CA2914715C - Cross-linkers for the preparation of a new family of single ion conduction polymers for electrochemical devices and such polymers - Google Patents
Cross-linkers for the preparation of a new family of single ion conduction polymers for electrochemical devices and such polymers Download PDFInfo
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- VWGUPMLBQYVKHT-UHFFFAOYSA-N CC([NH2+][SH+](c1ccc(C=C)cc1)=O)S(c1ccc(C=C)cc1)(O)=O Chemical compound CC([NH2+][SH+](c1ccc(C=C)cc1)=O)S(c1ccc(C=C)cc1)(O)=O VWGUPMLBQYVKHT-UHFFFAOYSA-N 0.000 description 1
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Abstract
The copolymers described are either polyvinylsulfonates or acrylate vinylsulfonate block-copolymers. Preferred acrylate monomers are methacrylates and preferred vinylsulfonates are styrene sulfonates. The copolymer is prepared by radical polymerization of the vinyl sulfonate and the cross-linker and optionally the acrylate, in particular radical photopolymerization using a functionalized bis(acyl)phosphane oxide (BAPO) as photoinitiator. Also described is the use of such copolymer as solid polymer electrolyte in a lithium ion battery.
(see formula I)
Description
SINGLE ION CONDUCTION POLYMERS FOR ELECTROCHEMICAL
DEVICES AND SUCH POLYMERS
Technical Field The present invention concerns cross-linkers suitable for being used in the production of conducting copolymers that are suitable for being used in lithium ion batteries as well as such copolymers.
Background Art The development of fully electric or hybrid vehicles has become an urgent need for sustainable long-term development.[1] The most important challenge in the near future is to find a safe, cheap and efficient battery technology that would provide electric vehicles with an extended driving range (>300 km). The corresponding increase in energy density requires the development of new chemistries for both the active electrode materials and the electrolyte.[2] Lithium metal is the ultimate anode and the only choice to complement the positive air (02) or sulfur cathodes and to take advantage of the high specific capacities of these cathodes.[3] Nevertheless, the use of lithium metal in contact with a liquid electrolyte leads to important safety problems associated with the formation of irregular metallic lithium electrodeposits during the recharge. This would result in dendrite formation responsible for explosion hazards. To meet the requirements of the electric vehicle mass market, the Li ion batteries must improve the safety issues related to the thermal instability,[4] with formation of flammable reaction products, the possibility of leaks, and internal short-circuits. Solid-state electrolytes are the perfect solution to mitigate the lithium dendritic growth.[5] The use of a solid polymer electrolyte (SPE), where a lithium salt is associated with a polar polymer matrix, can solve most of the safety issues mentioned above.
Moreover, other advantages related to the battery processing, as the lamination (Li metal, electrolyte, composite, cathode), stacking and hermetic sealing would be easier and cost-effective with a polymer electrolyte.
lf
In the last years, blending different types of polymers or direct copolymerization have been broadly used to match the requirements in terms of ionic conductivity and mechanical properties of SPE polymers. The advantage of a copolymer approach is the possibility of tailoring the mechanical properties as the rigidity/malleability by functionalization of the building blocks, which might include a new polymeric unit. By combining different functional units, the lithium conductivity and the electrochemical stability against alkaline metals can be improved. The mobility of the polymer chains can be enhanced by combining the copolymer with a plasticizer to avoid dense packing of the polymer and crystallization.
Up to now, however, conducting polymers that meet the mechanical and conductivity demands have not yet been provided to satisfaction.
Therefore it is the goal of the present invention to provide monomers, ,
Disclosure of the Invention Hence, it is a general object of the invention to provide a cross-linker suitable as cornonomer in the production of single-ion solid copolymer electrolytes.
Now, in order to implement these and still further objects of the invention, which will become more readily apparent as the description proceeds, the cross linker is manifested by the features that it is a bis(styrylsulfonylimide) alkaline metal salt, i.e. the compound of formula (I) as below Mr 0. = 0 õ (I) 01 a, " : Ify *...,:- =...,,b . N *
/
wherein M+ is Li+ or Na.
A presently preferred salt is the lithium salt.
This cross-linker is especially suitable for use in the preparation of single ion conduction polymers (also termed (single-ion) conducting (co)polymers or (single-ion) conductor (co)polymers) or, if used for application in batteries, (single-ion) conducting (solid) electrolyte or merely solid electrolyte).
In the production of single-ion solid copolymer electrolytes any radical initiator can be used, i.e. thermally activated and UV activated radical initiators and mixtures of thermally activated and UV activated radical
Suitable photoinitiators include a-hydroxyketones, benzophenones, benzyl derivatives, thioxanthones, acetylphosphanes, alkoxyamines or especially acylphosphane oxides. Acetylphosphanes and in particular acetylphosphane oxides allow high curing speeds at higher material depths. Presently preferred are photoinitiators of the acetylphosphane type or acylphosphane oxide type as they are e.g. described in WO 2006/056541, WO 2011/003772 and WO 2014/053455.
The general structure of acylphosphane oxide type photoinitiators is represented by formula (II) below:
R3(21) 0 (II) [U R21 I I Jrn _ n X
In such photoinitiators:
n is from 1 to 6, preferably n is equal to 1, 2, 3 or 4, and more preferably 1 or 2, M iS 1 Or 2, X is oxygen or sulfur, R1 is ¨C(R4)3, wherein if n=1, all R4 are independently from each other selected from the group consisting of - H, - aromatic groups, - alkenyl groups and r - aliphatic groups, wherein the aliphatic groups can be unbranched or branched, non-substituted or substituted by one or more of the following groups: aromatic groups, heteroaromatic groups, heterocyclic groups, ethers (polyethyleneglycol or polyethylene oxide), selenides, hydroxyl,
if n>1, in particular n is from 2 to 6, preferably n is 2, 3 or 4, at least one R4 is a 2 to 6-valent substituent selected from the list described above, wherein the afore mentioned alkyl can also comprise one, two or more of the afore mentioned groups within the chain, i.e. the aliphatic chain may be once, twice or more times interrupted (or interconnected) by functional groups previously mentioned, or be substituted once or more times with such groups, wherein said groups are non-successive, i.e. separated by at least one CH2-group R2 is an aryl group, preferably 2,4,6-trimethylphenyl (mesityl) or 2,6-dimethoxyphenyl, and R3 is ¨C(R4)3 as specified above for R1.
Such photoinitiators can be used in combination with photoinitiators of the same class and/or in combination with photoinitiators of other class(es).
Preferred initiators are bis(acyl)phosphane oxides (BAPOs). Such BAPOs can e.g. be used together with initiators that can complement the curing properties of the BAPOs, such as a-hydroxyketones, benzophenones, benzyl derivatives, thioxanthones, or other acylphosphane oxides.
In presently preferred embodiments, the radical initiator is a photoinitiator suitable to generate two radicals, in particular a photoinitiator of formula (II) above wherein:
nisi,
These photoinitiators will further be termed BAPO (for bis(acyl)phosphane oxide).
The synthesis of the BAPO photo-initiators (BAPO-1 and derivatives BAPO-2, BAPO-3, BAPO-4 and BAPO-5 and BAPO-6) are available through patents PCT/EP2013/070378 (WO 2014/053455), WO 2006/056541 and WO
2011/003772.
As already indicated above, presently preferred photoinitiators used within this invention include either R1 being small functional groups (BAPO-1
obtainable by polymerizing BAPO-2) with a Mn of up to about 2400 such as 2136 for the BAPO-4 used herein. BAPO-5 is functionalized with a polyethyleneoxide (PEO, Mn 6000) bonded at a phosphorous atom at each end (n= 2). The nature of the BAPO can influence the final polymer not only via the side chains attached but also via its polymerization activity, leading to polymers with different mechanical and conducting properties. In the following formulas, Mes is mesitylene or 1,3,5-trimethylbenzene, respectively.
ARA ARA
Mes P Mes Mes P Mes 0 0 0 0 Mes 0 0=P 0 Mes 0 pr.0 A CP-NMes 0 A, Mes (:)1 Mn 6000 0 n = 100 LCI" w BAPO-3 )( 000 A o o 0 0 Mes P Mes ARAMes P Mes Mes P Mes 0 0 LINMe3+13r-00 Siz:
Ll Si.
NMe3+ Cl- 'si-d Dependent on the one or more radical initiator chosen, the cross-linker of the present invention can be used together with a vinyl sulfonate monomer, preferably styrene sulfonate monomer, alone or together with an acrylate monomer to form a copolymer (CP) that ¨ in case that acrylate monomer is added ¨ is also called a tri-block copolymer (TBP) or ¨ in the absence of acrylate di-block-copolymer (DBP). For lithium-ion batteries the preferred alkaline metal is lithium, for sodium batteries sodium.
Copolymers of methacrylate, the linker and a lithium styrene sulfonate monomer, prepared using one of BAPO-1 to BAPO-5 were found to be thermally stable up to above 190 C and offering a single-ion conductivity in the range of 10-4 S cm-1 at 60 C, i.e. one order of magnitude superior to the state of the art in single-ion polymer electrolytes[10].
As already mentioned above, the non-fluorinated single-ion conduction copolymer electrolytes comprising (meth)acrylates are also termed tri-block polymers (TBP) although their actual structure cannot be determined due to lacking solubility. Thus, that the inventive copolymer electrolytes might be tri-block copolymers is a mere assumption based the fact that acrylates like methacrylates are known for fast homopolymerization and on the solid content and isolated yield of the obtained polymer. Nevertheless, the invention shall not be limited in any way by this assumption or this terminology.
In analogy to TBPs copolymers of vinyl sulfonate monomers and cross-linker are termed di-block (co)polymers (DBP) since ¨ due to the difference in molar ratios ¨ at least blocks of polyvinylsulfonates are present.
The copolymer (TBP) is suitably formed by a radical initiator (in particular a photoinitiator such as a BAPO) with promoted polymerization of an acrylate, preferably a methacrylate, in particular methylmethacrylate, an alkaline metal vinyl sulfonate monomer, preferably a styrene sulfonate like lithium styrene sulfonate and a bifunctional vinyl monomer linker, i.e. the alkaline metal (bis(styrenesulfonyl)imide), like lithium (bis(styrenesulfonyl)imide) in aqueous media. The general structure of a
M+ 802 N" M+ = Li + or Na+
- +
* *
. 0 le) Rn' Polymer CP-1 or TBP-1: R = -CH2CH2CO(OCH2CH2)20CH2CH3 Polymer CP-2 or TBP-2: R = -CH2CH2CO2(CH2)3Si(OCH3)3 Polymer CP-3 or TBP-3: R = -CH2CH2CO2(CH2)2NMe3+Br-Polymer CP-4 or TBP-4: R = -CH2CH2e01 (CH 1 Sian _ _2x _ _ 3-Polymer CP-5 or TBP-5: R = -CH2CH2CO(OCH2CH2)nO2COCH2CF12-Polymer CP-6 or DBP-6 (n=0): R = -CH2CH2CH2N(CH3)3Br Dependent on the desired features, the monomer ratios can be varied within certain ranges. The sulfonyl groups are needed for conductivity while in certain embodiments, dependent on the photoinitiator used, a (meth)acrylate is needed for mechanical stability . Taking these demands in consideration, the ratio of vinyl sulfonate monomer to acrylate monomer is 1 : 0 to 1 : 4.
The cross linking monomer can be present in a ratio of up to 20 mol% referred to the amount of the other monomers, i.e. the acrylate monomers and the vinyl sulfonate monomers, and preferably is present in amounts of about 10 mol%.
In specific embodiments, in particular if BAPOs are used that comprise an ester group in R1 like BAPO-1 to BAPO-5, the ratio of alkaline metal vinyl 1.0 sulfonate monomer : acrylate monomer can be varied from about 1 : 4 to about 4 : 1 (or the other way round the acrylate monomer : alkaline metal sulfonate vinyl monomer can be varied from about 4: 1 to about 1 : 4) with a ratio of about 1 : 1 being presently preferred. Therefore, in a presently preferred embodiment a molar ratio of (meth)acrylate groups to sulfonate groups is about 1 and preferably the ratio of (meth)acrylate : vinyl sulfonate :
bis(styrenesulfonyl)imide is about 1 : 1 : 0.2 .
For other BAPOs like BAPO-6, the acrylate may not be needed. For such polymers the ratio of vinyl sulfonate : (bis(styrenesulfonyl)imide can be varied from 10: 2 to 10 : 0.5, wherein 10: 1 is preferred.
The optimal amount of radical initiator can easily be determined by concentration series. However, the photoinitiator and/or thermally induced initiator usually is present in about 1 mol% of total monomers, i.e.
(meth)acrylate and vinyl sulfonate and bis(styrenesulfonyl)imide.
The final cross-linked polymer network structure facilitates weak interactions of M+ with this anionic structure, offering a high dissociation level and alkaline metal ion-mobility through the matrix (for Li 10-4 S cm-1 at 60 C). The result of the polymerization with BAPO-1 to -5 is an emulsion of polymer particles of 80-200 nm size. The result of the polymerization with .. BAPO-6 is a water-soluble ion conducting polymer.
During the reaction an alkaline metal containing surfactant (e.g. lithium dodecylsulfate) may be added that allows an effective control over the particle size and stability of the final emulsion, with a particle size distribution stable for several weeks.
A bis(acyl)phosphane oxide linked to an inorganic material such as a metal oxide (see Figure 1). The aim of using such coupled initiator in the preparation of a single-ion conduction polymer is to achieve an intimate contact between a lithium ion or sodium ion active material and a Li-ion or Na-ion conductor polymer. As a proof of concept, the polymerization of MMA
(methyl methacrylate) with BAPO linked to a vanadate in an organic solvent is described below.
A siloxane group containing BAPO such as BAPO-2, can be anchored to a material such as an electronically active material like a vanadate by co-suspending the reagents in a suitable organic solvent like THE and refluxing for an appropriate time in inert gas such as 4 h in argon.
The invention also relates to a drying process that allows processing the SPE emulsion to end with a SPE self-standing film. An electrochemical cell can be formed by positioning this SPE self-standing film between an anode and a cathode, said SPE self-standing film working as a separator.
The invention also covers the direct deposition of SPE by solution casting on the electrode.
It is also within the scope of the present invention to add a plasticizer.
Dependent on the time of addition and the amount or ratio, respectively, the features of the polymer film can be varied. In general a minimum of 5 and a maximum of 20 wt% of plasticizer such as tetraethyleneglycol dimethylether (TEG) might be used in a SPE separator.
In a further aspect this invention relates to an alkaline metal-ion battery like a lithium¨ion battery where a SPE film separates a negative electrode made of metallic lithium and a positive electrode, prepared by mixing a cathodic active material (for example LiFePO4 or LixHyV308 wherein in this formula 2<x+y<6.8 and 0<x<4 and 0.5<y<6) or a composite vanadate/graphene material as described in EP 2 755 259 (Al) "Self-assembled composite of graphene oxide and H4V308") with conductive carbon additives and the SPE described above. In this configuration the SPE
plays two roles, namely as a separator and as an electrolyte.
In such an embodiment, the SPE used for mixing with the cathode material and conductive carbon may have low mechanical strength but high conductivity and the self-standing film may have lower conductivity but improved mechanical stability.
In another embodiment, the SPE emulsion can optionally be admixed with an inorganic filler like fumed silica, titanium oxide, aluminum oxide, zirconium oxide, boron oxide, etc. Such inorganic nanosized fillers are in particular used to improve mechanical features of self-standing SPE films.
In another method, the active cathode material and conductive carbon is coated or mixed with the monomers and the initiator and then polymerization is initiated or ¨ in an alternative method ¨ the initiator is attached to the active cathode material and then combined with the monomers prior to polymerization initiation. Due to diffusion of the monomers into the porous cathodic material and conductive carbon layer, use of a thermally activated initiator instead of a photoinitiator may be advantageous.
Also in this embodiment the application of a SPE self standing film as (additional) separator may be needed.
It is also possible to use a two-step method, i.e. to first produce a cathode using usual binder or SPE if need be for obtaining a sufficiently stable cathode, and then coating this cathode with an SPE layer. Due to the intimate contact of the SPE layer with the cathode layer, the stability of the SPE layer is improved in comparison with a separately produced and then applied self-standing layer.
By changing the composition of the monomers and the fillers the features of the copolymer can be varied and to a large extent adapted to the specific needs with regard to conductivity and mechanical properties. As indicated above, it is also possible and often preferred to use combinations of SPEs, e.g. one layer of high conductivity and poorer mechanical strength with .. a self-standing film of lower conductivity.
The advantage of using a SPE layer or a self-standing film is an improved prevention of dendrite formation.
The composite films made of the SPE conducting polymer and the active cathode material are designed to assure an optimal interface between the electrode and the SPE-separator, providing an additional advantage when designing a full battery cell. Besides a good mechanical contact between the layers, the electrolyte polymer can also enhance local ion conduction inside the electrode.
The SPE of the present invention cannot only be admixed with cathode material but also with anode material. The above comments apply respectively. Nevertheless, the much preferred anodes at present are metallic lithium or sodium.
The electrochemical stability versus lithium and electrochemical feasibility has been shown using standard cathodes materials, such as lithium iron phosphate (LFP), or novel active materials, such as lithium vanadates, which is a highly attractive cathode material for the next generation of Li-ion batteries as e.g. described in EP 2 755 259 Al. The tri-block polymeric single ion conductor (denoted as TBP) can suitably be synthetized by a radical polymerization triggered by photo-initiators in water.
Therefore, besides of the specific linker and the therewith produced solid conducting polymers, other aspects of the present invention are electrodes comprising active electrode material, SPE and possibly conducting fillers like graphene, graphite, conducting carbon and combinations thereof, as well as batteries produced using an SPE of the present invention as electrolyte, preferably in combination with a metal anode. Such a battery can be produced by a method comprising the step of coating a releasable support such as an aluminum foil with active electrode material and optionally conductive fillers to form a cathode and then coating the cathode with a coating of a solid conducting polymer of the present invention.
Brief Description of the Drawings The invention will be better understood and objects other than those set forth above will become apparent when consideration is given to the following detailed description thereof. This description makes reference to the annexed drawings, wherein:
Figure 1: Synthesis of photoinitiator BAPO-Vanadate Figure 2: 31P NMR of the photoiniator linked to vanadate Figure 3: SEM image of PMMA embedding the LixHyV308 fibers resulted from a BAPO-vanadate polymerization Figure 4: XRD pattern of the films polymer TBP-1 la (prepared without LiDS) and lb (with 9mM LiDS) Figure 5: Particle size distribution of polymer TBP-1 in water Figure 6: TGA ("A") and DSC ("B") curves for TBP-1 Figure 7: Temperature dependence of conductivity (plotted logarithmically) for the tri-block polymers (TBP-1 to TBP-5 and DBP-6) prepared using the BAPO-1, BAPO-6 respectively as photo-initiators.
Figure 8: SEM images of LFP composite cathode films (L1 and L2) before and after pressing Figure 9: SEM images of vanadate composite cathode films (V1) Figure 10: Cycle-life of the composite L1 using the polymer TBP-1a at 60 C
and 70 C with a current of 20 mA/g (C/8).
Figure 11: Specific charge vs. cycle for composite L3 Figure 12: Potential vs. specific charge for composite V1 and V2 Figure 13: Specific charge vs. cycle for composite V1 and V2.
Modes for Carrying Out the Invention As indicated above, the present invention relates to cross-linkers suitable in the synthesis of single ionic conductive copolymers that are non-fluorinated and non-PEO based. Such copolymers meet the security and costs requirements to be used as solid polymers electrolytes (SPE). They are promising alternatives to standard liquid electrolytes in the Li-ion batteries or Na-ion batteries because of their improved security and inflammability properties. The copolymers described are either polyvinylsulfonates or polyacrylates, in particular methacrylates such as polymethylmetacrylates (PMMA) functionalized with alkaline metal polyvinylsulfonyl like alkaline metal , polysulfonylstyrene such as lithium polysulfonylstyrene (LiPSS) and crosslinked by the use of the inventive linker, i.e. the alkaline metal (like Li) bis(styrenesulfonyl)imide (MBSSI like LiBSSI) monomer. The copolymers of the present invention can be prepared by radical polymerization, in particular 5 radical photopolymerization, preferably photopolymerization using a functionalized bis(acyl)phosphane oxide (BAPO) as photoinitiator. Such copolymers can be used as solid polymer electrolytes in lithium-ion or sodium-ion batteries.
Experimental section
Methyl metacrylate (MMA) was purchased from Aldrich (>99%) and 15 was distilled prior to use. Tetraethyleneglycol dimethyl ether (TEG) was purified by distillation and stored over molecular sieves.
2) Synthesis of the cross linker: Bis(styrylsulfonylimide) lithium salt SO3Na i) SO2CI ii) S 02N H2 DMF 40 N,3 io soc12 0.c H20, rt, 2h 12h Li SO2CI SO2NH2 iii) ,0 THF ___________________________________________ i) 4-vinylbenzenesulfonylchloride.
A solution of 4-vinylbenzenesulfonic acid sodium salt (7.2 g, 35 mmol, 1 eq) in dimethylformamide (DMF) (58 mL) was cooled to 0 C before adding thionyl chloride (34.4 g, 21 mL, 289 mmol, 8.3 eq) dropwise. The thionylchloride was degassed but used without purification. After stirring for 12h, the mixture was left at -4 C overnight and then poured into ice-water (100 mL) and extracted with diethylether (3 x 50 mL). The solution was concentrated under reduced pressure affording a yellowish oil (4.4 g, 66 %).
1H-NMR (500.2 MHz, CDCI3) 8 = 7.92 (d, J = 8.0 Hz, 2 H, CHAr), 7.56 (d, J =
7.5 Hz, 2 H, CHAr), 6.81 (m, 1 H, CHolef), 5.92 (d, J = 17.5 Hz, 1 H, CHolef), 5.47 (d, J = 11.0 Hz, 1 H, CHolef) ppm.
13C{1H}NMR (75.5 MHz, CDCI3): 6 = 144.9 (CH2=CH-C), 142.9 (CS02C1), 135.0 (CH2=CH), 127.6 (CHAr), 127.2 (CHAr), 119.5 (CHOPPm=
ii) 4-Vinylbenzenesulfonylamide 4-vinylbenzenesulfonylchloride (2 g, 9.87 mmol, 1 equiv) was reacted for 2h with aqueous ammonia solution (100 mL, (25% NH3)) and then extracted with ether, dried over MgSO4 and concentrated giving the sulfonamide as a white solid (1.11 g, 62%).
Mp:141 C.
1H-NMR (500.2 MHz, CDCI3): 6 = 7.95 (d, J = 8.0 Hz, 2 H, CHAr), 7.58 (d, J =
8.5 Hz, 2 H, CHAr), 6.75 (m, 1 H, CHolef), 5.94 (d, J = 17.5 Hz, 1 H, CHolef), 5.50 (d, J = 11.0 Hz, 1 H, CHolef), 3.08 (s, 2 H, NH2) ppm.
iii) Bis(styrylsulfonylimide) lithium salt A mixture of 4-vinylbenzenesulfonylchloride (323 mg, 1.6 mmol, 1 eq), 4-vinylbenzenesulfonylamide (293 mg, 1.6 mmol, 1 eq) and LiH (77 mg, 3.2 mmol, 2 eq) in THF (5 mL) was stirred for 12h under Ar at room temperature, then concentrated and washed with ether giving a white solid. The solid was recrystallized from Me0H affording 0.4 g, 71 % yield.
Mp: >250 C dec.
1H-NMR (500.2 MHz, D20): 5 = 7.61 (m, 4H, CHAr), 7.46 (m, 4H, CHAr), 6.76 (m, 2H, CHolef), 5.91 (d, J= 17.5 Hz, 2H, CHolef), 5.36 (d, J = 11.0 Hz, 2H, CHolef).
13C-NMR (75.5 MHz, D20): 5 = 141.9 (CH2=CH-C), 138.9 (CSO2N), 135.4 (CH2=CH), 126.7 (CHAr), 125.8 (CHAr), 116.4 (CH2) PPrn.
7L1-MAS NMR 8 = 0 ppm ATR IR: 7c-1(cm-1) = 1626w, 1494 m, 1424 m, 1200 s, 1137 m, 1093 s, 989 s, 904 m, 839 s, 743 m.
EA Calc: C54.0%, H 4.0%; Found C53.4%, H4.1%
3) Synthesis of bis(acyl)phosphane oxide (BAPO) photoinitiators The general synthesis of the different BAPOs is described in PCT/EP2013/070378 (WO 2014/053455), WO 2011/003772 and WO 2006/056541. For BAPO-1, see example 23 of WO 2014/053455, for BAPO-2, see example 12a of WO 2014/053455, for BAPO-3, see example 27 of WO 2014/053455. BAPO-4 was prepared using BAPO-2 and the protocol described in example 34 of WO 2011/003772 and BAPO-5 was prepared according to example 23 of WO 2014/053455, using polyethyleneglycol diacrylate Mn 6000 as starting material.
BAPO-6 is soluble in water and the synthesis was performed as described for Example 1 in patent WO 2006/056541 using 3-Bromopropyltrimethylammonium bromide in ethanol for the alkylation of bisenolate Na[P(COMes)21xDME) (step d).
4) Synthesis of bis(acyl)phosphane oxide (BAPO) photoinitiator linked to vanadate and polymerization of MMA.
A bis(acyl)phosphane oxide functionalized with a siloxane group (BAPO-2) was linked to a lithium oxohydroxide vanadate LixHyV308 (wherein 2<x+y <6.8 and 0<x<4 and 0.5<y<6) (described within US20130157138 Al) (Figure 1).
The linking of the BAPO to the vanadate was carried out under argon atmosphere in a 100 mL Schlenk flask connected to a reflux condenser. To a suspension of LixHyV308 (1g) in THF (30 mL) was added BAPO-2 (0.05 g, 0.087 mmol) and the mixture refluxed during 4h. After cooling down the mixture, the solid was filtered, washed, and sonicated two times for 1 min in THE (20 mL). The resulting greenish solid was dried under vacuum at 50 C
for 24h affording 0.95g. Analysis of the material was performed spectroscopically (MAS NMR) to confirm the presence of bis(acyl)phosphane)oxide photoactive group in the material (31P NMR) (Figure 2).
5) Synthesis of PMMA by radical polymerization using a vanadate linked photoinitiator The photoinitiated polymerization of MMA was carried out in a 100 mL
Schlenk under argon atmosphere. A suspension of the linked photoinitiator (0.95 g) in THF (30 mL) was prepared and the MMA (0.78 g, 7.8 mmol) added to the suspension. The mixture was stirred vigorously for 5 min before irradiation. The irradiation of the mixture was performed with a mercury UV
lamp under vigorous stirring at room temperature during 1h affording a gel.
The greenish solid was suspended in 50 mL of THF sonicated and filtered.
The sample was dried under vacuum affording 0.87 g of a greenish solid. The morphology of this solid was investigated by SEM analysis (Figure 3).
6) Synthesis of the copolymers (C P-1 to CP-6) 6a)Synthesis of tri-block copolymers (TBP-1 to TBP-5) Reaction path for the synthesis of TBP-1:
01,40 M es Mes 40 so2 '14- Li+
sou 02g SO3Li 40 so Lt SO2 __________________________________ lh,OV
The synthesis of the polymer TBP-1 (1 b) was carried out in a 100 mL
Schlenk flask under argon atmosphere. The reactor was charged with lithium sulfonate styrene (4 mmol, 760 mg), lithium bis(styrenesulfonyl)imide (0.8 mmol, 284 mg) and distilled water (30 mL). Freshly distilled methyl methacrylate (MMA) (4 mmol, 400 mg, 430 pL) and photoinitiator BAP0-1 (R
= CH2CH2CO(OCH2CH2)20Et) (0.08 mmol, 42 mg) dissolved in DME
(dimethoxyethane) (5 mL) were slowly added under argon atmosphere to the stirred mixture. To the reaction mixture lithium dodecylsulfate (9 mM) was added. The emulsion was deoxygenated for 20 min prior to being irradiated at 22 C with a middle pressure mercury UV lamp (254 nm) for 1 h while maintaining a vigorous stirring (1200 rpm) resulting in a white suspension.
The polymer was isolated by removing solvent under vacuum (40C , mbar). The resulting white viscous residual was washed with isopropanol (2 x 5 mL) and tetrahydrofuran (2 x 5 mL). The recovered polymer was dried under vacuum overnight (25C , 0.1 mbar) affording 945 mg (71% yield).
Stable suspensions of the polymer were prepared by adding distilled water and 5% (w/w) tetraethyleneglycol dimethylether (TEG). TEG was added as plasticizer to avoid dense packing of the polymer.
Synthesis of TBP-2 to TBP-5 was performed analogously.
6b) Synthesis of Polymer DBP-6 For polymer TBP-6 a preferential ratio of lithium styrylsulfonate to cross linker is a 10:1 ratio with no acrylate or methacrylate employed. Except for this change and the fact that the BAPO-6 was added to the aqueous 10 solution containing monomers, the procedure for TBP-1 was followed.
7) Preparation of self-standing films of SPE from the suspension of the TBP
Self standing films of the polymer electrolyte were prepared by casting the TBP suspension within Teflon plates with 300 - 500 pm circular groves.
15 These circular groves had the size of the electrolyte films required for conductivity and battery tests (0 15 and 17 mm). The polymers were initially dried at room temperature under Ar for 24h; then at 50 C under Ar during 4 days, and finally under vacuum at 50 C for 24h. The processing resulted in homogeneous self-standing films of 200-700 pm which were stored in a glove 20 box for 2 days prior to use.
8) Characterization of tri-block copolymers (TBP) (after processing as self-standing films) 8a) Methods used NMR
The MAS NMR experiments were performed using a Bruker Avance 400 MHz 9.4T spectrometer. The 7Li MAS NMR spectra were recorded at 155.50 MHz using 1.0 s radiofrequency pulses, a recycle delay of 2.0 s, a number of transient of 600, and a spinning rate of 7.0 kHz.
=
XRD
Powder X-ray diffraction patterns were obtained on a STOE Stadi P
diffractometer equipped with a germanium monochromator and Cul<01 radiation (operated at 40 kV, 35 mA).
SEM
Scanning electron microscopy (SEM) was performed on a Zeiss Gemini 1530 operated at 1kV.
TEM
Transmission electron microscopy (TEM) was performed on a CM3OST (FEI; LaB6 cathode) and a TecnaiF30 microscope that were operated at 300 kV with a maximum point resolution of ca. 2A.
Ionic conductivity Impedance measurements were carried out in the frequency range of 500 kHz to 1 Hz using an excitation amplitude of 50 mV (VMP3, Biologic SAS, France). Discs of 17 mm diameter were cut from the electrolyte film and the samples were placed between two round stainless steel discs (1.8 cm2) and sealed for air and moisture protection with a temperature stable tape.
From the obtained line the bulk resistance (R) was calculated selecting the minimum in the Nyquist plot between the electrolyte arc and the beginning of the interfacial arc. The bulk resistance R of the polymer is then used to calculate the conductivity (a) according to Eq. 1, where d is the sample thickness and A the sample area measured between the steel discs. This methodology has been broadly described to measure the ionic conductivity of SPE at different temperatures.[11]
a ¨ _____________________________________________ A * R
Eq. 1 8b.Characterization of tri-block copolymer TBP-1 7Li MAS NMR 8 = -0.5 ppm ATR IR: v (cm-1) = 2350w, 1724s, 1456 m, 1248 s, 1149s, 1085 s, 1030 s, 985 m, 948 m, 892 m, 758 m, 638 s EA C 52.8%, H 4.0%, N 0.7%
Using XRD-diffraction no clear crystallinity was found for TBP1, independently on the addition of surfactant (LIDS). Only a very broad signal in the 20 range of 10 - 25 was detected, suggesting that the polymer contains regions having ordered chains, but from the signal width, it can be .. stated that these ordered domains are very small or not well defined (Figure 4).
On the other hand, the addition of LiDS had an influence on the polymer particle size and distribution. The polymer prepared without LiDS
exhibited inferior stability and suffered from particle sedimentation after few hours. Zeta size measurements of polymer suspensions containing LiDS (9 mM) showed a narrow distribution of the particles size around 41 nm (Figure 5). The size distribution remained unchanged after 2 weeks aging, and was used for the preparation of composite films.
The thermal stability of the polymers was evaluated by thermal gravimetric analysis (TGA). TBP1 was thermally stable up to 190 C, with negligible mass loss (1%). There was an increasing mass loss of 7.6% at 290 C. The melting behavior of the polymers was quantified using differential scanning calorimetry (DSC) and representative curves for the polymer la are represented in Figure 6 showing an endothermic peak at 290 C.
Figure 7 shows the conductivity vs inverse of temperature (T-1) for TBP-1 and the analogous polymers (TBP2, TBP3, TBP4, TBP5 and DBP6) prepared using the different BAPO photoinitiators described above. A linear increase in conductivity indicates that the conductivity mechanism remained the same throughout the temperature range measured. The maximum conductivity of 0.14 mS/cm at 60 C was reached for the polymer obtained using a polymeric siloxane containing BAPO (BAPO-4). This sample however exhibited a deviation from the linear increase on the plot of logarithmic conductivity vs T-1. This indicates a change of the conduction mechanism at .. higher temperature or the influence of a second conduction process.
Chemical stability of the polymer films against lithium was tested by placing the film on freshly cut lithium in dry argon atmosphere. The interface polymer/Li remained unchanged after the polymer film was lifted in regular time intervals (up to 3 weeks).
9) Composite cathode preparation with TBP-1 9a)One step SPE/AM composites preparation In a first step the cathode active materials (AM), either carbon coated lithium iron phosphate (LFP) (2 pm, A1100, Alees, Taiwan) or lithium oxohydroxide vanadate LixHyV308 (wherein 2<x+y <6.8 and 0<x<4 and 0.5<y<6) (described in US20130157138 Al) were premixed with carbon black conductive additive (Super-PTM, Timcal) and alternatively also with graphite (SFG6 or KS6, Timcal, Switzerland) in an agate ball mill (300 rpm, 2 x 10 minutes). Then an aqueous suspension of the polymer TBP-1 with a concentration of 0.16 g/ml was added. Depending on the solid content, some additional de-ionized water was added until suitable viscosity of the slurry had been achieved. Optimal solid content around 18% and 35% for preparation of LFP and vanadates composites (L1 -L2 and V1-V2) respectively were used.
To prevent strong foaming during ball milling and resulting holes in the cathode films, a minimum amount of tributyl phosphate (> 99.0 %, Fluka Chemie AG, Buchs, Switzerland) was added as anti-foaming agent. After ball milling for 2 x 30 minutes (300 rpm, with reversed rotation direction) an homogenous slurry was obtained. The weight percent of different composite compositions are shown in Table 1.
LFP LFP Lixl-lyV308 Lixl-lyV308 composite composite V1 (%) V2(%) L1 (%) L2(%) AM= 74 55 46 43 (LFP or Lixl-lvV308) Graphite 10 10 15 0 (SFG6) Super P 5 5 11 29 Polymer TBP-1 11 30 27 27 Table 1. LFP or Lixl-lyV308 composites with different ratios.
The slurries were casted by doctor-blading on standard aluminum foil (15 pm). The films were dried for one hour at room temperature and an airflow, then for 12 h at 50 C under an Argon atmosphere, and finally for at least 24 h at 50 C under vacuum, resulting in 40-100 pm thick dry films. The films were pressed (15 tons, 5 min) to reduce voids in the film and improve contact between particles. The microstructures of the LFP based films are shown in Figure 9 and the corresponding microstructure of the vanadate based films in Figure 10.
9b) Two steps SPE/AM composites preparation by coating and infiltration As an alternative way to prepare SPE/AM composites, a LFP-based cathode was first bar coated on an aluminum foil and then a SPE-solution was drop casted on the cathode.
The coated cathode had a composition of 88% (LFP), 6% (KS6) and 4% (SuperP)). In order to assure adhesion to the aluminum foil 2% of sodium methyl cellulose (Na-CMC) was used as binder. Then a suspension of TBP1 in water (30 %wt) was drop casted on the LFP-cathode. The composites cathodes were initially dried at room temperature under Ar for 24h then at 50 C under Ar during 24h, and finally under vacuum (10 mbar) at 50 C for 24h. The resulting cathode composites (composite L3) were 100 pm thick and contain a load of 17.6 mg polymer/cm2 cathode film.
10) Battery setup Electrochemical performance was tested in standard coin cells 5 (CR2025, Renata, Switzerland). Lithium metal disk was used as anode. Disks of 13 mm diameter were subsequently cut from the composite cathode films.
For the composites prepared by one step route (L1-L2 & V1-V2), a SPE disk (diameter 17 mm) from the self-standing SPE film TBP1 was placed between the anode and the cathode. The test cells were assembled in dry Ar 10 atmosphere (<0.1 ppm H20; <0.1 ppm 02). For galvanostatic experiments, a current of 20-25 mA/g was used (based on the active material). The LFP
window potential was 3.0-3.9 V and for vanadium 1.6-4.2 V.
10a) Electrochemical performance of LFP-composites (one step synthesis) 15 The cathode L1 (Figure 10) showed capacities close to the theoretical value (152 Ah/kg in the first cycle at 60 C), and was stable for the five cycles measured at this temperature when cycled with a current of 20 mA/g (C/8).
After these five cycles, the cell was transferred to another measurement device for long term measurement and the temperature was increased to 20 70 C. At this temperature, the capacity first increases to 167 Ah/kg. After 20 cycles 144 Ah/kg were measured.
10b) Electrochemical performance of LFP-composites (two step synthesis) In Figure 11 the composite L3 (where the SPE was drop-casted, see 25 8b) had been galvanostatically cycled at 70 C in the 3.0-3.9 V range with a current of 20 mA/g. In the first 6 cycles a slight overcapacity was observed and from the 7th cycle recharge efficiencies close to 100%. At C/8 rate, the performance of the cell still achieved capacities higher than 160 mA/g after the 20th cycle.
=
10c) Electrochemical performance of vanadate-composites (one step synthesis) Figure 12 displays the potential vs Li/Li (V) versus specific charge (Ah/Kg) for the first cycles of batteries using cathode V1 and V2. at 70 C. In Figure 13, the capacity in dependence on the cycle number is shown for both composites up to the 23th cycle. The cathode composite V1 exhibited capacities in the first cycle of 398 Ah/kg close to the theoretical value, which decreased to 148 Ah/Kg after the 23th cycle. The cathode composite V2 achieved capacities up to 419 Ah/kg in the first cycle, which slowly decreased to 150 Ah/Kg after the 23th cycle. Remarkably, the columbic efficiency of composite V2 (Super P and graphite) was improved when compared to V2 (only SuperP as carbon additive).
While there are shown and described presently preferred embodiments of the invention, it is to be distinctly understood that the invention is not limited thereto but may be otherwise variously embodied and practiced within the scope of the following claims.
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Claims (34)
as cross linking monomer in the production of a solid conducting polymer by copolymerizing said bis(styrylsulfonylimide) salt with an alkaline metal vinyl sulfonate monomer and a radical initiator, said radical initiator being a photoinitiator or a thermal initiator or a combination of photoinitiators and a thermal initiator, and optionally an acrylate monomer.
as cross linking monomer in the production of a solid polymer electrolyte, by copolymerizing said bis(styrylsulfonylimide) salt with an alkaline metal vinyl sulfonate monomer and a radical initiator, said radical initiator being a photoinitiator or a thermal initiator or a combination of photoinitiators and a thermal initiator, and optionally an acrylate monomer.
the aliphatic chain being once, twice or more times interrupted or interconnected by said functional groups, or be substituted once or more times with such functional groups, and wherein said functional groups are separated by at least one CH2-group R2 is an aryl group, 2,4,6-trimethylphenyl (mesityl) or dimethoxyphenyl, and R3 is ¨C(R4)3 as described above for R1.
1.
alkaline metal vinyl sulfonate: cross-linking monomer is about 10 : 1.
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| EP14197209.1 | 2014-12-10 | ||
| EP14197209.1A EP3031798B1 (en) | 2014-12-10 | 2014-12-10 | A novel cross-linker for the preparation of a new family of single ion conduction polymers for electrochemical devices and such polymers |
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| EP (1) | EP3031798B1 (en) |
| JP (1) | JP6110928B2 (en) |
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| DE102022204975A1 (en) | 2022-05-18 | 2023-11-23 | Technische Universität Braunschweig - Körperschaft des öffentlichen Rechts | Solid electrolyte for lithium-based rechargeable batteries |
| JP7842716B2 (en) * | 2022-07-21 | 2026-04-08 | 信越化学工業株式会社 | Bioelectrode composition, bioelectrode, and method for manufacturing the same |
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| CN120518807B (en) * | 2025-07-22 | 2025-10-28 | 浙江奕湃科技有限公司 | Polystyrene-sodium divinylbenzene sulfonate foam material and preparation method and application thereof |
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| FR2742437B1 (en) * | 1995-12-14 | 1998-01-09 | Electricite De France | BIS (PHENYLSULFONYL) IMIDIDES, THEIR PREPARATION METHOD AND ION CONDUCTIVE MATERIALS COMPRISING THE SAME |
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| DE69908499T2 (en) * | 1998-01-30 | 2004-05-13 | Hydro-Québec, Montréal | POLYMERIZABLE BIS-SULFONYL DERIVATIVES AND THEIR USE IN THE MANUFACTURE OF ION EXCHANGE MEMBRANES |
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| EP2755259A1 (en) | 2013-01-10 | 2014-07-16 | Belenos Clean Power Holding AG | Self-assembled composite of graphene oxide and H4V3O8 |
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| EP3031798A1 (en) | 2016-06-15 |
| EP3031798B1 (en) | 2017-09-27 |
| KR20160070701A (en) | 2016-06-20 |
| TW201638094A (en) | 2016-11-01 |
| KR102287715B1 (en) | 2021-08-09 |
| JP6110928B2 (en) | 2017-04-05 |
| US20160168086A1 (en) | 2016-06-16 |
| JP2016128562A (en) | 2016-07-14 |
| CN105693566A (en) | 2016-06-22 |
| CA2914715A1 (en) | 2016-06-10 |
| US9771319B2 (en) | 2017-09-26 |
| KR20170140138A (en) | 2017-12-20 |
| CN105693566B (en) | 2018-04-03 |
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