M
Meng Ding
Researcher at Singapore University of Technology and Design
Publications - 40
Citations - 1987
Meng Ding is an academic researcher from Singapore University of Technology and Design. The author has contributed to research in topics: Capacitive deionization & Desalination. The author has an hindex of 19, co-authored 33 publications receiving 1173 citations. Previous affiliations of Meng Ding include National University of Singapore.
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Regulating the polysulfide redox conversion by iron phosphide nanocrystals for high-rate and ultrastable lithium-sulfur battery
Shaozhuan Huang,Yew Von Lim,Xiaoming Zhang,Ye Wang,Ye Wang,Yun Zheng,Dezhi Kong,Meng Ding,Shengyuan A. Yang,Hui Ying Yang +9 more
TL;DR: In this article, a high-rate and ultrastable Li-S battery has been demonstrated by using the multifunctional iron phosphide (FeP) nanocrystals as an efficient host material to anchor the polysulfides and regulate the redox conversion.
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A Prussian blue anode for high performance electrochemical deionization promoted by the faradaic mechanism
TL;DR: The faradaic mechanism promoted EDI has provided a new insight into the design and selection of host materials for highly concentrated salt water desalination.
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Enabling Superior Sodium Capture for Efficient Water Desalination by a Tubular Polyaniline Decorated with Prussian Blue Nanocrystals.
Wenhui Shi,Xiaoyue Liu,Tianqi Deng,Shaozhuan Huang,Meng Ding,Xiaohe Miao,Chongzhi Zhu,Yihan Zhu,Wenxian Liu,Fangfang Wu,Congjie Gao,Shuo-Wang Yang,Hui Ying Yang,Jiangnan Shen,Xiehong Cao +14 more
TL;DR: This work provides a facile strategy for design of PB-based composites, which motivates the development of advanced materials toward high-performance CDI applications.
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A dual-ion electrochemistry deionization system based on AgCl-Na0.44MnO2 electrodes
TL;DR: The salt absorption/desorption capacity of the novel deionization system is stable and reversible, up to 57.4 mg g-1 for 100 cycles, which is much higher than that obtained by conventional or hybrid capacitive deionized devices.
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Designed hybrid nanostructure with catalytic effect: beyond the theoretical capacity of SnO2 anode material for lithium ion batteries.
TL;DR: A new method is proposed in employing the catalyst to increase the capacity of alloying-dealloying type anode material to beyond its theoretical value and enhance the electrochemical performance of lithium-ion batteries.