Aluminum-substituted tungstophosphoric acid (AlTPA)/sulfonated poly ether ether ketone (SPEEK) (sulfonation degree approximately 77%) nanocomposite membranes have been prepared for fuel cell application. AlTPA nanoparticles are synthesized by the reaction of TPA and aluminum nitrate in aqueous medium. X-ray diffraction, energy dispersive X-ray, Fourier transform infrared and Raman spectroscopies, and field-emission scanning electron microscopy (FESEM) are used to characterize the AlTPA particles and SPEEK. Study reveals that 2.31 numbers of protons of TPA have been replaced by Al3+ in AlTPA with retention of Keggin’s structure. Nanocomposite membranes with varying AlTPA and TPA content are prepared and evaluated by measuring water uptake, ion exchange capacity, equilibrium water content, water desorption rate, proton conductivity, leaching tendency, and thermal properties. SPEEK/AlTPA nanocomposite membrane exhibits proton conductivity as high as 1.09 mS cm−1 at 10 wt% filler loading. Leaching of filler is reduced by approximately 92% in SPEEK/AlTPA nanocomposite membrane compared to SPEEK/TPA membrane. SPEEK/AlTPA membrane shows approximately 15% higher equilibrium water content and approximately 57% reduction in water desorption rate as compared to SPEEK/TPA membrane. Membranes are thermally stable up to 215°C, which is well above the operating temperature of fuel cells. Composite films are also examined by FESEM to gain further insights into the microstructure.
PrasadMMohantySNayakSK. Study of polymeric nanocomposite membrane made from sulfonated polysulfone and nanoclay for fuel cell applications. High Perform Polym2014; 26(5): 578–586.
2.
BanerjeeSKarKKDasMK. Electrolyte membranes for fuel cells: synthesis, characterization and degradation analysis. Recent Pat Mater Sci2014; 7: 173–203.
3.
BanerjeeSKarKKGhoraiMK. Synthesis of poly ether ether ketone membrane with pendent phosphonic acid group and determination of proton conductivity and thermal stability. High Perform Polym2014; 27: 402–411.
UnnikrishnanLMohantySNayakSK. Proton exchange membranes from sulfonated poly(ether ether ketone) reinforced with silica nanoparticles. High Perform Polym2013; 25(7): 854–867.
6.
LiYWangXXieM. High proton conductivity and low fuel crossover polymer electrolyte membranes derived from branched sulfonated poly(ether ether ketone)s and silica sulfonic acid nanoparticles. High Perform Polym2014; 26(7): 770–778.
7.
ColicchioIWenFKeulH. Sulfonated poly(ether ether ketone)–silica membranes doped with phosphotungstic acid. Morphology and proton conductivity. J Membr Sci2009; 326: 45–57.
8.
BanerjeeSKarKK. Synergistic effect of aluminium phosphate and tungstophosphoric acid on the physicochemical properties of sulfonated poly ether ether ketone nanocomposite membrane. J Appl Polym Sci 2015. Epub ahead of print 06 October 2015. DOI: 10.1002/app.42952.
VonaMLDSgrecciaEDonnadioA. Composite polymer electrolytes of sulfonated poly-ether-ether-ketone (SPEEK) with organically functionalized TiO2. J Membr Sci2011; 369: 536–544.
11.
MohtarSSIsmailAFMatsuuraT. Preparation and characterization of SPEEK/MMT-STA composite membrane for DMFC application. J Membr Sci2011; 371: 10–19.
12.
BanerjeeSKarKK. Particulate filled polymer electrolyte membrane for fuel cell applications. Recent Pat Mater Sci2014; 7: 131–150.
13.
ZengJShenPKLuS. Correlation between proton conductivity, thermal stability and structural symmetries in novel HPW-meso-silica nanocomposite membranes and their performance in direct methanol fuel cells. J Membr Sci2012; 397–398: 92–101.
14.
PandeyJMirFQShuklaA. Performance of PVDF supported silica immobilized phosphotungstic acid membrane (Si-PWA/PVDF) in direct methanol fuel cell. Int J Hydrogen Energ2014; 39: 17306–17313.
15.
ShengXZhouYZhangY. Immobilization of 12-tungstophosphoric acid in alumina-grafted mesoporous LaSBA-15 and its catalytic activity for alkylation of o-xylene with styrene. Micropor Mesopor Mater2012; 161: 25–32.
16.
DoganHInanTYUnverenE. Effect of cesium salt of tungstophosphoric acid (Cs-TPA) on the properties of sulfonated polyether ether ketone (SPEEK) composite membranes for fuel cell applications. Int J Hydrogen Energ2010; 35: 7784–7795.
17.
XiangYYangMZhangJ. Phosphotungstic acid (HPW) molecules anchored in the bulk of Nafion as methanol-blocking membrane for direct methanol fuel cells. J Membr Sci2011; 368: 241–245.
18.
NaKOkuharaTMisonoM. Skeletal isomerization of n-butane catalyzed by an acidic cesium salt of 12-tungstophosphoric acid. Chem Lett1993; 22: 1141–1144.
19.
Ramesh KumarCRambabuNLingaiahN. Hafnium salts of dodeca-tungstophosphoric acid catalysts for liquid phase benzylation of anisole with dibenzylether. Appl Catal A Gen2014; 471: 1–11.
20.
OkuharaTNishimuraTWatanabeH. Novel catalysis of cesium salt of heteropoly acid and its characterization by solid-state NMR. In: HatoriHMisonoMOnoY (eds) Acid-base Catalysis II. Japan: Elsevier, 1994, pp. 419–428.
21.
OkuharaTNishimuraTWatanabeH. Novel catalysis of cesium salt of heteropoly acid and its characterization by solid-state NMR. Stud Surf Sci Catal1994; 90: 419–428.
22.
IbrahimSM. Catalytic activity and selectivity of unsupported dodecatungstophosphoric acid, and its cesium and potassium salts supported on silica. Modern Res Catal2013; 2: 110–118.
AmirinejadMMadaeniSSRafieeE. Cesium hydrogen salt of heteropolyacids/Nafion nanocomposite membranes for proton exchange membrane fuel cells. J Membr Sci2011; 377: 89–98.
25.
KreuerKD. Proton conductivity: materials and applications. Chem Mater1996; 8: 610–641.
26.
PourcellyGGavachC. Perfluorinated membranes. In: ColombanP (ed.) Proton Conductors: Solids, Membranes and Gels-materials and Devices. New York: Cambridge University Press, 1992, pp. 294–310.
27.
KoubekE. Acid-base chemistry of the aluminum ion in aqueous solution. J Chem Educ1998; 75: 60.
28.
Ramesh KumarCSai PrasadPSLingaiahN. Aluminium exchanged heteropoly tungstate supported on titania catalysts: the generation of Lewis acidity and its role for benzylation reaction. J Mol Catal A2011; 350: 83–90.
29.
YeeRSLZhangKLadewigBP. The effects of sulfonated poly(ether ether ketone) ion exchange preparation conditions on membrane properties. Membranes2013; 3: 182–195.
30.
HouHMaranesiBChailanJ-F. Crosslinked SPEEK membranes: mechanical, thermal, and hydrothermal properties. J Mater Res2012; 27: 1950–1957.
31.
WinstonPWBatesDH. Saturated solutions for the control of humidity in biological research. Ecology1960; 41: 232–237.
32.
LiLZhangJWangY. Sulfonated poly(ether ether ketone) membranes for direct methanol fuel cell. J Membr Sci2003; 226: 159–167.
33.
TripathiBPKumarMShahiVK. Organic-inorganic hybrid alkaline membranes by epoxide ring opening for direct methanol fuel cell applications. J Membr Sci2010; 360: 90–101.
34.
KimYSWangFHicknerM. Fabrication and characterization of heteropolyacid (H3PW12O40)/directly polymerized sulfonated poly(arylene ether sulfone) copolymer composite membranes for higher temperature fuel cell applications. J Membr Sci2003; 212: 263–282.
35.
KloproggeJTFrostRL. Raman microscopy study of basic aluminium nitrate. Spectrochim Acta A1999; 55: 163–169.
36.
Muthu LakshmiRTSChoudharyVVarmaIK. Sulphonated poly(ether ether ketone): synthesis and characterization. J Mater Sci2005; 40: 629–636.
37.
GargMQuamaraJK. FTIR analysis of high energy heavy ion irradiated kapton-H polyimide. Indian J Pure Appl Phys2007; 45: 563–568.
38.
El-KabbanyFTahaSHafezM. IR spectroscopic analysis of the new organic silver complex C13H13N4OAg. Spectrochim Acta A Mol Biomol Spectrosc2013; 111: 252–259.
39.
RahnavardARowshanzamirSParnianMJ. The effect of sulfonated poly (ether ether ketone) as the electrode ionomer for self-humidifying nanocomposite proton exchange membrane fuel cells. Energy2015; 82: 746–757.
40.
JangI-YKweonO-HKimK-E. Application of polysulfone (PSf)– and polyether ether ketone (PEEK)–tungstophosphoric acid (TPA) composite membranes for water electrolysis. J Membr Sci2008; 322: 154–161.
KnauthPDiVonaML. Hydration and proton conductivity of ionomers: the model case of sulfonated aromatic polymers. Front Energ Res2014; 2: 1–6.
43.
MauritzKAMooreRB. State of understanding of Nafion. Chem Rev2004; 104: 4535–4585.
44.
HogarthWHJDiniz da CostaJCLuGQ (Max). Solid acid membranes for high temperature (>140 °C) proton exchange membrane fuel cells. J Power Sources2005; 142: 223–237.
WieczorekWRaduchaDZalewskaA. Effect of salt concentration on the conductivity of PEO-based composite polymeric electrolytes. J Phys Chem B1998; 102: 8725–8731.
47.
MaierJ. Ionic conduction in space charge regions. Prog Solid State Chem1995; 23: 171–263.
48.
NanC-W. Conduction theory of ionic conductor containing dispersed second phase. Acta Phys Sin1987; 36: 191–198.
49.
FournierMFeumi-JantouCRabiaC. Polyoxometalates catalyst materials: x-ray thermal stability study of phosphorus-containing heteropolyacids H3+xPM12 –xVxO40·13–14H2O (M = Mo,W; x= 0–1). J Mater Chem1992; 2: 971–978.
50.
ArmatasGSKatsoulidisAPPetrakisDE. Synthesis and acidic catalytic properties of ordered mesoporous alumina–tungstophosphoric acid composites. J Mater Chem2010; 20: 8631–8638.
51.
MordinaBTiwariRK. A comparative study of mechanical and tribological properties of poly(ether ether ketone) composites filled by micro- and nano-Ni and ZrO2 fillers. J Compos Mater2012; 47(22): 2835–2845.
52.
DecSFHerringAM. Structure and dynamics of disodium hydrogen 12-tungstophosphoric acid. J Phys Chem B2004; 108: 12339–12351.
53.
BelangerRMoffatJB. Interaction of NO and NO2 on 12-tungstophosphoric acid. Catal Lett1995; 32: 371–378.
