Preparation of 2D Molybdenum Phosphide via Surface-Confined Atomic Substitution

Wenbin Wang; Junlei Qi; Li Zhai; Chen Ma; Chengxuan Ke; Wei Zhai; Zongxiao Wu; Kai Bao; Yao Yao; Siyuan Li; Bo Chen; D. V.Maheswar Repaka; Xiao Zhang; Ruquan Ye; Zhuangchai Lai; Guangfu Luo; Ye Chen; Qiyuan He

doi:10.1002/adma.202203220

Preparation of 2D Molybdenum Phosphide via Surface-Confined Atomic Substitution

Wenbin Wang, Junlei Qi, Li Zhai, Chen Ma, Chengxuan Ke, Wei Zhai, Zongxiao Wu, Kai Bao, Yao Yao, Siyuan Li, Bo Chen, D. V.Maheswar Repaka, Xiao Zhang, Ruquan Ye, Zhuangchai Lai, Guangfu Luo, Ye Chen, Qiyuan He

Research output: Journal article publication › Journal article › Academic research › peer-review

38 Citations (Scopus)

Abstract

The emerging nonlayered 2D materials (NL2DMs) are sparking immense interest due to their fascinating physicochemical properties and enhanced performance in many applications. NL2DMs are particularly favored in catalytic applications owing to the extremely large surface area and low-coordinated surface atoms. However, the synthesis of NL2DMs is complex because their crystals are held together by strong isotropic covalent bonds. Here, nonlayered molybdenum phosphide (MoP) with well-defined 2D morphology is synthesized from layered molybdenum dichalcogenides via surface-confined atomic substitution. During the synthesis, the molybdenum dichalcogenide nanosheet functions as the host matrix where each layer of Mo maintains their hexagonal arrangement and forms isotropic covalent bonds with P that substitutes S, resulting in the conversion from layered van der Waals material to a covalently bonded NL2DM. The MoP nanosheets converted from few-layer MoS₂ are single crystalline, while those converted from monolayers are amorphous. The converted MoP demonstrates metallic charge transport and desirable performance in the electrocatalytic hydrogen evolution reaction (HER). More importantly, in contrast to MoS₂, which shows edge-dominated HER performance, the edge and basal plane of MoP deliver similar HER performance, which is correlated with theoretical calculations. This work provides a new synthetic strategy for high-quality nonlayered materials with well-defined 2D morphology for future exploration.

Original language	English
Article number	2203220
Journal	Advanced Materials
Volume	34
Issue number	35
DOIs	https://doi.org/10.1002/adma.202203220
Publication status	Published - 28 Jul 2022

Keywords

dangling bonds
hydrogen evolution reaction
molybdenum phosphide
on-chip electrochemistry
surface-confined atomic substitution

ASJC Scopus subject areas

General Materials Science
Mechanics of Materials
Mechanical Engineering

More information

10.1002/adma.202203220

Cite this

@article{34922a40f8494413963b5eebf2712d4f,

title = "Preparation of 2D Molybdenum Phosphide via Surface-Confined Atomic Substitution",

abstract = "The emerging nonlayered 2D materials (NL2DMs) are sparking immense interest due to their fascinating physicochemical properties and enhanced performance in many applications. NL2DMs are particularly favored in catalytic applications owing to the extremely large surface area and low-coordinated surface atoms. However, the synthesis of NL2DMs is complex because their crystals are held together by strong isotropic covalent bonds. Here, nonlayered molybdenum phosphide (MoP) with well-defined 2D morphology is synthesized from layered molybdenum dichalcogenides via surface-confined atomic substitution. During the synthesis, the molybdenum dichalcogenide nanosheet functions as the host matrix where each layer of Mo maintains their hexagonal arrangement and forms isotropic covalent bonds with P that substitutes S, resulting in the conversion from layered van der Waals material to a covalently bonded NL2DM. The MoP nanosheets converted from few-layer MoS2 are single crystalline, while those converted from monolayers are amorphous. The converted MoP demonstrates metallic charge transport and desirable performance in the electrocatalytic hydrogen evolution reaction (HER). More importantly, in contrast to MoS2, which shows edge-dominated HER performance, the edge and basal plane of MoP deliver similar HER performance, which is correlated with theoretical calculations. This work provides a new synthetic strategy for high-quality nonlayered materials with well-defined 2D morphology for future exploration.",

keywords = "dangling bonds, hydrogen evolution reaction, molybdenum phosphide, on-chip electrochemistry, surface-confined atomic substitution",

author = "Wenbin Wang and Junlei Qi and Li Zhai and Chen Ma and Chengxuan Ke and Wei Zhai and Zongxiao Wu and Kai Bao and Yao Yao and Siyuan Li and Bo Chen and Repaka, \{D. V.Maheswar\} and Xiao Zhang and Ruquan Ye and Zhuangchai Lai and Guangfu Luo and Ye Chen and Qiyuan He",

note = "Funding Information: W.W. and J.Q. contributed equally to this work. Q.H. thanks the support from the Grants (Project Nos. 9229079, 9610482, and 7005468) from City University of Hong Kong and Early Career Scheme Project 21302821 and General Research Fund Project 11314322 from Research Grants Council. Y.C. thanks the support from the Chinese University of Hong Kong Start‐up Fund (Project No. 4930977) and the Direct Grant for Research (Project No. 4053444). R.Y. acknowledges the funding Project No. 21905240 from the National Natural Science Foundation of China. C.K. and G.L. were supported by the fund of the Guangdong Provincial Key Laboratory of Computational Science and Material Design (No. 2019B030301001), the Introduced Innovative R\&D Team of Guangdong (2017ZT07C062), and the Shenzhen Science and Technology Innovation Committee (No. JCYJ20200109141412308). All the calculations were supported by the Center for Computational Science and Engineering of Southern University of Science and Technology. D.V.M.R. acknowledges funding from the Accelerated Materials Development for Manufacturing Program at A*STAR via the AME Programmatic Fund by the Agency for Science, Technology, and Research under grant No. A1898b0043. Funding Information: W.W. and J.Q. contributed equally to this work. Q.H. thanks the support from the Grants (Project Nos. 9229079, 9610482, and 7005468) from City University of Hong Kong and Early Career Scheme Project 21302821 and General Research Fund Project 11314322 from Research Grants Council. Y.C. thanks the support from the Chinese University of Hong Kong Start-up Fund (Project No. 4930977) and the Direct Grant for Research (Project No. 4053444). R.Y. acknowledges the funding Project No. 21905240 from the National Natural Science Foundation of China. C.K. and G.L. were supported by the fund of the Guangdong Provincial Key Laboratory of Computational Science and Material Design (No. 2019B030301001), the Introduced Innovative R\&D Team of Guangdong (2017ZT07C062), and the Shenzhen Science and Technology Innovation Committee (No. JCYJ20200109141412308). All the calculations were supported by the Center for Computational Science and Engineering of Southern University of Science and Technology. D.V.M.R. acknowledges funding from the Accelerated Materials Development for Manufacturing Program at A*STAR via the AME Programmatic Fund by the Agency for Science, Technology, and Research under grant No. A1898b0043. Publisher Copyright: {\textcopyright} 2022 Wiley-VCH GmbH.",

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doi = "10.1002/adma.202203220",

language = "English",

volume = "34",

journal = "Advanced Materials",

issn = "0935-9648",

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TY - JOUR

T1 - Preparation of 2D Molybdenum Phosphide via Surface-Confined Atomic Substitution

AU - Wang, Wenbin

AU - Qi, Junlei

AU - Zhai, Li

AU - Ma, Chen

AU - Ke, Chengxuan

AU - Zhai, Wei

AU - Wu, Zongxiao

AU - Bao, Kai

AU - Yao, Yao

AU - Li, Siyuan

AU - Chen, Bo

AU - Repaka, D. V.Maheswar

AU - Zhang, Xiao

AU - Ye, Ruquan

AU - Lai, Zhuangchai

AU - Luo, Guangfu

AU - Chen, Ye

AU - He, Qiyuan

N1 - Funding Information: W.W. and J.Q. contributed equally to this work. Q.H. thanks the support from the Grants (Project Nos. 9229079, 9610482, and 7005468) from City University of Hong Kong and Early Career Scheme Project 21302821 and General Research Fund Project 11314322 from Research Grants Council. Y.C. thanks the support from the Chinese University of Hong Kong Start‐up Fund (Project No. 4930977) and the Direct Grant for Research (Project No. 4053444). R.Y. acknowledges the funding Project No. 21905240 from the National Natural Science Foundation of China. C.K. and G.L. were supported by the fund of the Guangdong Provincial Key Laboratory of Computational Science and Material Design (No. 2019B030301001), the Introduced Innovative R&D Team of Guangdong (2017ZT07C062), and the Shenzhen Science and Technology Innovation Committee (No. JCYJ20200109141412308). All the calculations were supported by the Center for Computational Science and Engineering of Southern University of Science and Technology. D.V.M.R. acknowledges funding from the Accelerated Materials Development for Manufacturing Program at A*STAR via the AME Programmatic Fund by the Agency for Science, Technology, and Research under grant No. A1898b0043. Funding Information: W.W. and J.Q. contributed equally to this work. Q.H. thanks the support from the Grants (Project Nos. 9229079, 9610482, and 7005468) from City University of Hong Kong and Early Career Scheme Project 21302821 and General Research Fund Project 11314322 from Research Grants Council. Y.C. thanks the support from the Chinese University of Hong Kong Start-up Fund (Project No. 4930977) and the Direct Grant for Research (Project No. 4053444). R.Y. acknowledges the funding Project No. 21905240 from the National Natural Science Foundation of China. C.K. and G.L. were supported by the fund of the Guangdong Provincial Key Laboratory of Computational Science and Material Design (No. 2019B030301001), the Introduced Innovative R&D Team of Guangdong (2017ZT07C062), and the Shenzhen Science and Technology Innovation Committee (No. JCYJ20200109141412308). All the calculations were supported by the Center for Computational Science and Engineering of Southern University of Science and Technology. D.V.M.R. acknowledges funding from the Accelerated Materials Development for Manufacturing Program at A*STAR via the AME Programmatic Fund by the Agency for Science, Technology, and Research under grant No. A1898b0043. Publisher Copyright: © 2022 Wiley-VCH GmbH.

PY - 2022/7/28

Y1 - 2022/7/28

N2 - The emerging nonlayered 2D materials (NL2DMs) are sparking immense interest due to their fascinating physicochemical properties and enhanced performance in many applications. NL2DMs are particularly favored in catalytic applications owing to the extremely large surface area and low-coordinated surface atoms. However, the synthesis of NL2DMs is complex because their crystals are held together by strong isotropic covalent bonds. Here, nonlayered molybdenum phosphide (MoP) with well-defined 2D morphology is synthesized from layered molybdenum dichalcogenides via surface-confined atomic substitution. During the synthesis, the molybdenum dichalcogenide nanosheet functions as the host matrix where each layer of Mo maintains their hexagonal arrangement and forms isotropic covalent bonds with P that substitutes S, resulting in the conversion from layered van der Waals material to a covalently bonded NL2DM. The MoP nanosheets converted from few-layer MoS2 are single crystalline, while those converted from monolayers are amorphous. The converted MoP demonstrates metallic charge transport and desirable performance in the electrocatalytic hydrogen evolution reaction (HER). More importantly, in contrast to MoS2, which shows edge-dominated HER performance, the edge and basal plane of MoP deliver similar HER performance, which is correlated with theoretical calculations. This work provides a new synthetic strategy for high-quality nonlayered materials with well-defined 2D morphology for future exploration.

AB - The emerging nonlayered 2D materials (NL2DMs) are sparking immense interest due to their fascinating physicochemical properties and enhanced performance in many applications. NL2DMs are particularly favored in catalytic applications owing to the extremely large surface area and low-coordinated surface atoms. However, the synthesis of NL2DMs is complex because their crystals are held together by strong isotropic covalent bonds. Here, nonlayered molybdenum phosphide (MoP) with well-defined 2D morphology is synthesized from layered molybdenum dichalcogenides via surface-confined atomic substitution. During the synthesis, the molybdenum dichalcogenide nanosheet functions as the host matrix where each layer of Mo maintains their hexagonal arrangement and forms isotropic covalent bonds with P that substitutes S, resulting in the conversion from layered van der Waals material to a covalently bonded NL2DM. The MoP nanosheets converted from few-layer MoS2 are single crystalline, while those converted from monolayers are amorphous. The converted MoP demonstrates metallic charge transport and desirable performance in the electrocatalytic hydrogen evolution reaction (HER). More importantly, in contrast to MoS2, which shows edge-dominated HER performance, the edge and basal plane of MoP deliver similar HER performance, which is correlated with theoretical calculations. This work provides a new synthetic strategy for high-quality nonlayered materials with well-defined 2D morphology for future exploration.

KW - dangling bonds

KW - hydrogen evolution reaction

KW - molybdenum phosphide

KW - on-chip electrochemistry

KW - surface-confined atomic substitution

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U2 - 10.1002/adma.202203220

DO - 10.1002/adma.202203220

M3 - Journal article

AN - SCOPUS:85135054396

SN - 0935-9648

VL - 34

JO - Advanced Materials

JF - Advanced Materials

IS - 35

M1 - 2203220

ER -

Preparation of 2D Molybdenum Phosphide via Surface-Confined Atomic Substitution

Abstract

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