Enhanced Proton Transfer in Proton‐Exchange Membranes with Interconnected and Zwitterion‐Functionalized Covalent Porous Material Structures

Rao, Zhuang; Zhu, Deyu; Xu, You; Lan, Minqiu; Jiang, Li; Wang, Zhengyun; Tang, Beibei; Liu, Hongfang

doi:10.1002/cssc.202202279

Cited by 8 publications

(14 citation statements)

References 48 publications

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“…For BAGO/RN-1.8, its SRs reduce to 20.1 from 29.4% of RN under 40 °C and to 28.8 from 36.6% of RN under 80 °C. The reduced SRs can be attributed to that electrostatic interaction between Nafion and BAGO combined with the steric effect of BAGO restricting the chain movement of Nafion . IEC values are shown in Figure S7.…”

Section: Resultsmentioning

confidence: 99%

“…Proton conductivities (40–90 °C, 95% RH) of (a) RN, BAGO/RN-0.6, BAGO/RN-1.2, and BAGO/RN-1.8 and (b) RN, GO/RN-1.2, and BAGO/RN-1.2.…”

Section: Resultsmentioning

confidence: 99%

“…(a) Anhydrous proton conductivities (120 °C) of RN, GO/RN-1.2, and BAGO/RN-1.2 and (b) proton conductivities (95% RH, 90 °C) of RN and BAGO/RN-1.2 during 1550 min of test.…”

Section: Resultsmentioning

confidence: 99%

“…The reduced SRs can be attributed to that electrostatic interaction between Nafion and BAGO combined with the steric effect of BAGO restricting the chain movement of Nafion. 19 IEC values are shown in Figure S7. BAGO/RN membranes exhibit slightly lower IEC values than those of RN.…”

Section: Pem Characterizationmentioning

confidence: 99%

“…Its nanoscopic and microscopic ductility can induce long-range ionic channels . In addition, its barrier effect, modulated nanophase separation and decreased the void volume of the membrane by the interaction between GO and host polymers can increase the resistance of methanol crossover. ,, Therefore, it possesses grand promise for boosting proton conduction and restraining methanol permeation of PEMs. For example, sulfonated organosilane functionalized GO (SSi-GO)/SPEEK, sulfonated imidized GO (SIGO)/sulfonated poly(imide) (SPI), sulfonated GO (SGO)/sulfonated CS (SCS)/CS, GO/sulfonated polyvinylidene fluoride (SPVDF), PA functionalized GO (PGO)/Nafion, polyaniline decorated GO (PANI-GO)/SPEEK, and phosphorous acid and sulfanilic acid modified GO (PS-MGO)/sulfonated polyethylene grafted polystyrene (PE-PS) composite PEMs were successfully fabricated.…”

Section: Introductionmentioning

confidence: 99%

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Construction of Surface Sulfonic and Amino Acid–Base Pair Modified Graphene Oxide for Effectively Promoting the Selectivity of the Proton Exchange Membrane

Rao,

Zhang,

Liu

et al. 2023

ACS Appl. Polym. Mater.

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Surface −SO3H and −NH2 acid–base pair modified graphene oxide (BAGO) was constructed by first polydopamine (PDA) coating onto GO and subsequent reaction with 2,2′-benzidinedisulfonic acid (BA). The composite proton exchange membrane (PEM) with prominently elevated selectivity (selectivity: the ratio of proton conductivity to methanol permeability) was prepared by incorporation of BAGO into the Nafion matrix. The functional groups (−SO3H and −NH2) onto BAGO could form consecutive acid–base pairs for proton transfer benefitting from the tethering function of GO and the interconnection of the functional groups. In addition, continuous acid–base pair proton conducting pathways could be constructed between −NH2 of BAGO and −SO3H of Nafion. These enormously expedited the proton transportation of the composite PEM, enabling its proton conductivity to reach 0.262 S cm–1 under 95% RH, 90 °C, twice that of the recast Nafion (RN). Furthermore, significantly attenuated methanol permeability was achieved by the composite PEM due to the methanol barrier effect of BAGO and reduced free volume of the composite PEM. Meanwhile, the maximum power density of the composite PEM in a direct methanol fuel cell reached 32.5 mW cm–2, approximately 62% larger than that of RN (20.1 mW cm–2). This work offers a valuable guidance for constructing the composite PEM with effectively improved selectivity.

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Section: Resultsmentioning

confidence: 99%

“…Proton conductivities (40–90 °C, 95% RH) of (a) RN, BAGO/RN-0.6, BAGO/RN-1.2, and BAGO/RN-1.8 and (b) RN, GO/RN-1.2, and BAGO/RN-1.2.…”

Section: Resultsmentioning

confidence: 99%

“…(a) Anhydrous proton conductivities (120 °C) of RN, GO/RN-1.2, and BAGO/RN-1.2 and (b) proton conductivities (95% RH, 90 °C) of RN and BAGO/RN-1.2 during 1550 min of test.…”

Section: Resultsmentioning

confidence: 99%

Section: Pem Characterizationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Construction of Surface Sulfonic and Amino Acid–Base Pair Modified Graphene Oxide for Effectively Promoting the Selectivity of the Proton Exchange Membrane

Rao,

Zhang,

Liu

et al. 2023

ACS Appl. Polym. Mater.

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Quantifying the Ground‐State Hydrogen‐Bond Formation of a Super‐Photoacid by Inspecting Its Excited‐State Dynamics

Choi,

Nho,

Kim

et al. 2023

ChemPhotoChem

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The identification and quantification of hydrogen (H)‐bonded complexes form the cornerstone of reaction‐mechanism analysis in ultrafast proton transfers. Traditionally, the Benesi‐Hildebrand method has been employed to obtain the formation constants of H‐bonded complexes, given that H‐bonding additives induce an alteration in spectral features exclusively through H‐bond formation. However, if the additive introduction impacts the bulk polarity of the solution, inducing a spectral shift, the spectroscopic method's accuracy in analyzing the H‐bond formation becomes compromised. In this study, we scrutinize H‐bond formation under the influence of an H‐bond accepting solute in an aprotic solvent. This is achieved by quantifying the fractions of two concurrent pathways involved in the excited‐state proton transfer (ESPT) of a super‐photoacid: the ultrafast ESPT of an H‐bonded complex vs. the diffusion‐controlled ESPT of the free acid. Our method offers improved accuracy compared to conventional steady‐state spectroscopic techniques, by directly quantifying the H‐bonded complexes using the time‐resolved spectroscopic method, thereby circumventing the aforementioned limitation.

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Composite proton exchange membrane for fuel cells based on chitosan modified by acid-base amphoteric nanoparticles

Fan,

Ou,

Yang

et al. 2024

International Journal of Biological Macromolecules

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Enhanced Proton Transfer in Proton‐Exchange Membranes with Interconnected and Zwitterion‐Functionalized Covalent Porous Material Structures

Cited by 8 publications

References 48 publications

Construction of Surface Sulfonic and Amino Acid–Base Pair Modified Graphene Oxide for Effectively Promoting the Selectivity of the Proton Exchange Membrane

Construction of Surface Sulfonic and Amino Acid–Base Pair Modified Graphene Oxide for Effectively Promoting the Selectivity of the Proton Exchange Membrane

Quantifying the Ground‐State Hydrogen‐Bond Formation of a Super‐Photoacid by Inspecting Its Excited‐State Dynamics

Composite proton exchange membrane for fuel cells based on chitosan modified by acid-base amphoteric nanoparticles

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