Earth-Rich Transition Metal Phosphide for Energy Conversion and Storage

Low‐cost and resourceful transition metal phosphides (TMPs) have gradually received wide acceptance in the energy industry through exhibiting comparable catalytic activity and long‐term stability to traditional catalysts (e.g., Pt/C, LiCoO2, LiFePO4, etc.). With the emergence of the research hotspot...

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Bibliographic Details
Published in:	Advanced energy materials Vol. 6; no. 13; pp. np - n/a
Main Authors:	Sun, Meng, Liu, Huijuan, Qu, Jiuhui, Li, Jinghong
Format:	Journal Article
Language:	English
Published:	Weinheim Blackwell Publishing Ltd 01-07-2016 Wiley Subscription Services, Inc
Subjects:	Catalysis Catalysts characterization Direct power generation Earth electrocatalysis Energy conversion Energy industry energy storage Morphology Phosphides Structural analysis transition metal phosphides Transition metals
Online Access:	Get full text
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Summary:	Low‐cost and resourceful transition metal phosphides (TMPs) have gradually received wide acceptance in the energy industry through exhibiting comparable catalytic activity and long‐term stability to traditional catalysts (e.g., Pt/C, LiCoO2, LiFePO4, etc.). With the emergence of the research hotspot of TMPs, probing their mechanism of catalytic energy conversion and storage inspired by the superb structure of metal‐phosphorus chelate is of great significance. To this end, recent developments in TMPs with various crystal structures and morphologies have attracted much attention. The design of TMPs ranging from the choice of different transition metals to phosphorus sources has been intensively explored. This research has indicated that multidimensional morphologies of TMPs prominently enrich the patterns of charge storage and electron transportation, and ultra‐nanoscaled TMPs obtained by multiple tools and techniques might challenge the threshold of electrocatalytic reactions. Here, recent developments in synthetic strategies of TMPs from different precursors are classified. The underlying mechanism between the structural and crystallographic characteristics and the tuned properties of TMPs in energy applications is also presented. Additionally, the key trends in structure and morphology characterization of TMPs are highlighted. Future perspectives on the challenges and opportunities facing TMPs catalysts are thereby proposed. Recent work toward exploring high‐performance TMPs applied in energy conversion and storage is summarized. For each class of TMPs, advances in synthetic mechanisms and methods to the key trends in structure and morphology characterizations in full‐scale energy applications are discussed. Lastly, perspectives on challenges and opportunities facing TMPs are presented to shed light on their promising future.
Bibliography:	National Natural Science Foundation of China - No. 51572139 National Basic Research Program of China - No. 2013CB934004 Major Program of National Natural Science Foundation of China - No. 51290282 Tsinghua University Initiative Scientific Research Program ark:/67375/WNG-JQG3K1KT-N National Science Fund for Distinguished Young Scholars of China - No. 51225805 istex:042A67428D79900BDD132B07D7FC6BCE80FE2F8B ArticleID:AENM201600087 ObjectType-Article-1 SourceType-Scholarly Journals-1 ObjectType-Feature-2 content type line 23
ISSN:	1614-6832 1614-6840
DOI:	10.1002/aenm.201600087