Electrochemical Characterization of Ethylenetetrafluoroethylene-g-polystyrenesulfonic Acid Solid Polymer Electrolytes

Abstract: Proton-exchange-membrane fuel cells (PEMFCs) have received considerable interest as a reliable power source due to their ability to attain high power densities with high energy efficiency. 1 A vital component of the PEMFC is the proton exchange membrane (PEM), which provides the ionic path between the anode and the cathode while separating the two reactant gases. The PEM material most frequently used for this type of application is Nafion ® due to its chemical and mechanical stability and its commercial availa… Show more

“…New bands were observed; these were present in the Raman spectrum of poly(vinylbenzyl chloride). The most significant of these were strong bands at 1613, 1268, 1003 cm -1 , the latter of which was the most intense and was also present as the 12 band in the spectrum of poly(styrene). 22 There was evidence of a small amount of residual VBC monomer in the material (a band at 1632 cm -1 in the Raman spectrum of F1 -see thermogravimetry of F1 later); this feature corresponds to the strong C=C band located in the Raman spectrum of VBC, which does not occur in the spectrum of poly(vinylbenzyl chloride).…”

“…21 The new bands observed were all present in the Raman spectrum of poly(vinylbenzyl chloride). The most significant of these were strong bands at 1613, 1269, 1003 cm -1 , the latter of which was the most intense and was also present as the 12 band in the Raman spectrum of poly(styrene). 22 Bands at 1633 and 1408 cm -1 in the spectrum of VBC associated with the C=C str.…”

“…In fuel cell membrane research, the effort has concentrated on PEMs with lower methanol permeabilities 8 and lower cost than Nafion ® (> US$ 780 m -2 ) 9 (note, it has been recently reported that new solution cast Nafion ® membranes (NR-111) would allow the cost to drop to US$ 50 m -2 with volume production of 2 million m 2 per annum). 10 A proportion of this effort has examined the radiation-grafting (using -rays and e-beams) of styrene onto non-fluorinated films 11 such as poly(ethylene), partially fluorinated films 11,12 such as poly(ethylene-cotetrafluoroethylene) ( 14 There is, however, some concern about the lack of stability of these membranes in a fuel cell environment, 15 with peroxyradical attack of the -hydrogen of the styrenic backbone being principally responsible (especially at the anode); ESR studies, 15 however, suggest that the OH · radicals are only damaging at pH as a shift reference) spectra were recorded using cross polarisation (with a flip-back pulse after acquisition) and spinning rates of 3 -5 kHz. Measurements were carried out at ambient temperature and pressures.…”

Alkaline anion-exchange radiation-grafted membranes for possible electrochemical application in fuel cells

“…New bands were observed; these were present in the Raman spectrum of poly(vinylbenzyl chloride). The most significant of these were strong bands at 1613, 1268, 1003 cm -1 , the latter of which was the most intense and was also present as the 12 band in the spectrum of poly(styrene). 22 There was evidence of a small amount of residual VBC monomer in the material (a band at 1632 cm -1 in the Raman spectrum of F1 -see thermogravimetry of F1 later); this feature corresponds to the strong C=C band located in the Raman spectrum of VBC, which does not occur in the spectrum of poly(vinylbenzyl chloride).…”

“…21 The new bands observed were all present in the Raman spectrum of poly(vinylbenzyl chloride). The most significant of these were strong bands at 1613, 1269, 1003 cm -1 , the latter of which was the most intense and was also present as the 12 band in the Raman spectrum of poly(styrene). 22 Bands at 1633 and 1408 cm -1 in the spectrum of VBC associated with the C=C str.…”

“…In fuel cell membrane research, the effort has concentrated on PEMs with lower methanol permeabilities 8 and lower cost than Nafion ® (> US$ 780 m -2 ) 9 (note, it has been recently reported that new solution cast Nafion ® membranes (NR-111) would allow the cost to drop to US$ 50 m -2 with volume production of 2 million m 2 per annum). 10 A proportion of this effort has examined the radiation-grafting (using -rays and e-beams) of styrene onto non-fluorinated films 11 such as poly(ethylene), partially fluorinated films 11,12 such as poly(ethylene-cotetrafluoroethylene) ( 14 There is, however, some concern about the lack of stability of these membranes in a fuel cell environment, 15 with peroxyradical attack of the -hydrogen of the styrenic backbone being principally responsible (especially at the anode); ESR studies, 15 however, suggest that the OH · radicals are only damaging at pH as a shift reference) spectra were recorded using cross polarisation (with a flip-back pulse after acquisition) and spinning rates of 3 -5 kHz. Measurements were carried out at ambient temperature and pressures.…”

Alkaline anion-exchange radiation-grafted membranes for possible electrochemical application in fuel cells

“…For this reason, DAIS membranes are being promoted for the low temperature (<60 °C) portable fuel cell power market. In the grafting strategy, thermally and chemically stable fluorinated polymers (fluorinated ethylene propylene (FEP) [95,96]) or partially fluorinated polymers [ethylene tetrafluoroethylene (ETFE) [97,98] or polyvinylidene fluoride (PVDF) [99]] were chosen as the base polymers and shown to produce materials with some improved performance. It has been reported that the most stable polystyrene analogue is a vinyl perfluorosulfonic system developed by Ballard Power [100].…”

Water Soluble Polymers as Proton Exchange Membranes for Fuel Cells

“…A significant proportion of previous fuel cell membrane research has examined the radiation-grafting of styrene onto polyethylene films, partially fluorinated films such as poly(vinylidene fluoride) (PVDF) and poly(ethylene-co-tetrafluoroethylene) (ETFE), and fully fluorinated poly(tetrafluoroethene-co-hexafluoropropylene) (FEP) films with subsequent sulfonation to yield cation-exchange sites [8][9][10][11][12][13][14][15], the properties and compositions of the final materials being easily controlled [8,12]. Such protonexchange membranes have been tested in DMFC mode by Scott et al [16].…”

The radiation-grafting of vinylbenzyl chloride onto poly(hexafluoropropylene-co-tetrafluoroethylene) films with subsequent conversion to alkaline anion-exchange membranes: optimisation of the experimental conditions and characterisation