Related Data for: Graphene quantum dot enabled interlayer spacing and electronic structure regulation of single-atom doped MoS2 for efficient alkaline hydrogen evolution (doi:10.21979/N9/MFQSBN)

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Document Description

Citation

Title:

Related Data for: Graphene quantum dot enabled interlayer spacing and electronic structure regulation of single-atom doped MoS2 for efficient alkaline hydrogen evolution

Identification Number:

doi:10.21979/N9/MFQSBN

Distributor:

DR-NTU (Data)

Date of Distribution:

2023-11-17

Version:

1

Bibliographic Citation:

Zhang, Zheye; Gong, Jun; Xi, Shibo; Wang, Wenjun; Lu, Jianmei; Chen, Peng, 2023, "Related Data for: Graphene quantum dot enabled interlayer spacing and electronic structure regulation of single-atom doped MoS2 for efficient alkaline hydrogen evolution", https://doi.org/10.21979/N9/MFQSBN, DR-NTU (Data), V1

Study Description

Citation

Title:

Related Data for: Graphene quantum dot enabled interlayer spacing and electronic structure regulation of single-atom doped MoS2 for efficient alkaline hydrogen evolution

Identification Number:

doi:10.21979/N9/MFQSBN

Authoring Entity:

Zhang, Zheye (Nanyang Technological University)

Gong, Jun (Nanyang Technological University)

Xi, Shibo (Agency for Science, Technology and Research (A*STAR))

Wang, Wenjun (Liaocheng University)

Lu, Jianmei (Soochow University)

Chen, Peng (Nanyang Technological University)

Software used in Production:

Zhang Zheye

Grant Number:

AMEIRG18-0016

Grant Number:

BK20202012

Distributor:

DR-NTU (Data)

Access Authority:

Zhang, Zheye

Depositor:

Zhang, Zheye

Date of Deposit:

2023-10-01

Holdings Information:

https://doi.org/10.21979/N9/MFQSBN

Study Scope

Keywords:

Chemistry, Chemistry, Interlayer engineering; Graphene quantum dots; Molybdenum disulfide; Single-atom catalysts; Hydrogen evolution reaction

Abstract:

1. GQD/Co-MoS2 was synthesized by a facile one-pot hydrothermal approach 2. GQD/Co-MoS2 exhibits excellent HER activity and stability in alkaline electrolyte. 3. Enlarged interlayer spacing and electronic coupling enhanced the HER activity.

Kind of Data:

experimental data

Methodology and Processing

Sources Statement

Data Access

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Related Publications

Citation

Identification Number:

10.1016/j.cej.2022.138951

Bibliographic Citation:

Gong, J., Zhang, Z., Xi, S., Wang, W., Lu, J., & Chen, P. (2023). Graphene quantum dot enabled interlayer spacing and electronic structure regulation of single-atom doped MoS2 for efficient alkaline hydrogen evolution. Chemical Engineering Journal, 451, 138951.

Citation

Identification Number:

10356/162773

Bibliographic Citation:

Gong, J., Zhang, Z., Xi, S., Wang, W., Lu, J., & Chen, P. (2023). Graphene quantum dot enabled interlayer spacing and electronic structure regulation of single-atom doped MoS2 for efficient alkaline hydrogen evolution. Chemical Engineering Journal, 451, 138951.

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