Polynorepinephrine-Regulated Filler Sulfonation Toward Interfacial Reformation And Conductive Promotion Of Nanocomposite Proton Exchange Membrane

Huang, Tong; Liu, Xin; Ma, Ruibin; Gao, Yangyang; Xu, Xiaomin; Yan, Chengrun; Guo, Yuchen; Li, Xiaoxu; Sharma, Kamlesh; Liu, Lingling; Xue, Jiandang; Huang, Huadong; Zhang, Xiyuan; Yin, Xiaochun; Zhai, Shaoxiong; Chen, Jiechao; Jia, Xiaoyang; He, Shaojian; Lin, Jun; Zhang, Liqun

doi:10.2139/ssrn.4631850

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Polynorepinephrine-Regulated Filler Sulfonation Toward Interfacial Reformation And Conductive Promotion Of Nanocomposite Proton Exchange Membrane

24 Pages Posted: 14 Nov 2023

See all articles by Tong Huang

Ruibin Ma

Beijing University of Chemical Technology

Yangyang Gao

Beijing University of Chemical Technology

Kamlesh Sharma

Indian Institute of Technology (IIT), Kharagpur

Beijing University of Chemical Technology - State Key Laboratory of Organic-Inorganic Composites; Beijing University of Chemical Technology- Engineering Research Center of Ministry of Education on Energy and Resource Saved Elastomers

Abstract

Interfacial compatibility between filler and matrix substantially affects the overall morphology and performance of nanocomposites. Compared with bare montmorillonite (MMT), surface modified product such as sulfonated MMT (SMMT) has been known to render optimized interfacial compatibility in composite proton exchange membranes (PEMs) for proton exchange membrane fuel cells (PEMFCs) and direct methanol fuel cells (DMFCs). Nevertheless, in-depth understanding and investigation on the sulfonation of MMT are seldom focused, such as uniformity and sufficiency. Herein, these broadly neglected issues are proposed and resolved using an exemplary polynorepinephrine (PNE)-regulated SMMT (SNMMT). Rather than direct sulfonation utilizing the inherent hydroxyl groups of MMT, a PNE coating with ample hydroxyl groups is deposited on MMT beforehand, which results in more homogeneous and sufficient sulfonation of SNMMT. Compared with normal SMMT, this alteration on surficial geography of filler functionalization brings significant benefits when composited with Nafion matrix, including harmonized filler-matrix compatibility, improved mechanical stability and enhanced proton conduction. Moreover, the antioxidative ability of PNE layer enables improved chemical stability of nanocomposite PEM. The Nafion/SNMMT composite PEM achieves 0.275 S cm-1 proton conductivity at 95 ºC in water, evidently beyond any previously reported composite PEMs using normal SMMT. Equipped with this reformed nanocomposite PEM, both PEMFC and DMFC display competitive peak power densities (1.121 W cm-2 with H2/O2 at 80 ºC/100% relative humidity (RH) for PEMFC, and 0.228 W cm-2 with 1.6 M methanol/100% RH O2 for DMFC), and simultaneously show minor performance deteriorations in constant current density operation and RH cycle tests. It would be instructive the specific focus and reformation on the uniformity and sufficiency of filler modification may render significant interface and performance advancements for nanocomposites.

Keywords: Organic-inorganic nanocomposite, Filler functionalization, Interfacial compatibility, proton conduction, Fuel Cell

Suggested Citation: Suggested Citation

Huang, Tong and Liu, Xin and Ma, Ruibin and Gao, Yangyang and Xu, Xiaomin and Yan, Chengrun and Guo, Yuchen and Li, Xiaoxu and Sharma, Kamlesh and Liu, Lingling and Xue, Jiandang and Huang, Huadong and Zhang, Xiyuan and Yin, Xiaochun and Zhai, Shaoxiong and Chen, Jiechao and Jia, Xiaoyang and He, Shaojian and Lin, Jun and Zhang, Liqun, Polynorepinephrine-Regulated Filler Sulfonation Toward Interfacial Reformation And Conductive Promotion Of Nanocomposite Proton Exchange Membrane. Available at SSRN: https://ssrn.com/abstract=4631850 or http://dx.doi.org/10.2139/ssrn.4631850