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Correlation between proton conductivity, hydrophilicity, and thermal stability of chitosan/montmorillonite composite membrane modified GPTMS and their performance in direct methanol fuel cell

Chitosan based inorganic hybrid membrane is a promising organic–inorganic hybrids for the development of high performance proton exchange membrane (PEM). The immobilization of modified montmorillonite (MMT) using GPTMS within chitosan matrix would possess superior physicochemical characteristics due...

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Main Authors: Purwanto, M., Atmaja, L., Salleh, M. T., Mohamed, M. A., Jaafar, J., Ismail, A. F., Santoso, M., Widiastuti, N.
Format: Article
Published: Malaysian Society of Analytical Sciences 2017
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TP Chemical technology
Online Access:http://eprints.utm.my/id/eprint/76816/
https://www.scopus.com/inward/record.uri?eid=2-s2.0-85021181695&doi=10.17576%2fmjas-2017-2103-17&partnerID=40&md5=fe212df5cacc9d8bb39985663f06dcab
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spelling my.utm.768162018-04-30T14:10:24Z http://eprints.utm.my/id/eprint/76816/ Correlation between proton conductivity, hydrophilicity, and thermal stability of chitosan/montmorillonite composite membrane modified GPTMS and their performance in direct methanol fuel cell Purwanto, M. Atmaja, L. Salleh, M. T. Mohamed, M. A. Jaafar, J. Ismail, A. F. Santoso, M. Widiastuti, N. TP Chemical technology Chitosan based inorganic hybrid membrane is a promising organic–inorganic hybrids for the development of high performance proton exchange membrane (PEM). The immobilization of modified montmorillonite (MMT) using GPTMS within chitosan matrix would possess superior physicochemical characteristics due to more hydrogen bonding formation introduced by GPTMS. Therefore, higher number hydrogen bond formation can be expected in Ch/MMT-GPTMS membrane rather than in pure Ch membrane. A fully hydrated membrane at elevated temperatures is desirable for efficient proton conduction in the membranes. It remains a critical challenge to maintain proper hydration of the membranes for the operation of the direct methanol fuel cell (DMFC). The microstructure obtained by SEM for composites showed that filler was successfully incorporated and relatively well dispersed in the chitosan polymer matrix. The role of surface modification of MMT filler by GPTMS have increase the functional group that can form hydrogen bonding which suitable for interaction with water. High water uptake is favourable for high performance PEM to facilitate great numbers of protons hopping and diffusion through the membrane. In addition, greater hydrogen bonding formation would lead to the tighter packing of composite membrane, resulting in higher bonding strength and higher thermal resistance. The Ch/MMT-GPTMS composite membrane with 5 wt% filler loading exhibited the best proton conductivity are 4.66 mScm-1, with water contact angle value of 64.73°. A maximum power density of 0.24 mWcm-2 was obtained with a 2M methanol feed. The relationship of water contact angle, water upake, membrane swelling, thermal stability, and proton conductivity shown suitable trend, it means that all quality of them are related to the hydrophilicity properties. Malaysian Society of Analytical Sciences 2017 Article PeerReviewed Purwanto, M. and Atmaja, L. and Salleh, M. T. and Mohamed, M. A. and Jaafar, J. and Ismail, A. F. and Santoso, M. and Widiastuti, N. (2017) Correlation between proton conductivity, hydrophilicity, and thermal stability of chitosan/montmorillonite composite membrane modified GPTMS and their performance in direct methanol fuel cell. Malaysian Journal of Analytical Sciences, 21 (3). pp. 675-689. ISSN 1394-2506 https://www.scopus.com/inward/record.uri?eid=2-s2.0-85021181695&doi=10.17576%2fmjas-2017-2103-17&partnerID=40&md5=fe212df5cacc9d8bb39985663f06dcab DOI:10.17576/mjas-2017-2103-17
institution Universiti Teknologi Malaysia
building UTM Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Teknologi Malaysia
content_source UTM Institutional Repository
url_provider http://eprints.utm.my/
topic TP Chemical technology
spellingShingle TP Chemical technology
Purwanto, M.
Atmaja, L.
Salleh, M. T.
Mohamed, M. A.
Jaafar, J.
Ismail, A. F.
Santoso, M.
Widiastuti, N.
Correlation between proton conductivity, hydrophilicity, and thermal stability of chitosan/montmorillonite composite membrane modified GPTMS and their performance in direct methanol fuel cell
description Chitosan based inorganic hybrid membrane is a promising organic–inorganic hybrids for the development of high performance proton exchange membrane (PEM). The immobilization of modified montmorillonite (MMT) using GPTMS within chitosan matrix would possess superior physicochemical characteristics due to more hydrogen bonding formation introduced by GPTMS. Therefore, higher number hydrogen bond formation can be expected in Ch/MMT-GPTMS membrane rather than in pure Ch membrane. A fully hydrated membrane at elevated temperatures is desirable for efficient proton conduction in the membranes. It remains a critical challenge to maintain proper hydration of the membranes for the operation of the direct methanol fuel cell (DMFC). The microstructure obtained by SEM for composites showed that filler was successfully incorporated and relatively well dispersed in the chitosan polymer matrix. The role of surface modification of MMT filler by GPTMS have increase the functional group that can form hydrogen bonding which suitable for interaction with water. High water uptake is favourable for high performance PEM to facilitate great numbers of protons hopping and diffusion through the membrane. In addition, greater hydrogen bonding formation would lead to the tighter packing of composite membrane, resulting in higher bonding strength and higher thermal resistance. The Ch/MMT-GPTMS composite membrane with 5 wt% filler loading exhibited the best proton conductivity are 4.66 mScm-1, with water contact angle value of 64.73°. A maximum power density of 0.24 mWcm-2 was obtained with a 2M methanol feed. The relationship of water contact angle, water upake, membrane swelling, thermal stability, and proton conductivity shown suitable trend, it means that all quality of them are related to the hydrophilicity properties.
format Article
author Purwanto, M.
Atmaja, L.
Salleh, M. T.
Mohamed, M. A.
Jaafar, J.
Ismail, A. F.
Santoso, M.
Widiastuti, N.
author_facet Purwanto, M.
Atmaja, L.
Salleh, M. T.
Mohamed, M. A.
Jaafar, J.
Ismail, A. F.
Santoso, M.
Widiastuti, N.
author_sort Purwanto, M.
title Correlation between proton conductivity, hydrophilicity, and thermal stability of chitosan/montmorillonite composite membrane modified GPTMS and their performance in direct methanol fuel cell
title_short Correlation between proton conductivity, hydrophilicity, and thermal stability of chitosan/montmorillonite composite membrane modified GPTMS and their performance in direct methanol fuel cell
title_full Correlation between proton conductivity, hydrophilicity, and thermal stability of chitosan/montmorillonite composite membrane modified GPTMS and their performance in direct methanol fuel cell
title_fullStr Correlation between proton conductivity, hydrophilicity, and thermal stability of chitosan/montmorillonite composite membrane modified GPTMS and their performance in direct methanol fuel cell
title_full_unstemmed Correlation between proton conductivity, hydrophilicity, and thermal stability of chitosan/montmorillonite composite membrane modified GPTMS and their performance in direct methanol fuel cell
title_sort correlation between proton conductivity, hydrophilicity, and thermal stability of chitosan/montmorillonite composite membrane modified gptms and their performance in direct methanol fuel cell
publisher Malaysian Society of Analytical Sciences
publishDate 2017
url http://eprints.utm.my/id/eprint/76816/
https://www.scopus.com/inward/record.uri?eid=2-s2.0-85021181695&doi=10.17576%2fmjas-2017-2103-17&partnerID=40&md5=fe212df5cacc9d8bb39985663f06dcab
_version_ 1643657416940716032
score 13.212271

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