Bifunctional porous iron phosphide/carbon nanostructure enabled high-performance sodium-ion battery and hydrogen evolution reaction

Bifunctional porous iron phosphide/carbon nanostructure enabled high-performance sodium-ion battery and hydrogen evolution reaction

Transition metal phosphides, such as iron phosphide (FeP), have recently been studied as promising high performance active materials for sodium-ion batteries (SIBs) and hydrogen evolution reaction (HER) due to their excellent energy storage and conversion capabilities. To achieve long cycle lifetime...

Full description

Saved in:
Bibliographic Details
Main Authors: Lim, Yew Von, Huang, Shaozhuan, Zhang, Yingmeng, Kong, Dezhi, Wang, Ye, Guo, Lu, Zhang, Jun, Shi, Yumeng, Chen, Tu Pei, Ang, Lay Kee, Yang, Hui Ying
Other Authors: School of Electrical and Electronic Engineering
Format: Article
Language:English
Published: 2020
Subjects:
Engineering::Electrical and electronic engineering
Metal-organic Framework
Porous FeP/C Nanocomposites
Online Access:https://hdl.handle.net/10356/139177
Tags: Add Tag
No Tags, Be the first to tag this record!
Institution: Nanyang Technological University
Language: English
id sg-ntu-dr.10356-139177
record_format dspace
spelling sg-ntu-dr.10356-1391772020-05-18T01:18:08Z Bifunctional porous iron phosphide/carbon nanostructure enabled high-performance sodium-ion battery and hydrogen evolution reaction Lim, Yew Von Huang, Shaozhuan Zhang, Yingmeng Kong, Dezhi Wang, Ye Guo, Lu Zhang, Jun Shi, Yumeng Chen, Tu Pei Ang, Lay Kee Yang, Hui Ying School of Electrical and Electronic Engineering Engineering::Electrical and electronic engineering Metal-organic Framework Porous FeP/C Nanocomposites Transition metal phosphides, such as iron phosphide (FeP), have recently been studied as promising high performance active materials for sodium-ion batteries (SIBs) and hydrogen evolution reaction (HER) due to their excellent energy storage and conversion capabilities. To achieve long cycle lifetime, high rate sodium storage performance and stable HER reactivity, porous FeP/C nanostructures have been designed and synthesized through low temperature phosphorization of the Metal-Organic Framework (MOF) nanostructure. The resulting FeP/C composite consists of highly porous nanocubic structure with FeP nanoparticles distributing the carbon scaffolding, showing high surface area and small pore size distribution. This unique nanostructure enables fast and efficient electrons/ions transportation, and provides abundant reactive sites uniformly distributing the highly-ordered MOF-derived nanocubes. Benefitting from the unique porous structure, the FeP/C nanocubes exhibit remarkable sodium storage performance in terms of high capacity (410 mA h g−1, 100 mA g−1), excellent rate capacity (up to 1 A g−1) and long cycle life (> 200 cycles). The electrochemical reaction mechanisms of the FeP/C composite upon sodiation/desodiation are investigated in detail via ex-situ XRD, SEM and TEM methods, which show that the sodium storage in FeP is based on both the intercalation/conversion reactions. In addition, FeP/C as HER electrodes maintain its reactivity for at least 40 h and exhibit an low onset overpotential of 80 mV and a low Tafel slope of 40 mV dec−1. These results reveal the sodium storage mechanism of FeP and suggest that the MOF-derived FeP/C composite is a promising candidate for high-performance SIBs and HER electrode material. 2020-05-18T01:18:08Z 2020-05-18T01:18:08Z 2018 Journal Article Lim, Y. V., Huang, S., Zhang, Y., Kong, D., Wang, Y., Guo, L., . . . Yang, H. Y. (2018). Bifunctional porous iron phosphide/carbon nanostructure enabled high-performance sodium-ion battery and hydrogen evolution reaction. Energy Storage Materials, 15, 98-107. doi:10.1016/j.ensm.2018.03.009 2405-8297 https://hdl.handle.net/10356/139177 10.1016/j.ensm.2018.03.009 2-s2.0-85044635388 15 98 107 en Energy Storage Materials © 2018 Elsevier B.V. All rights reserved.
institution Nanyang Technological University
building NTU Library
country Singapore
collection DR-NTU
language English
topic Engineering::Electrical and electronic engineering
Metal-organic Framework
Porous FeP/C Nanocomposites
spellingShingle Engineering::Electrical and electronic engineering
Metal-organic Framework
Porous FeP/C Nanocomposites
Lim, Yew Von
Huang, Shaozhuan
Zhang, Yingmeng
Kong, Dezhi
Wang, Ye
Guo, Lu
Zhang, Jun
Shi, Yumeng
Chen, Tu Pei
Ang, Lay Kee
Yang, Hui Ying
Bifunctional porous iron phosphide/carbon nanostructure enabled high-performance sodium-ion battery and hydrogen evolution reaction
description Transition metal phosphides, such as iron phosphide (FeP), have recently been studied as promising high performance active materials for sodium-ion batteries (SIBs) and hydrogen evolution reaction (HER) due to their excellent energy storage and conversion capabilities. To achieve long cycle lifetime, high rate sodium storage performance and stable HER reactivity, porous FeP/C nanostructures have been designed and synthesized through low temperature phosphorization of the Metal-Organic Framework (MOF) nanostructure. The resulting FeP/C composite consists of highly porous nanocubic structure with FeP nanoparticles distributing the carbon scaffolding, showing high surface area and small pore size distribution. This unique nanostructure enables fast and efficient electrons/ions transportation, and provides abundant reactive sites uniformly distributing the highly-ordered MOF-derived nanocubes. Benefitting from the unique porous structure, the FeP/C nanocubes exhibit remarkable sodium storage performance in terms of high capacity (410 mA h g−1, 100 mA g−1), excellent rate capacity (up to 1 A g−1) and long cycle life (> 200 cycles). The electrochemical reaction mechanisms of the FeP/C composite upon sodiation/desodiation are investigated in detail via ex-situ XRD, SEM and TEM methods, which show that the sodium storage in FeP is based on both the intercalation/conversion reactions. In addition, FeP/C as HER electrodes maintain its reactivity for at least 40 h and exhibit an low onset overpotential of 80 mV and a low Tafel slope of 40 mV dec−1. These results reveal the sodium storage mechanism of FeP and suggest that the MOF-derived FeP/C composite is a promising candidate for high-performance SIBs and HER electrode material.
author2 School of Electrical and Electronic Engineering
author_facet School of Electrical and Electronic Engineering
Lim, Yew Von
Huang, Shaozhuan
Zhang, Yingmeng
Kong, Dezhi
Wang, Ye
Guo, Lu
Zhang, Jun
Shi, Yumeng
Chen, Tu Pei
Ang, Lay Kee
Yang, Hui Ying
format Article
author Lim, Yew Von
Huang, Shaozhuan
Zhang, Yingmeng
Kong, Dezhi
Wang, Ye
Guo, Lu
Zhang, Jun
Shi, Yumeng
Chen, Tu Pei
Ang, Lay Kee
Yang, Hui Ying
author_sort Lim, Yew Von
title Bifunctional porous iron phosphide/carbon nanostructure enabled high-performance sodium-ion battery and hydrogen evolution reaction
title_short Bifunctional porous iron phosphide/carbon nanostructure enabled high-performance sodium-ion battery and hydrogen evolution reaction
title_full Bifunctional porous iron phosphide/carbon nanostructure enabled high-performance sodium-ion battery and hydrogen evolution reaction
title_fullStr Bifunctional porous iron phosphide/carbon nanostructure enabled high-performance sodium-ion battery and hydrogen evolution reaction
title_full_unstemmed Bifunctional porous iron phosphide/carbon nanostructure enabled high-performance sodium-ion battery and hydrogen evolution reaction
title_sort bifunctional porous iron phosphide/carbon nanostructure enabled high-performance sodium-ion battery and hydrogen evolution reaction
publishDate 2020
url https://hdl.handle.net/10356/139177
_version_ 1681056164279746560

Similar Items