EP2621959A1 - Preparation of hydrophilic polymers of high mass by controlled radical polymerization - Google Patents

Abstract

The present invention relates to a process for preparing a polymer comprising at least one step (E) of gel polymerization, which gives access to polymer blocks of controlled high mass, in which the following are brought into contact: - identical or different, ethylenically unsaturated water-soluble monomers; - a source of free radicals suitable for the polymerization of said monomers, typically a redox system; and - an agent for controlling the radical polymerization, preferably comprising a thiocarbonylthio group -S(C=S)-, with a concentration of monomers in the reaction medium of step (E) that is high enough to induce gelation of the medium if the polymerization is performed in the absence of the control agent.

Description

 Preparation of hydrophilic polymers of high mass by controlled radical polymerization

The present invention relates to an original polymerization process giving access to water-soluble polymers of very high mass, typically of the order of 100 000 to 1 000000 g / mol, and with a control of the mass of these polymers. The invention also relates to the water-soluble polymers of high controlled mass thus obtained, which can be used in particular as rheological agents, surface modifiers and flocculating agents.

In conventional radical polymerization, various processes are known that make it possible to obtain water-soluble polymers of very high masses. In particular, it has been described the implementation of water-in-oil inverse emulsion polymerization processes, which make it possible to recover the hydrophilic polymer (for example polyacrylamide) by inversion of the emulsion. Another way to obtain high mass hydrophilic polymers is low temperature water solution polymerization (generally between 5 ° C and 25 ° C), typically with redox priming.

More specifically, it has been developed polymerization processes called "gel"("gelpolymerization" in English) which make it possible to obtain polymers of very high masses. In processes of this type, a low concentration of a suitable redox couple is contacted at low temperature and in aqueous medium with at least one hydrophilic monomer (typically acrylamide). In these processes, the monomer concentration in the water is chosen to be high enough that the reaction medium gels rapidly during polymerization. At the end of the reaction, the polymer is in the form of a physical gel in water, which is typically a non-covalent gel, formed essentially by reversible physical interactions, such as, for example, hydrogen bonds. It is recovered to be dried and crushed. Under these conditions, polyacrylamides of M _n much higher than 10 ⁶ g / mol (> 10 ⁷ g / mol) can be obtained.

In the context of the present description, and unless otherwise stated, a "physical gel" refers to a non-covalent gel of the aforementioned type, excluding chemically cross-linked structure, resin type for example. In particular, these physical gels, such as obtained according to the gel polymerization processes, are distinguished from the so-called "nanogel" or "microgel" structures described for example in WO 2010/046342 or WO 2008/155282 and which comprise red blood cells. a chemically crosslinked phase (improperly described as "gelled") within a dispersing medium. These processes give access to high molecular weight polymers, generally with high reaction rates. Nevertheless, they do not prove to be fully satisfactory. In particular, the rapid gelation of the medium generates a very high exotherm, which implies in particular the implementation of specific initiator systems. More fundamentally, gel polymerization processes are not able to provide control of the size and architecture of the polymer chains formed. In particular, the gel polymerization does not make it possible to access block polymers (for example diblocks).

On the other hand, polymerization processes are known that allow a fine control of the molar mass of the polymers, but which do not allow access to very high molar masses, especially when wishes to carry out a polymerization in aqueous phase.

 More precisely, various controlled radical polymerization processes are known at the present time, designated in particular under the terminology RAFT or MADIX, which make it possible to obtain polymers with controlled architecture and mass. These methods typically implement a reversible addition-fragmentation transfer method employing control agents (also known as reversible transfer agents), for example of the xanthate type (compounds bearing -SC = SO- functions). By way of examples of such methods, mention may in particular be made of those described in WO96 / 30421, WO 98/01478, WO 99/35178, WO 98/58974, WO 00/75207, WO 01/42312, WO 99 / 35177, WO 99/31144, FR2794464 or WO 02/26836.

 These so-called "controlled radical polymerization" processes lead, in a well-known manner, to the formation of polymer chains, all of which grow substantially at the same rate, which results in a substantially linear increase in the molecular weights with the conversion and a narrow mass distribution. with a number of chains which typically remains substantially fixed throughout the duration of the reaction, which makes it possible very easily to control the average molar mass of the polymer synthesized (this mass is even higher than the initial concentration of control agent is low, this concentration dictates the number of growing polymer chains).

Thus, for example, the controlled polymerization processes of acrylamide disclosed to date result in polymers of relatively limited size. Thus, among the examples of controlled radical polymerizations of acrylamide leading to the polymers of the highest sizes, mention may be made of: a RAFT polymerization of redox-primed acrylamide at room temperature, described in Macromolecular Rapid Communications, vol. 29, No. 7, pp. 562-566 (2008), which leads to polyacrylamides having a molar mass in number M _n of at most 40,000 g / mol; and

 a RAFT polymerization process in inverse miniemulsion which has been described in Macromolecular Rapid Communications, vol. 28, no. 9, p. 1010 (2007), which leads to molecular weights in numbers of up to 70,000 - 80,000 g / mol.

 These articles are exceptions, the sizes of the polymers obtained in the context of controlled radical polymerizations being generally well below these extreme values found in the literature.

An object of the present invention is to provide a method for obtaining both hydrophilic polymers of very high molar mass, well above 100,000 g / mol, preferably at least 500,000 g / mol, while providing a control of the mass of the polymers, with a substantially linear increase in molecular weights with the conversion and a mass distribution tightened around a mean value.

To this end, the present invention provides a novel type of hydrophilic polymer synthesis method, which combines the specificities of gel polymerization and controlled radical polymerization. Against all odds, it turns out that this new type of process can combine the benefits of each of the two methods without retaining the harmful aspects.

More specifically, according to a first aspect, the present invention provides a process for the preparation of a polymer comprising at least one gel polymerization step (E) in which, generally in an aqueous medium:

water-soluble ethylenically unsaturated monomers, which are identical or different;

a source of free radicals adapted to the polymerization of said monomers, typically a redox system; and

an agent for controlling the radical polymerization, preferably comprising a thiocarbonylthio -S (C = S) - group, with a monomer concentration within the reaction medium of step (E) which is sufficiently high to induce gelation of the medium if the polymerization is conducted in the absence of the control agent.

The work that has been done by the inventors in the context of the present invention has now made it possible to demonstrate that the implementation of step (E), which consists schematically to implement under the conditions of a synthesis In a gel a polymerization control agent of the type used for the synthesis of controlled polymers of low masses, leads to the formation of polymers of size both high and controlled, which is particularly unexpected in view of the sizes. maximum that can be obtained today by using controlled radical polymerization methods. Under the conditions of step (E), it is in fact possible to control the number-average molar mass of the polymers to very high values, which allows the synthesis of polymers and copolymers with controlled architecture with less a hydrophilic sequence of both high mass and controlled mass.

As in conventional controlled radical polymerization, the process of step (E) leads to the synthesis of polymers whose molar mass in number M _n is controllable by varying the initial concentration of control agent in the medium, the value of M _n being even higher than this initial concentration of control agent is low. By adjusting this concentration, step (E) can typically lead to the synthesis of a hydrophilic polymer block having a molecular weight Mn greater than 500,000 g / mol, for example between 500,000 and 1,000,000 g / mol. Thus, it appears that in step (E) effective control of the average mass of the polymers, of a type similar to that obtained with conventional controlled radical polymerization processes, is obtained, with the difference that this control effective to very high sizes (up to 1,000,000 g / mol or more) According to an advantageous embodiment of the process of the invention, in step (E), the initial concentration of control agent in the medium is chosen such that the synthesized hydrophilic polymer block average molecular weight has a number-average molecular weight Mn greater than 100,000 g / mol, preferably greater than or equal to 500,000 g / mol, for example between 500,000 and 1,000,000 g / mol.

Furthermore, it turns out that, even more unexpectedly, the implementation of a radical polymerization control agent in step (E) makes it possible, in general, to reduce, or even totally inhibit, the Exothermic phenomena generally observed in gel polymerization processes. Given these various advantages, the process of the invention is a particularly suitable process for the preparation of hydrophilic polymers, optionally in blocks, having a high molar mass.

In general, in the method of the invention, the conditions to be implemented in step (E) can typically be modeled on those typically used in gel polymerizations well known to those skilled in the art. In this regard, concerning the conditions to be used in gel polymerization, reference may in particular be made to US Pat. Nos. 3,002,960, 3,022, 279, US 3,480,761, US 3,929,791, US 4,455,41, or US Pat. Iranian Polymer Journal, 14 (7), pp 603-608 (2005).

 It is well known to those skilled in the art that gel polymerization leads to the formation of a physical gel which is related to entanglement of long linear or substantially linear chains in solution. Dissolution of said gel in solution can therefore lead to linear chains that are not entangled in a reversible manner.

The hydrophilic monomers used in step (E) are typically those suitable for gel polymerization.

These monomers may in particular comprise acrylic acid (AA). According to one possible embodiment, the monomers are all acrylic acids, but it is also conceivable to use as monomers a mixture comprising, inter alia, acrylic acid, mixed with other hydrophilic monomers.

According to another embodiment, the monomers used in step (E) comprise (and typically consist of) acrylamide monomers, or more generally acrylamido monomers. By acrylamido monomers is meant the family of monomers including acrylamide, its sulfonate derivative (AMPS) and quaternary ammonium (APTAC).

The acrylamide employed in step (E) is preferably a non-copper stabilized acrylamide, which may otherwise induce exothermic problems, except to introduce a copper complexing agent such as EDTA. If appropriate, the complexing content in the reaction medium is preferably of the order of 20 to 2000 ppm. When using acrylamide in step (E), it can typically be employed in the form of a powder, an aqueous solution (optionally, but not necessarily, stabilized with MEHQ hydroquinone monomethyl ether, or with copper salts (preferably with EDTA if appropriate)).

Regardless of their exact nature, the monomers of step (E) are carried out at relatively high concentrations, that is, sufficient to ensure gel formation if step (E) was conducted in the absence of control agent. In other words, the monomers are used at a concentration suitable for carrying out a gel polymerization, which are well known to those skilled in this type of polymerization. Typically, the initial concentration of monomers in the reaction medium of step (E) is at least 10%, or even at least 20% by weight relative to the total mass of the reaction medium. In particular, to further limit the phenomena of exothermicity, it is nevertheless generally preferable for this concentration to remain below 40%, preferably below 35%, or even below 30% by mass relative to the total mass of the reaction medium. Preferably, this initial concentration of monomers in the reaction medium of step (E) is between 15% and 35%, for example between 20 and 25% by weight relative to the total mass of the reaction medium. Although these concentration conditions are implemented in step (E), they do not necessarily lead to gelation of the reaction medium during the polymerization, due to the presence of the control agent. In some cases, the system gels during the polymerization, but it may remain more fluid in other cases. In all cases, step (E) allows a polymerization of controlled type, unlike the conventional type of gel polymerization, conducted without additional control agent.

According to a particular embodiment, the monomers employed in step (E) are thermosensitive macromonomers, insoluble in water beyond a certain temperature (cloud point or cloud point), but soluble at lower temperature, the step (E) being conducted at a temperature below the cloud point temperature. Macromonomers of this type typically have a polymerizable function of the acrylamido type, and a side chain composed of ethylene oxide or propylene oxide (random or block) chains, or based on N-isopropylacrylamide, or N-isopropylacrylamide caprolactam. This embodiment gives particular access to the preparation of polymers having thermo-thickening properties, used for example in the oil industry. On the other hand, it is possible to use in step (E) of the process of the invention any source of free radicals known per se as suitable for gel polymerization processes. However, preferably, it is generally preferable to use in this context a radical initiator of the redox type, which has the advantage of not requiring a heating of the reaction medium (no thermal initiation), which allows to better manage the exotherm of the reaction.

Thus, the source of free radicals employed can typically be selected from redox initiators conventionally used in radical polymerization, typically not requiring heating for their thermal initiation. It is typically a mixture of at least one oxidizing agent with at least one reducing agent.

The oxidizing agent present in the redox system is preferably a water-soluble agent. This oxidizing agent may for example be chosen from peroxides, such as: hydrogen peroxide, tertiary butyl hydroperoxide, cumene hydroperoxide, t-butyl peroxyacetate, t-butylperoxybenzoate, t butylperoxyoctoate, t-butylperoxynéodécanoate, t-butylperoxyisobutarate, lauroyl peroxide, t-amylperoxypivalte, t-butylperoxypivalate, dicumyl peroxide, benzoyl peroxide; sodium persulfate, potassium persulfate, ammonium persulfate, or even potassium bromate.

The reducing agent present in the redox system is also preferably a water-soluble agent. This reducing agent can typically be selected from sodium formaldehyde sulfoxylate (especially in its dihydrate form, known as Rongalit or in the form of an anhydride), ascorbic acid, erythorbic acid, sulphites, bisulphites or metasulfites (in particular sulphites, bisulphites or metasulfites of alkali metals), nitrilotrispropionamides, and tertiary amines and ethanolamines (preferably water-soluble).

 Possible redox systems include combinations such as:

 mixtures of water-soluble persulfates with water-soluble tertiary amines,

 mixtures of water-soluble bromates (alkali metal bromate, for example) with water-soluble sulphites (alkali metal sulphites, for example),

mixtures of hydrogen peroxide, alkyl, peresters, percarbonates and the like and of any of the iron salts or titanous salts, zinc formaldehyde sulfoxylate or sodium formaldehyde sulfoxylate, and reducing sugars,

 persulfates, perborate or perchlorate of alkali metals or ammonium in combination with an alkali metal bisulfite, such as sodium metabisulphite, and reducing sugars, and

 alkali metal persulfates in combination with an arylphosphinic acid, such as benzene phosphonic acid and the like, and reducing sugars.

An interesting redox system includes (and preferably consists of), for example, the combination of ammonium persulfate and sodium formaldehyde sulfoxylate.

In general, and in particular in the case of the use of a redox system of the ammonium persulfate / sodium formaldehyde sulfoxylate type, it proves preferable that the reaction medium of step (E) is free of copper. In the case of the presence of copper, it is generally desirable to add a copper complexing agent, such as EDTA.

The nature of the control agent implemented in step (E) can vary to a large extent.

According to an interesting variant, the control agent used in step (E) is a compound carrying a thiocarbonylthio group -S (C = S) -. According to a particular embodiment, the control agent may carry several thiocarbonylthio groups.

It may possibly be a polymer chain bearing such a group. Thus, according to a particular embodiment, the control agent used in step (E) is a living polymer resulting from a preliminary step (E ₀ ) in which the radical polymerization of a composition comprising:

 ethylenically unsaturated monomers;

 a radical polymerization control agent comprising at least one thiocarbonylthio group -S (C = S) -; and

an initiator of the radical polymerization (source of free radicals). According to this embodiment, step (E) leads to a block copolymer comprising at least one hydrophilic block of very high molar mass bonded to the polymer chain resulting from the polymerization of step (E ₀ ).

More generally, the control agent implemented in step (E) responds

advantageously with the formula (A) below:

 (AT)

in which

Z represents:

 . a hydrogen atom,

 . a chlorine atom,

 . an optionally substituted alkyl radical, optionally substituted aryl,

. an optionally substituted heterocycle,

 . an optionally substituted alkylthio radical,

 . an optionally substituted arylthio radical,

 . an optionally substituted alkoxy radical,

 . an optionally substituted aryloxy radical,

 . an optionally substituted amino radical,

 . an optionally substituted hydrazine radical,

 . an optionally substituted alkoxycarbonyl radical,

 . an optionally substituted aryloxycarbonyl radical,

 . an optionally substituted carboxy, acyloxy radical,

 . an optionally substituted aroyloxy radical,

 . an optionally substituted carbamoyl radical,

 . a cyano radical,

 . a dialkyl- or diaryl-phosphonato radical,

. a dialkyl phosphinato or diaryl phosphinato radical, or . a polymer chain,

and

 Ri represents:

 . an optionally substituted alkyl, acyl, aryl, aralkyl, alkene or alkyne group,

 . a saturated or unsaturated aromatic ring or heterocycle, optionally substituted aromatic, or

 . a polymer chain.

The groups R 1 or Z, when substituted, may be substituted with optionally substituted phenyl groups, optionally substituted aromatic groups, saturated or unsaturated carbon rings, saturated or unsaturated heterocycles, or alkoxycarbonyl or aryloxycarbonyl groups ( -COOR), carboxy (-COOH), acyloxy (-O2CR), carbamoyl (-CONR2), cyano (-CN), alkylcarbonyl, alkylarylcarbonyl, arylcarbonyl, arylalkylcarbonyl, phthalimido, maleimido, succinimido, amidino, guanidimo, hydroxy (-OH ), amino (-NR2), halogen, perfluoroalkyl C _n F _{2n +} 1, allyl, epoxy, alkoxy (-OR), S-alkyl, S-aryl, groups having a hydrophilic or ionic character such as the alkaline salts of carboxylic acids, alkali metal salts of sulfonic acid, polyalkylene oxide chains (PEO, POP), cationic substituents (quaternary ammonium salts), R representing an alkyl or aryl group, or a polymer chain.

 According to a particular embodiment, is a substituted or unsubstituted alkyl group, preferably substituted.

 The optionally substituted alkyl, acyl, aryl, aralkyl or alkyne groups generally have 1 to 20 carbon atoms, preferably 1 to 12, and more preferably 1 to 9 carbon atoms. They can be linear or branched. They may also be substituted by oxygen atoms, in particular esters, sulfur or nitrogen atoms.

 Among the alkyl radicals, mention may especially be made of the methyl, ethyl, propyl, butyl, pentyl, isopropyl, tert-butyl, pentyl, hexyl, octyl, decyl or dodecyl radical.

The alkyne groups are radicals generally of 2 to 10 carbon atoms, they have at least one acetylenic unsaturation, such as the acetylenyl radical. The acyl group is a radical generally having from 1 to 20 carbon atoms with a carbonyl group.

 Among the aryl radicals, there may be mentioned the phenyl radical,

optionally substituted in particular by a nitro or hydroxyl function.

 Among the aralkyl radicals, mention may especially be made of the benzyl or phenethyl radical, optionally substituted in particular by a nitro or hydroxyl function.

 When R 1 or Z is a polymer chain, this polymer chain may be derived from a radical or ionic polymerization or from a polycondensation.

In the context of the present invention, it is particularly advantageous to use as control agents xanthates, trithiocarbonates, dithiocarbamates, or dithiocarbazates.

Advantageously, compounds having a xanthate function -S (C = S) O-, for example carrying an O-ethyl xanthate function of formula -S, are used as control agent in step (E). (C = S) OCH ₂ CH ₃ , for example O-ethyl-S- (1-methoxycarbonylethyl) xanthate of formula (CH ₃ CH (CO ₂ CH ₃ )) S (C = S) OEt.

Another possible control agent in step (E) is dibenzyltrithiocarbonate of formula PhCH ₂ S (C = S) SCH ₂ Ph (where Ph = phenyl).

According to a particular embodiment, the control agent used in step (E) is a living polymer carrying a thiocarbonylthio function, in particular xanthate, for example O-ethyl xanthate, prepared in a prior controlled radical polymerization step in step (E).

According to an interesting embodiment of step (E), this step is carried out in the absence of any crosslinking agent. Nevertheless, in the most general case, the implementation of a crosslinking agent is not excluded in step (E).

According to another particular aspect, the subject of the present invention is the polymers as obtained at the end of the process of the invention, which comprise at least one hydrophilic polymer block of controlled mass around an average value M _n of at least 100,000 g / mol, preferably at least 500,000 g / mol, for example between 500,000 and 1,000,000 g / mol. In particular, the invention particularly relates to the polymers as obtained at the end of the process of the invention and which comprise at least one polyacrylamide block of size greater than 100,000 g / mol, preferably at least 500 000 g / mol, for example between 500 000 and 1 000 000 g / mol.

According to one particular embodiment, the polymers as obtained at the end of the process of the invention are linear, namely that they are exclusively formed of a linear sequence of monomers (it being understood that each monomer of the chaining may possibly carry a lateral group). The linear polymers within the meaning of the present description are distinguished in particular from branched polymers, which comprise a linear sequence of monomers and at least one branch on which is grafted another sequence of monomers.

The hydrophilic polymers of high mass controlled according to the invention can be advantageously used in different types of applications.

They can in particular be used as a rheology regulator (for petrochemistry for example), or as a flocculating agent (for use in the paper industry or the treatment of wastewater, in particular). They can also be used as thickeners, or as viscosifying agents, gelling agents, surface modifiers, and for the constitution of nanonohybrid materials. More generally, they can also be used as vectorization agents.

Various features and advantages of the invention will be further illustrated by the following examples in which polymers have been prepared according to the method of the invention.

In these examples, the number-average molecular weight of the synthesized polymers was compared, by way of indication, with the theoretical number-average molecular weight, which would be obtained in the context of a perfectly controlled polymerization, which makes it possible to validate the character particularly well controlled polymerization performed according to the invention, radically opposite to the results usually obtained when implementing the conditions of a gel polymerization.

The theoretical average molecular weight referred to herein is calculated according to the following formula: Mn (theo) = ^^ - xM _MU x Conv. + M _x where:

Mn (t _h eo) = Mean mass in theoretical number

[M] ₀ = initial concentration of monomer

[X] ₀ = initial concentration of control agent

M _MU = molar mass of the monomer

Conv. = conversion of the monomer (reaction yield) M _x = Molar mass of the control agent

EXAMPLE 1 Synthesis of a Polyacrylamide According to the Invention (Control Agent: Living Prepolymer with Xanthate Function - Initiator: Ammonium Persulfate / Sodium Formaldehyde Sulfoxylate Pair)

1 .1: Synthesis of a living P1 polv (acrylamide) prepolymer

In a 50 ml flask was added at room temperature (20 ° C) 6 g of powdered acrylamide (the acrylamide powder employed in all the examples is free of copper), 15.2 g. of distilled water, 2.53 g of O-ethyl-S- (1-methoxycarbonylethyl) xanthate of formula (CH ₃ CH (CO ₂ CH ₃ )) S (C = S) OEt, 8 g of ethanol and 150 mg of initiator V-50 (2,2'-Azobis (2-methylpropionamidine) dihydrochloride). The mixture was degassed by bubbling extra pure argon for 30 minutes. The flask was then placed in an oil bath thermostated at 60 ° C and the polymerization reaction was allowed to proceed with stirring for 3 hours at 60 ° C.

 A conversion of 100% (determined by 1 H NMR) was obtained. The number average molecular weight of the prepolymer P1, determined by NMR H, is 750 g / mol.

1 .2: Gel polymerization of acrylamide (using P1 as a control agent)

 After step 1 .1, the reaction mixture was dried under vacuum to evaporate the ethanol and the extract was readjusted by adding distilled water to obtain an aqueous solution S1 of the pre-polymer P1 at 50% by weight.

 In a 200 ml flask, at room temperature, 20 g of powdered acrylamide, 56 g of distilled water and 30 mg of solution S1 were introduced. The mixture was degassed by bubbling extra pure argon for 30 minutes, then the temperature of the solution was lowered to 10 ° C. Ammonium persulfate and sodium formaldehyde sulfoxylate, as two aqueous solutions at 0.6% by weight, were added in one go, with 2 ml of each of the solutions being introduced. These two aqueous solutions of ammonium persulfate and sodium formaldehyde sulfoxylate were degassed beforehand by bubbling with argon.

 The polymerization reaction was then allowed to proceed with stirring for 24 hours at room temperature (20 ° C.).

At the end of the 24 hours of reaction, a conversion of 98% (determined by H NMR) was obtained. An analysis in steric exclusion chromatography in water with additive NaNO ₃ (0.1 N) with an eighteen angle MALLS detector provides the following average molecular weight (M _n ) and polymolecularity index (M _w / M _n ) values:

M _n = 1 062 000 g / mol M _w / M _n = 1.89.

 For comparison purposes, the theoretical average molecular weight is 990 00 g / mol

EXAMPLE 2 Synthesis of a Polyacrylamide According to the Invention (Control Agent: Living Pre-polymer with Xanthate Function-Initiator: Ammonium Persulfate / Sodium Formaldehyde Sulfoxylate Couple)

 The same prepolymer P1 as that of Example 1 was used in this example, prepared under the conditions of Step 1 .1 of Example 1 and used in the form of the same aqueous solution S1 as that of Step 1 .2 of Example 1.

 In a 200 ml flask, at room temperature, 20 g of powdered acrylamide, 56 g of distilled water and 35 mg of solution S1 were introduced. The mixture was degassed by bubbling extra pure argon for 30 minutes, then the temperature of the solution was lowered to 10 ° C. Ammonium persulfate and sodium formaldehyde sulfoxylate, as two aqueous solutions at 0.6% by weight, were added in one go, with 2 ml of each of the solutions being introduced. As in Example 1, the two aqueous solutions of ammonium persulfate and sodium formaldehyde sulfoxylate were degassed beforehand by bubbling with argon.

 The polymerization reaction was then allowed to proceed with stirring for 24 hours at room temperature (20 ° C.).

At the end of the 24 hours of reaction, 96% conversion was obtained (determined by H NMR). An analysis in water additive steric exclusion chromatography of NaNO ₃ (0.1 N) with an eighteen angle MALLS detector provides the values of number average molecular weight (M _n ) and polymolecularity index ( M _w / M _n ) following:

M _n = 846,000 g / mol M _w / M _n = 1.89.

For comparison purposes, the theoretical average molecular weight is 812 00 g / mol EXAMPLE 3 Synthesis of a Polyacrylamide According to the Invention (Control Agent: Living Pre-polymer with Xanthate Function - Initiator: Ammonium Persulfate / Sodium Formaldehyde Sulfoxylate Couple)

 Here again, the same prepolymer P1 as that of Example 1 was used in this example, prepared under the conditions of Step 1 .1 of Example 1 and used in the form of the same aqueous solution S1. than that of step 1 .2 of example 1.

 In a 200 ml flask, at room temperature, 20 g of powdered acrylamide, 56 g of distilled water and 50 mg of solution S1 were introduced. The mixture was degassed by bubbling extra pure argon for 30 minutes, then the temperature of the solution was lowered to 10 ° C. Ammonium persulfate and sodium formaldehyde sulfoxylate, as two aqueous solutions at 0.6% by weight, were added in one go, with 2 ml of each of the solutions being introduced. As in Example 1, the two aqueous solutions of ammonium persulfate and sodium formaldehyde sulfoxylate were degassed beforehand by bubbling with argon.

 The polymerization reaction was then allowed to proceed with stirring for 24 hours at room temperature (20 ° C.).

At the end of the 24 hours of reaction, a conversion of 88% (determined by 1 H NMR) was obtained. An analysis in water additive steric exclusion chromatography of NaNO ₃ (0.1 N) with an eighteen angle MALLS detector provides the values of number average molecular weight (M _n ) and polymolecularity index ( M _w / M _n ) following:

M _n = 640,000 g / mol M _w / M _n = 1.81.

 For comparison purposes, the theoretical average molecular weight is 530,000 g / mol

EXAMPLE 4 Synthesis of a Polyacrylamide According to the Invention (Control Agent: Live Pre-Polymer with Xanthate Function - Initiator: Ammonium Persulfate / Sodium Formaldehyde Sulfoxylate Couple)

 The same prepolymer P1 as that of Example 1 was used in this example, prepared under the conditions of Step 1 .1 of Example 1 and used in the form of the same aqueous solution S1 as that of Step 1 .2 of Example 1.

In a 200 ml flask, at room temperature, 10 g of acrylamide powder, 26 g of distilled water and 35 mg of solution S1 were introduced. The mixture was degassed by bubbling extra pure argon for 30 minutes, then the temperature of the solution was lowered to 10 ° C. Ammonium persulfate and sodium formaldehyde sulfoxylate, as two aqueous 0.6% by weight solutions, were added in one go, 1 ml of each of the solutions being introduced. As in Example 1, the two aqueous solutions of ammonium persulfate and sodium formaldehyde sulfoxylate were degassed beforehand by bubbling with argon.

 The polymerization reaction was then allowed to proceed with stirring for 24 hours at room temperature (20 ° C.).

At the end of the 24 hours of reaction, a conversion of 100%, determined by NMR H, was obtained. An analysis in steric exclusion chromatography in water with NaNO ₃ additive (0.1 N) with a MALLS detector. eighteen angles provides the following average molecular weight values (M _n ) and polymolecularity index (M _w / M _n ):

M _n = 452 700 g / mol M _w / M _n = 1.59.

 For comparison purposes, the theoretical average molecular weight is 410,000 g / mol

EXAMPLE 5 Synthesis of a Polyacrylamide According to the Invention (Control Agent: Living Prepolymer with Xanthate Function - Initiator: Ammonium Persulfate / Sodium Formaldehyde Sulfoxylate Couple)

 The same prepolymer P1 as that of Example 1 was used in this example, prepared under the conditions of Step 1 .1 of Example 1 and used in the form of the same aqueous solution S1 as that of Step 1 .2 of Example 1.

 In a 200 ml flask, at room temperature, 10 g of acrylamide powder, 26 g of distilled water and 150 mg of solution S1 were introduced. The mixture was degassed by bubbling extra pure argon for 30 minutes, then the temperature of the solution was lowered to 10 ° C. Ammonium persulfate and sodium formaldehyde sulfoxylate, as two aqueous 0.6% by weight solutions, were added in one go, 1 ml of each of the solutions being introduced. As in Example 1, the two aqueous solutions of ammonium persulfate and sodium formaldehyde sulfoxylate were degassed beforehand by bubbling with argon.

The polymerization reaction was then allowed to proceed with stirring for 24 hours at room temperature (20 ° C.). At the end of the 24 hours of reaction, a conversion of 100%, determined by NMR H, was obtained. An analysis in steric exclusion chromatography in water with NaNO ₃ additive (0.1 N) with a MALLS detector. eighteen angles provides the following average molecular weight values (M _n ) and polymolecularity index (M _w / M _n ):

M _n = 103 700 g / mol M _w / M _n = 1.59.

 For comparison purposes, the theoretical average molecular weight is 100,000 g / mol

Although Examples 1 to 5 have been carried out with an unstabilized acrylamide, similar results are obtained with stabilized acrylamides, for example with copper salts (with the addition of an EDTA-type complexing agent to prevent exothermicity), or well by the MEHQ.

EXAMPLE 6 Synthesis of a diblock copolymer poly (acrylic acid) -b- poly (acrylamide) - Synthesis of the poly (acrylamide) block according to the invention (control agent: xanthate-terminated live polyacrylate - initiator: persulfate pair of ammonium / sodium formaldehyde sulfoxylate)

6.1: Synthesis of a Living Acrylic Polviacide Xanthate-terminated (Polymer P6)

In a 15 ml flask at room temperature, 4 g of acrylic acid, 3.2 g of distilled water, 0.8 g of ethanol and 87 mg of 0-ethyl-S- (1-methoxycarbonyl) were introduced. ethyl) xanthate of formula (CH ₃ CH (CO ₂ CH ₃ )) S (C = S) OEt and 25 mg of 4,4'-Azobis (4-cyanovaleric) acid. The mixture was degassed by bubbling extra pure argon for 30 minutes.

 The flask was then placed in a thermostat'Ό thermostated oil bath, and the reaction mixture was stirred for 2 hours at 60 ° C.

 At the end of these two hours, a conversion of 99% was determined by NMR H.

An analysis in water additive steric exclusion chromatography of NaNO ₃ (0.1 N) with an eighteen angle MALLS detector provides the values of number average molecular weight (M _n ) and polymolecularity index ( M _w / M _n ) for the polymer P6 thus obtained:

M _n = 13000 g / mol M _w / M _n = 1, 52.

6.2: Synthesis of the diblock copolymer At the end of step 6.1, the reaction mixture was dried under vacuum and then taken up in ethanol and precipitated in diethyl ether. The precipitate obtained was dried under vacuum for 24 hours in order to remove the residual solvents, whereby the polymer P6 was obtained in the form of a dried powder.

 20 mg of this dried powder of polymer P6 was introduced into a 15 ml flask at room temperature and then 2 g of powdered acrylamide and 5.6 g of distilled water were added to the flask.

 The mixture was degassed by bubbling extra pure argon for 30 minutes, then the temperature of the solution was lowered to 10 ° C. Ammonium persulfate and sodium formaldehyde sulfoxylate, as two aqueous solutions at 0.6% by weight, were added in one go, with 0.2 ml of each of the solutions being introduced. The two aqueous solutions of ammonium persulfate and sodium formaldehyde sulfoxylate were degassed beforehand by bubbling with argon.

 The polymerization reaction was then allowed to proceed with stirring for 24 hours at room temperature (20 ° C.).

 At the end of the 24 hours of reaction, 96% conversion was obtained as determined by 1H NMR.

An analysis in water additive steric exclusion chromatography of NaNO ₃ (0.1 N) with an eighteen angle MALLS detector provides the values of number average molecular weight (M _n ) and polymolecularity index ( M _w / M _n ) following:

M _n = 682,000 g / mol M _w / M _n = 2.18.

 For comparison purposes, the theoretical average molecular weight is 890,000 g / mol

EXAMPLE 7 Synthesis of a diblock copolymer poly (acrylic acid) -b-poly (acrylamide) - Synthesis of the poly (acrylamide) block according to the invention (control agent: xanthate-terminated live polyacrylate - initiator: persulfate pair of ammonium / sodium formaldehyde sulfoxylate)

 The same polymer P6 as that of Example 6 was used in this example, used in the form of a powder prepared under the conditions of step 6.2 of Example 6.

210 mg of the P6 polymer powder were introduced into a 15 ml flask at room temperature and then 2 g of acrylamide powder and 5.6 g of distilled water were added to the flask. The mixture was degassed by bubbling extra pure argon for 30 minutes, then the temperature of the solution was lowered to 10 ° C. Ammonium persulfate and sodium formaldehyde sulfoxylate, as two aqueous solutions at 0.6% by weight, were added in one go, with 0.2 ml of each of the solutions being introduced. The two aqueous solutions of ammonium persulfate and sodium formaldehyde sulfoxylate were degassed beforehand by bubbling with argon.

 The polymerization reaction was then allowed to proceed with stirring for 24 hours at room temperature (20 ° C.).

 At the end of the 24 hours of reaction, a conversion of 99%, as determined by 1 H NMR, was obtained.

An analysis in water additive steric exclusion chromatography of NaNO ₃ (0.1 N) with an eighteen angle MALLS detector provides the values of number average molecular weight (M _n ) and polymolecularity index ( M _w / M _n ) following:

M _n = 108,000 g / mol M _w / M _n = 1, 46.

For comparison purposes, the theoretical average molecular weight is 100,000 g / mol

EXAMPLE 8 Synthesis of a poly (2-acrylamido-2-methylpropanesulphonic acid) -b-poly (acrylamide) diblock copolymer Synthesis of the poly (acrylamide) block according to the invention (control agent: poly (AMPS) xanthate-initiator termination: ammonium persulfate / sodium formaldehyde sulfoxylate pair

8.1 Synthesis of a terminally xanthate-terminated poly (2-acrylamido-2-methylpropanesulphonic acid) (polymer P8)

25 g of an aqueous solution of 2-acrylamido-2-methylpropanesulphonic acid (AMPS, concentration: 50% by weight), 1.4 g of distilled water, were introduced into a 25 ml flask at room temperature. 1.2 g of ethanol, 90 mg of 0-ethyl-S- (1-methoxycarbonylethyl) xanthate of formula (CH ₃ CH (CO ₂ CH ₃ )) S (C = S) OEt and 40 mg of acid 4,4'-Azobis (4-cyanovaleric). The mixture was degassed by bubbling extra pure argon for 30 minutes. The flask was then placed in an oil bath thermostated at 60 ° C., and the reaction medium was left stirring for 2 hours at 60 ° C.

 At the end of these two hours, a conversion of 99% was determined by NMR H.

An analysis in water additive steric exclusion chromatography of NaNO ₃ (0.1 N) with an eighteen angle MALLS detector provides the values of number average molecular weight (M _n ) and polymolecularity index ( M _w / M _n ) following:

M _n = 10 700 g / mol M _w / M _n = 1.45. 8.2: Synthesis of the diblock copolymer

 At the end of step 8.1, the reaction mixture was dried under vacuum and then taken up in ethanol and precipitated in diethyl ether. The precipitate obtained was dried under vacuum for 24 hours in order to remove the residual solvents, whereby the polymer P8 was obtained in the form of a dried powder.

 20 mg of this dried P8 polymer powder were introduced into a 15 ml flask at room temperature, and then 2 g of acrylamide powder and 5.6 g of distilled water were added to the flask.

 The mixture was degassed by bubbling extra pure argon for 30 minutes, then the temperature of the solution was lowered to 10 ° C. Ammonium persulfate and sodium formaldehyde sulfoxylate, as two aqueous solutions at 0.6% by weight, were added in one go, with 0.2 ml of each of the solutions being introduced. The two aqueous solutions of ammonium persulfate and sodium formaldehyde sulfoxylate were degassed beforehand by bubbling with argon.

 The polymerization reaction was then allowed to proceed with stirring for 24 hours at room temperature (20 ° C.).

 At the end of the 24 hours of reaction, 96% conversion was obtained as determined by 1H NMR.

An analysis in water additive steric exclusion chromatography of NaNO ₃ (0.1 N) with an eighteen angle MALLS detector provides the values of number average molecular weight (M _n ) and polymolecularity index ( M _w / M _n ) following:

M _n = 730,000 g / mol M _w / M _n = 2.51.

For comparison purposes, the theoretical average molecular weight is 950 000 g / mol Example 9 Synthesis of a poly (2-acrylamido-2-methylpropanesulphonic acid) -b-poly (acrylamide) diblock copolymer Synthesis of the poly (acrylamide) block according to the invention (control agent: poly (AMPS) xanthate-initiator termination: ammonium persulfate / sodium formaldehyde sulfoxylate pair

The same polymer P8 as that of Example 8 was used in this example, used in the form of a powder prepared under the conditions of step 8.2 of Example 8.

215 mg of the P8 polymer powder was introduced into a 15 ml flask at room temperature and then 2 g of powdered acrylamide and 5.6 g of distilled water were added.

 The mixture was degassed by bubbling extra pure argon for 30 minutes, then the temperature of the solution was lowered to 10 ° C. Ammonium persulfate and sodium formaldehyde sulfoxylate, as two aqueous solutions at 0.6% by weight, were added in one go, with 0.2 ml of each of the solutions being introduced. The two aqueous solutions of ammonium persulfate and sodium formaldehyde sulfoxylate were degassed beforehand by bubbling with argon.

 The polymerization reaction was then allowed to proceed with stirring for 24 hours at room temperature (20 ° C.).

 At the end of the 24 hours of reaction, a conversion of 100%, as determined by 1 H NMR, was obtained.

An analysis in water additive steric exclusion chromatography of NaNO ₃ (0.1 N) with an eighteen angle MALLS detector provides the values of number average molecular weight (M _n ) and polymolecularity index ( M _w / M _n ) following:

M _n = 105,000 g / mol M _w / M _n = 2.44.

 For comparison purposes, the theoretical average molecular weight is 100,000 g / mol

EXAMPLE 10 Synthesis of a diblock copolymer poly (acrylamidopropyltrimethylammonium chloride) -b-poly (acrylamide) - Synthesis of the poly (acrylamide) block according to the invention (control agent: xanthate-terminated living polymer - initiator: persulfate couple ammonium / sodium formaldehyde sulfoxylate) 10.1: Synthesis of Xanthate-terminated Living Poly (acrylamidopropyltrimethylammonium) Polymer Chloride (Polymer P10)

25 g of a solution of acrylamidopropyltrimethylammonium chloride (solution 75% by weight in water), 3.9 g of distilled water, 1.3 g of ethanol, were introduced into a 25 ml flask at room temperature. mg of 0-ethyl-S- (1-methoxycarbonylethyl) xanthate of formula (CH ₃ CH (CO ₂ CH ₃ )) S (C = S) OEt and 30 mg of initiator V-50 (2.2%). Azobis (2-methylpropionamidine) dihydrochloride). The mixture was degassed by bubbling extra pure argon for 30 minutes.

 The flask was then placed in an oil bath thermostated at 60 ° C., and the reaction medium was left stirring for 2 hours at 60 ° C.

 At the end of these two hours, a conversion of 99% was determined by NMR H.

An analysis in water additive steric exclusion chromatography of NaNO ₃ (0.1 N) with an eighteen angle MALLS detector provides the values of number average molecular weight (M _n ) and polymolecularity index ( M _w / M _n ) following:

M _n = 13 100 g / mol M _w / M _n = 1.64.

10.2: Synthesis of the diblock copolymer

 After step 10.1, the reaction mixture was dried under vacuum and then taken up in ethanol and precipitated in diethyl ether. The precipitate obtained was dried under vacuum for 24 hours in order to remove the residual solvents, whereby the polymer P10 was obtained in the form of a dried powder.

 20 mg of this dried P10 polymer powder were introduced into a 15 ml flask at room temperature and then 2 g of acrylamide powder and 5.6 g of distilled water were added to the flask.

 The mixture was degassed by bubbling extra pure argon for 30 minutes, then the temperature of the solution was lowered to 10 ° C. Ammonium persulfate and sodium formaldehyde sulfoxylate, as two aqueous solutions at 0.6% by weight, were added in one go, with 0.2 ml of each of the solutions being introduced. The two aqueous solutions of ammonium persulfate and sodium formaldehyde sulfoxylate were degassed beforehand by bubbling with argon.

The polymerization reaction was then allowed to proceed with stirring for 24 hours at room temperature (20 ° C.). At the end of the 24 hours of reaction, a conversion of 99%, as determined by 1 H NMR, was obtained.

An analysis in water additive steric exclusion chromatography of NaNO ₃ (0.1 N) with an eighteen angle MALLS detector provides the values of number average molecular weight (M _n ) and polymolecularity index ( M _w / M _n ) following:

M _n = 806,000 g / mol M _w / M _n = 3.25.

 For comparison purposes, the theoretical average molecular weight is 900,000 g / mol

EXAMPLE 11 Synthesis of a diblock copolymer poly (acrylamidopropyltrimethylammonium chloride) -b-poly (acrylamide) - Synthesis of the poly (acrylamide) block according to the invention (control agent: xanthate-terminated living polymer - initiator: persulfate couple ammonium / sodium formaldehyde sulfoxylate)

Step 1: Synthesis of the poly (acrylamidopropyltrimethylammonium chloride) block

The same polymer formed in Example 8 is used.

Step 2: Synthesis of the diblock copolymer

 The same polymer P10 as that of Example 10 was used in this example, used in the form of a powder prepared under the conditions of Step 10.2 of Example 10.

 215 mg of the P8 polymer powder was introduced into a 15 ml flask at room temperature and then 2 g of powdered acrylamide and 5.6 g of distilled water were added.

 . The mixture was degassed by bubbling extra pure argon for 30 minutes, then the temperature of the solution was lowered to 10 ° C. Ammonium persulfate and sodium formaldehyde sulfoxylate, as two aqueous solutions at 0.6% by weight, were added in one go, with 0.2 ml of each of the solutions being introduced. The two aqueous solutions of ammonium persulfate and sodium formaldehyde sulfoxylate were degassed beforehand by bubbling with argon.

The polymerization reaction was then allowed to proceed with stirring for 24 hours at room temperature (20 ° C.). At the end of the 24 hours of reaction, a conversion of 98% was obtained, as determined by 1 H NMR.

An analysis in steric exclusion chromatography in water with NaNO ₃ additive (0.1 N) with an eighteen angle MALLS detector gives the values of number average molecular weight (M _n ) and polymolecularity index. (M _w / M _n ) following:

M _n = 160 500 g / mol M _w / M _n = 2.0.

 For comparison purposes, the theoretical average molecular weight is 100,000 g / mol

Claims

1. - Process for preparing a polymer comprising at least one gel polymerization step (E) in which:

water-soluble ethylenically unsaturated monomers, which are identical or different;

a source of free radicals adapted to the polymerization of said monomers, typically a redox system; and

an agent for controlling the radical polymerization, preferably comprising a thiocarbonylthio -S (C = S) - group, with a monomer concentration within the reaction medium of the step (E) which is sufficiently high to induce gelation of the medium if the polymerization was conducted in the absence of the control agent.

2. - The method of claim 1, wherein in step (E), the monomers, the source of free radicals and the control agent are contacted in aqueous medium.

3. - Process according to claim 1 or 2, wherein in step (E), the monomers used in step (E) comprise or consist of acrylamido monomers.

4. - Method according to one of claims 1 to 3, wherein in step (E), the initial concentration of monomers in the reaction medium of step (E) is between 10 and 40% by weight by relative to the total mass of the reaction medium

5. - Method according to one of claims 1 to 4, wherein in step (E), the source of free radicals employed is a redox initiator.

6. - The method of claim 5, wherein in step (E), the source of free radicals is a redox system which is a combination of ammonium persulfate and sodium formaldehyde sulfoxylate.

7. - Method according to one of claims 1 to 6, wherein in step (E), the control agent used is a compound bearing a thiocarbonylthio group -S (C = S) -.

8. - The method of claim 7, wherein in step (E), the control agent used is a compound carrying a xanthate function -S (C = S) O-, for example carrying a O-ethyl xanthate function of formula -S (C = S) OCH ₂ CH ₃ .

9. - The method of claim 7 or 8, wherein in step (E), the control agent used is a living polymer carrying said thiocarbonylthio function, which is prepared in a step of controlled radical polymerization prior to l step (E).

10. - Method according to one of claims 1 to 9, wherein the reaction medium of step (E) is free of copper.

1 1. - Process according to one of claims 1 to 10, wherein step (E) is carried out in the absence of any crosslinking agent.

12. - Method according to one of claims 1 to 1 1, wherein in step (E), the initial concentration of control agent in the medium is chosen such that the number average molecular weight M _n of the hydrophilic polymer synthesized is greater than 100,000 g / mol, preferably greater than or equal to 500,000 g / mol.

13. - Polymer obtainable at the end of the process of claim 12, which comprises at least one hydrophilic polymer block of controlled mass around an average value M _n of at least 100,000 g / mol, preferably at least 500,000g / mol.

14. Polymer according to claim 13, which comprises at least one polyacrylamide block of controlled mass around an average value M _n of at least 100,000 g / mol, preferably at least 500,000 g / mol.

15. - Polymer according to claim 13 or 14, characterized in that it is linear.

16. - Use of a polymer according to claim 13 to 15, as a rheology regulator, flocculating agent, thickener, viscosifier, gelling agent, surface modifier, or for the formation of nanohybrid materials.