rGO coated cotton fabric and thermoelectric module arrays for efficient solar desalination and electricity generation

Ahmed Mortuza Saleque; Amrit Kumar Thakur; R. Saidur; Mohammad Ismail Hossain; Wayesh Qarony; Md Shamim Ahamed; Iseult Lynch; Y. Ma; Yuen Hong Tsang

doi:10.1039/d3ta04715f

rGO coated cotton fabric and thermoelectric module arrays for efficient solar desalination and electricity generation

Ahmed Mortuza Saleque, Amrit Kumar Thakur, R. Saidur, Mohammad Ismail Hossain, Wayesh Qarony, Md Shamim Ahamed, Iseult Lynch, Y. Ma, Yuen Hong Tsang^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

Abstract

One promising solution to the freshwater crisis is solar-driven interfacial evaporation-based desalination. However, an alternate strategy is needed to address both water and energy shortages in parallel. Additionally, the disposal of desalination brine necessitates specific consideration while designing a sustainable solar interfacial desalination system. Herein, we demonstrate a single system that utilizes incident solar irradiance to produce interfacial steam using reduced graphene oxide (rGO) coated cotton fabric (CF) to desalinate seawater with an evaporation efficiency of 86.98%. The high thermal conductivity and excellent optical absorption of rGO contribute to the absorption of a broad solar spectrum. The system also produces 339.26 mW of electricity simultaneously by deploying commercially available thermoelectric generator (TEG) modules that use the squandered heat, increasing the overall system efficiency by 7.3%. The use of a custom-made power electronics module ensures operating at the maximum power point which has also been verified by computer simulation. Finally, hydrogen gas with zero carbon emission is produced by electrolyzing the seawater utilizing the electricity generated by the TEG module using solar-induced heat at a rate of 0.52 mmol h⁻¹. Converting brine into hydrogen and oxygen gas by electrolysis demonstrates a potential in situ approach for desalination waste remediation.

Original language	English
Pages (from-to)	405-418
Number of pages	14
Journal	Journal of Materials Chemistry A
Volume	12
Issue number	1
Early online date	29 Nov 2023
DOIs	https://doi.org/10.1039/d3ta04715f
Publication status	Published - 7 Jan 2024

Bibliographical note

Funding Information:
This work is financially supported by the Innovation and Technology Fund, Hong Kong, China (GHP/040/19SZ), the Hong Kong Polytechnic University (Project number: 1-ZE14), Photonic Research Institute, The Hong Kong Polytechnic University (Project number: 1-CD6V), and the Hong Kong Polytechnic University Shenzhen Research Institute, Shenzhen, China (Grant Code: the science and technology innovation commission of Shenzhen (JCYJ20210324141206017)).

Publisher Copyright:
© 2024 The Royal Society of Chemistry.

ASJC Scopus subject areas

General Chemistry
Renewable Energy, Sustainability and the Environment
General Materials Science

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1039/d3ta04715f

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SalequeAM2023rGO_AAM
Accepted author manuscript, 2.43 MB
Licence: Other (please specify with Rights Statement)
Embargo ends: 29/11/24

Cite this

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abstract = "One promising solution to the freshwater crisis is solar-driven interfacial evaporation-based desalination. However, an alternate strategy is needed to address both water and energy shortages in parallel. Additionally, the disposal of desalination brine necessitates specific consideration while designing a sustainable solar interfacial desalination system. Herein, we demonstrate a single system that utilizes incident solar irradiance to produce interfacial steam using reduced graphene oxide (rGO) coated cotton fabric (CF) to desalinate seawater with an evaporation efficiency of 86.98%. The high thermal conductivity and excellent optical absorption of rGO contribute to the absorption of a broad solar spectrum. The system also produces 339.26 mW of electricity simultaneously by deploying commercially available thermoelectric generator (TEG) modules that use the squandered heat, increasing the overall system efficiency by 7.3%. The use of a custom-made power electronics module ensures operating at the maximum power point which has also been verified by computer simulation. Finally, hydrogen gas with zero carbon emission is produced by electrolyzing the seawater utilizing the electricity generated by the TEG module using solar-induced heat at a rate of 0.52 mmol h−1. Converting brine into hydrogen and oxygen gas by electrolysis demonstrates a potential in situ approach for desalination waste remediation.",

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AU - Lynch, Iseult

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AU - Tsang, Yuen Hong

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N2 - One promising solution to the freshwater crisis is solar-driven interfacial evaporation-based desalination. However, an alternate strategy is needed to address both water and energy shortages in parallel. Additionally, the disposal of desalination brine necessitates specific consideration while designing a sustainable solar interfacial desalination system. Herein, we demonstrate a single system that utilizes incident solar irradiance to produce interfacial steam using reduced graphene oxide (rGO) coated cotton fabric (CF) to desalinate seawater with an evaporation efficiency of 86.98%. The high thermal conductivity and excellent optical absorption of rGO contribute to the absorption of a broad solar spectrum. The system also produces 339.26 mW of electricity simultaneously by deploying commercially available thermoelectric generator (TEG) modules that use the squandered heat, increasing the overall system efficiency by 7.3%. The use of a custom-made power electronics module ensures operating at the maximum power point which has also been verified by computer simulation. Finally, hydrogen gas with zero carbon emission is produced by electrolyzing the seawater utilizing the electricity generated by the TEG module using solar-induced heat at a rate of 0.52 mmol h−1. Converting brine into hydrogen and oxygen gas by electrolysis demonstrates a potential in situ approach for desalination waste remediation.

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rGO coated cotton fabric and thermoelectric module arrays for efficient solar desalination and electricity generation

Abstract

Bibliographical note

ASJC Scopus subject areas

UN SDGs

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