 20 hours with stirring in a nitrogen atmosphere; quatemisation /gelification was confirmed by FT-IR: N-CH3 (quaternised imidazole nitrogen) 1550 cm ¹ .

Viscosity: 6108 cP at 25°C (shear rate, sec ^"1 , 10) EIS: i?s = 300 Ω; Ret = 260 Ω; σ = 5.8 mS/cm. Example 11

Synthesis of vinyl imidazole-2,2,2-trifluoroethyl methacrylate copolymer (Copolymer according to formula (II) with y=l, x=0 and z=10)

Using the same procedure as described in Example 1 , 2.93 ml (3.46 g, 20.6 mmol) of 2,2,2-trifluoroethyl methacrylate and 0.23 ml (0.24 g, 2.58 mmol) of vinyl imidazole in 6 ml of toluene were caused to react in the presence of 21 mg (0.13 mmol) of azoisobutyronitrile. The solution was heated to 65°C-70°C under stirring for 48 hours in a nitrogen atmosphere. After returning the reaction mixture to ambient temperature, the copolymer was isolated after evaporation under vacuum at 40°C/21 mbar, yielding 3.4 g of copolymer.

Element analysis: Experimental C = 43.79%

H = 4.25%

N = 1.57%

Calculated for y= l, x=0 and z= 10

C = 43.97% H = 4.28%

N = 1.58%

*H NMR 6 _H (400 MHz, CDC1 ₃ ) 7.24 (Ar, VI), 7.01 (Ar, VI), 6.76 (Ar, VI), 4.35 ((CH ₂ 0)-TTT), 2.04 (-(CH)-vi), 1.93 (-(CH ₂ )- _T ) , 1.69 (-(CH ₂ )- _T ) , 1.51 (- (CH ₂ )-vi), 1.08 ((CH ₃ )-x), 0.92 ((CH ₃ )-T) .

GPC: M _n = 34.800 Da; M _w =38.200 Da Example 12

Quatemisation of the copolymer in Example 11 and geliftcation. (R ₂ = CH ₃ Y = I) Using the same procedure described as in Example 2, 0.4 g of the copolymer in Example 11 was caused to react with 0.32 g (1.2 mmol) of l,2-dimethyl-3-propyl imidazolium iodide, 50 mg (0.2 mmol) of I2 and 34 mg (0.24 mmol) of CH3I in 1.25 g of a mixture comprising 3-methoxyisopropionitrile/ N-methyl oxazolidinone = 1/ 1 (w/w). The resulting mixture was held at 70°C under stirring for 20 hours in a nitrogen atmosphere; quatemisation/ gelification was confirmed by FT-IR: N-CH3 (quaternised imidazole nitrogen) 1550 cm ¹ .

Viscosity: 102,5 cP at 40°C (shear rate, sec ¹ , 68)

EIS: Rs = 255 Ω; Rct = 261 Ω; σ = 6.5 mS/cm. Example 13

Quatemisation of the copolymer in Example 11 and gelification.

Using the same procedure described as in Example 2, 0.4 g of the copolymer in Example 1 1 was caused to react with 0.32 g (1.2 mmol) of l,2-dimethyl-3-propyl imidazolium iodide, 50 mg (0.2 mmol) of I2 and 40 mg (0.24 mmol) of CH3CH2CH2I in 1.25 g of a mixture comprising 3-methoxypropionitrile/ N-methyl oxazolidinone = 1/ 1 (w/w). The resulting mixture was held at 70°C under stirring for 20 hours in a nitrogen atmosphere; quatemisation /gelification was confirmed by FT-IR: N-CH ₂ - (quaternised imidazole nitrogen) 1550 cm ⁴ .

Viscosity: 100 cP at 25°C (shear rate, sec" ¹ , 68)

EIS: i?s = 255 Ω; Rct = 295 Ω; σ = 6.4 mS/cm. Example 14

Synthesis of 4-vinyl pyridine-vinyl imidazole-methyl methacrylate terpolymer (terpolymer according to formula (II) with x=l, y=2 and z=6) Using the same procedure as described in Example 1 , 3.20 ml (3.0 g, 29.96 mmol) of methyl methacrylate, 1.98 ml (2.05 g, 21.79 mmol) of vinyl imidazole and 0.29 ml (0.29 g, 2.72 mmol) of 4-vinyl pyridine in 12 ml of toluene were caused to react in the presence of 49 mg (0.30 mmol) of AIBN (azobisisobutyronitrile). The solution was heated to 65°C-70°C under stirring for 48 hours. After returning the reaction mixture to ambient temperature, the copolymer was isolated by evaporation of the solvent under vacuum at 40°C/21 mbar yielding 5.29 g of copolymer.

Element analysis:

Experimental C = 63. 03% H = 7.46%

N = 7.82%

Calculated for x= 1 , y=2 and z=6

C = 63. 16%

H = 7.50% N = 7.84%

*H NMR δ _Η (400 MHz, CDCb) 8.44 (Ar, V) , 7.28 (Ar, VI) , 7.02 (Ar, VI), 6.97 (Ar, VI), 6.72 (Ar, V), 3.58 {(CH ₂ 0)-MMM), 3.25 ((CH ₂ 0)-MMV) , 2.95 ((CH ₂ 0)-MMVI) , 2.14 (-(CH)-v, -(CH)-vi), 1.84 (-(CH ₂ )-M), 1.73 (-(CH ₂ )-v), 1.40 (-(CH ₂ )-vi), 1.0 (-(CH ₃ )M) , 0.96 (-(CH ₃ ) _M ) , 0.81 (-(CH ₃ )M) . GPC: Mn = 23.400 Da; M _w =28.400 Da Example 15

Quatemisation of the copolymer in Example 14 and gelification. (R ₂ = CH ₃ Y = I )

Using the same procedure as described in Example 2, 0.4 g of the copolymer in Example 14 was caused to react with 0.32 g (1.2 mmol) of l,2-dimethyl-3-propyl imidazolium iodide, 50 mg (0.2 mmol) of h and 47 mg (0.33 mmol) of CH3I in 1.25 g of a mixture comprising 3- methoxyisopropionitrile/iV- methyl oxazolidinone = 1 / 1 (w/w). The resulting mixture was held at 70°C for 20 hours under stirring in a nitrogen atmosphere; quatemisation/ gelification was confirmed by FT-IR: N-CH3 (quaternised pyridine nitrogen) 1642 cm ¹ , N-CH3 (quaternised imidazole nitrogen) 1550 cm' ¹ .

Viscosity: 10450 cP at 60°C (shear rate, sec ¹ , 10)

EIS: i?s = 220 Ω; Ret = 100 Ω; o = 7.5 mS/cm. Example 16

A DSSC [dye sensitized solar cell) was assembled as described below: the working electrode (or photoelectrode) is a 2 cm x 2 cm glass electrode (Solaronix TCO22- 15, thickness 2.2 mm, 15 ohm/cm ² ) coated by a conductive substrate based on FTO (fluoride-doped tin oxide). The photoelectrode (anode) comprised a 12 pm thick film of Solaronix paste based on T1O2; the paste was deposited on the surface of the photoelectrode by screen printing (active area 0.9 cm x 0.3 cm) and the photoelectrode was gradually heated up to 520°C, sintered for 30 minutes at 520°C, and gradually returned to ambient temperature. After the sintering process, the photoelectrode was immersed in a 0.3 mM solution of 7V719 dye (cis-di(thiocyanate)-N,iV-bis(2,2'-bipyridyl-4-carboxy- 4'-tetrabutyl ammonium carboxylate)Ru(II) in acetonitrile/ tert- butyl alcohol (v:v = 1 : 1) and maintained at ambient temperature for 24 hours in order to complete adsorption of the dye onto the titanium dioxide surface. The counterelectrode was prepared as described as follows: a hole was made in the electrode and platinum was deposited on the surface of the latter using an electron beam evaporator (Pt thickness 200 nm).

The T1O2 photoelectrode and the Pt counterelectrode were then assembled to form a device which used Surlyn 1702(Du-Pont) as sealant and spacer (thickness 50 Mm).

The electrolyte gel obtained as described in Example 8, previously heated to 50-60°C, was placed in correspondence of the hole made in the cell counterelectrode, heating the cell to 50-60°C. The electrolyte was then inserted into the device by filling under vacuum: the cell was placed in the small chamber in which vacuum was successively applied in order to remove the air within it. Finally the hole was sealed with Surlyn.

Following photo -irradiation the following parameters which are characteristic of the current-voltage response of a solar cell were recorded at time 0 and after 2160 hours.

Example 17

Using the same procedure as described in Example 16, but using the electrolyte gel obtained as described in Example 13, the following parameters characteristic of the current-voltage response of a solar cell following photo-irradiation were recorded at time 0 and after 2160 hours. η (%) FF Voc (V) Jsc (mA/cm ) t = 0 4.3516 0.6559 0.7408 8.9558 t = 2160 h 4.1869 0.649 0.731 8.8252 Example 18 (reference)

The same procedure as described in Example 16 was performed, but using a liquid electrolyte characterised by the following composition: acetonitrile, Lil 0.1 M, 0.05 M, l,2-dimethyl-3-propyl imidazolium iodide 0.6 M, 4-t- butyl pyridine 0.5 M. No heating of either the device or the material itself was required when introducing the electrolyte into the cell. Following photo-irradiation the following parameters characteristic of the current - voltage response of the solar cell were recorded at time zero and after 336 hours. n (%) FF Voc (V) Jsc (mA/cm ² ) t = 0 5.6292 0.7389 0.669 11.3877 t = 336 h 2.707 0.6783 0.5788 6.8951