Frequency-dependent on immitance response and ionic transport mechanisms in poly(methylmethacrylate)–NaTFSi based gel polymer electrolytes: 5th International Conference on Science and Engineering of Materials 2025 (ICSEM 2025)

This study investigates the dielectric relaxation and ionic conduction behavior of gel polymer electrolytes (GPEs) composed of poly(methyl methacrylate) (PMMA), sodium bis(trifluoromethanesulfonyl)imide (NaTFSI), and tetraethylene glycol dimethyl ether (TEGDME). GPE samples containing 5–30 wt.% NaTF...

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Main Authors:	Nurfatin Nabilah, Abdul Hafidz, Aynharan, Sanjjeevadharshini, Ahmad Salihin, Samsudin
Format:	Article
Language:	English
Published:	John Wiley & Sons, Inc. 2025
Subjects:	HD Industries. Land use. Labor
Online Access:	https://umpir.ump.edu.my/id/eprint/46016/

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author	Nurfatin Nabilah, Abdul Hafidz Aynharan, Sanjjeevadharshini Ahmad Salihin, Samsudin
author_facet	Nurfatin Nabilah, Abdul Hafidz Aynharan, Sanjjeevadharshini Ahmad Salihin, Samsudin
author_sort	Nurfatin Nabilah, Abdul Hafidz
building	UMP Institutional Repository
collection	Online Access
description	This study investigates the dielectric relaxation and ionic conduction behavior of gel polymer electrolytes (GPEs) composed of poly(methyl methacrylate) (PMMA), sodium bis(trifluoromethanesulfonyl)imide (NaTFSI), and tetraethylene glycol dimethyl ether (TEGDME). GPE samples containing 5–30 wt.% NaTFSI were synthesized and analyzed using dielectric spectroscopy across 102 – 106 Hz and temperatures from 303 to 373 K. The 20 wt.% NaTFSI composition exhibited the highest ionic conductivity, attributed to optimal ion dissociation and enhanced motion of the polymer segments. Dielectric parameters, such as permittivity (εʹ, εʺ), electric modulus (Mʹ, Mʺ), and loss tangent (tan δ), demonstrated temperature- and frequency-dependent trends characteristic of ionic relaxation processes. The 20 wt.% NaTFSI composition (Na20) exhibited the highest ionic conductivity of 3.65 × 10−4 S cm−1 at 303 K, attributed to optimal salt dissociation and enhanced polymer chain mobility. Dielectric spectra revealed characteristic relaxation peaks, with Na20 showing the shortest relaxation time (τ = 2.65 s) compared to other compositions. The results confirm that a combination of hopping and segmental motion mechanisms governs ion conduction. These findings highlight the unique value of frequency-dependent dielectric analysis in elucidating coupled hopping and segmental motion mechanisms, offering a molecular-level understanding of polymer–ion interactions. This work provides a fresh perspective on tailoring PMMA-based GPEs for sodium-ion batteries, bridging critical knowledge gaps in sodium-conducting polymer electrolytes.
first_indexed	2025-11-15T04:02:26Z
format	Article
id	ump-46016
institution	Universiti Malaysia Pahang
institution_category	Local University
language	English
last_indexed	2025-11-15T04:02:26Z
publishDate	2025
publisher	John Wiley & Sons, Inc.
recordtype	eprints
repository_type	Digital Repository
spelling	ump-460162025-10-23T03:51:05Z https://umpir.ump.edu.my/id/eprint/46016/ Frequency-dependent on immitance response and ionic transport mechanisms in poly(methylmethacrylate)–NaTFSi based gel polymer electrolytes: 5th International Conference on Science and Engineering of Materials 2025 (ICSEM 2025) Nurfatin Nabilah, Abdul Hafidz Aynharan, Sanjjeevadharshini Ahmad Salihin, Samsudin HD Industries. Land use. Labor This study investigates the dielectric relaxation and ionic conduction behavior of gel polymer electrolytes (GPEs) composed of poly(methyl methacrylate) (PMMA), sodium bis(trifluoromethanesulfonyl)imide (NaTFSI), and tetraethylene glycol dimethyl ether (TEGDME). GPE samples containing 5–30 wt.% NaTFSI were synthesized and analyzed using dielectric spectroscopy across 102 – 106 Hz and temperatures from 303 to 373 K. The 20 wt.% NaTFSI composition exhibited the highest ionic conductivity, attributed to optimal ion dissociation and enhanced motion of the polymer segments. Dielectric parameters, such as permittivity (εʹ, εʺ), electric modulus (Mʹ, Mʺ), and loss tangent (tan δ), demonstrated temperature- and frequency-dependent trends characteristic of ionic relaxation processes. The 20 wt.% NaTFSI composition (Na20) exhibited the highest ionic conductivity of 3.65 × 10−4 S cm−1 at 303 K, attributed to optimal salt dissociation and enhanced polymer chain mobility. Dielectric spectra revealed characteristic relaxation peaks, with Na20 showing the shortest relaxation time (τ = 2.65 s) compared to other compositions. The results confirm that a combination of hopping and segmental motion mechanisms governs ion conduction. These findings highlight the unique value of frequency-dependent dielectric analysis in elucidating coupled hopping and segmental motion mechanisms, offering a molecular-level understanding of polymer–ion interactions. This work provides a fresh perspective on tailoring PMMA-based GPEs for sodium-ion batteries, bridging critical knowledge gaps in sodium-conducting polymer electrolytes. John Wiley & Sons, Inc. 2025-10 Article PeerReviewed pdf en https://umpir.ump.edu.my/id/eprint/46016/1/Frequency-Dependent%20on%20Immitance%20Response%20and%20Ionic%20Transport%20Mechanisms%20in%20Poly.pdf Nurfatin Nabilah, Abdul Hafidz and Aynharan, Sanjjeevadharshini and Ahmad Salihin, Samsudin (2025) Frequency-dependent on immitance response and ionic transport mechanisms in poly(methylmethacrylate)–NaTFSi based gel polymer electrolytes: 5th International Conference on Science and Engineering of Materials 2025 (ICSEM 2025). Macromolecular Symposia. pp. 1-9. ISSN 1521-3900. (In Press / Online First) (In Press / Online First) https://doi.org/10.1002/masy.70167
spellingShingle	HD Industries. Land use. Labor Nurfatin Nabilah, Abdul Hafidz Aynharan, Sanjjeevadharshini Ahmad Salihin, Samsudin Frequency-dependent on immitance response and ionic transport mechanisms in poly(methylmethacrylate)–NaTFSi based gel polymer electrolytes: 5th International Conference on Science and Engineering of Materials 2025 (ICSEM 2025)
title	Frequency-dependent on immitance response and ionic transport mechanisms in poly(methylmethacrylate)–NaTFSi based gel polymer electrolytes: 5th International Conference on Science and Engineering of Materials 2025 (ICSEM 2025)
title_full	Frequency-dependent on immitance response and ionic transport mechanisms in poly(methylmethacrylate)–NaTFSi based gel polymer electrolytes: 5th International Conference on Science and Engineering of Materials 2025 (ICSEM 2025)
title_fullStr	Frequency-dependent on immitance response and ionic transport mechanisms in poly(methylmethacrylate)–NaTFSi based gel polymer electrolytes: 5th International Conference on Science and Engineering of Materials 2025 (ICSEM 2025)
title_full_unstemmed	Frequency-dependent on immitance response and ionic transport mechanisms in poly(methylmethacrylate)–NaTFSi based gel polymer electrolytes: 5th International Conference on Science and Engineering of Materials 2025 (ICSEM 2025)
title_short	Frequency-dependent on immitance response and ionic transport mechanisms in poly(methylmethacrylate)–NaTFSi based gel polymer electrolytes: 5th International Conference on Science and Engineering of Materials 2025 (ICSEM 2025)
title_sort	frequency-dependent on immitance response and ionic transport mechanisms in poly(methylmethacrylate)–natfsi based gel polymer electrolytes: 5th international conference on science and engineering of materials 2025 (icsem 2025)
topic	HD Industries. Land use. Labor
url	https://umpir.ump.edu.my/id/eprint/46016/ https://umpir.ump.edu.my/id/eprint/46016/

Frequency-dependent on immitance response and ionic transport mechanisms in poly(methylmethacrylate)–NaTFSi based gel polymer electrolytes: 5th International Conference on Science and Engineering of Materials 2025 (ICSEM 2025)

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