Ultra-stable ZnO nanobelts in electrochemical environments
Author:
Affiliation:
1. Beijing Advanced Innovation Centre for Materials Genome Engineering
2. Beijing Key Laboratory for Advanced Energy Materials and Technologies
3. University of Science and Technology Beijing
4. Beijing 100083
5. People's Republic of China
Abstract
The In-ZnO nanobelts present ultrahigh stability of morphology and electrical properties in the electrochemical environment. It can be attributed to the adsorption energy decrease in the unique lattice structure with doped indium atoms.
Funder
National Natural Science Foundation of China
Natural Science Foundation of Beijing Municipality
National Basic Research Program of China
Fundamental Research Funds for the Central Universities
Publisher
Royal Society of Chemistry (RSC)
Subject
Materials Chemistry,General Materials Science
Link
http://pubs.rsc.org/en/content/articlepdf/2021/QM/D0QM00709A
Reference72 articles.
1. Solution-Processed LiF-Doped ZnO Films for High Performance Low Temperature Field Effect Transistors and Inverted Solar Cells
2. Homostructured ZnO-based metal-oxide-semiconductor field-effect transistors deposited at low temperature by vapor cooling condensation system
3. High-Mobility ZnO Nanorod Field-Effect Transistors by Self-Alignment and Electrolyte-Gating
4. Tunable channel width of a UV-gate field effect transistor based on ZnO micro-nano wire
5. Strain-Gated Field Effect Transistor of a MoS2–ZnO 2D–1D Hybrid Structure
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