Unraveling Temperature‐Dependent Contact Electrification between Sliding‐Mode Triboelectric Pairs
Article Properties
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LanguageEnglish
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DOI (url)
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Publication Date2020/01/23
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Journal
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Indian UGC (journal)
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Refrences64
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Citations43
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Aurelia C. Wang School of Materials Science and Engineering Georgia Institute of Technology Atlanta GA 30332‐0245 USA
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Binbin Zhang School of Materials Science and Engineering Georgia Institute of Technology Atlanta GA 30332‐0245 USA
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Cheng Xu School of Materials Science and Engineering China University of Mining and Technology Xuzhou 221116 China
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Haiyang Zou School of Materials Science and Engineering Georgia Institute of Technology Atlanta GA 30332‐0245 USA
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Zhiqun Lin School of Materials Science and Engineering Georgia Institute of Technology Atlanta GA 30332‐0245 USA
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Zhong Lin Wang School of Materials Science and Engineering Georgia Institute of Technology Atlanta GA 30332‐0245 USABeijing Institute of Nanoenergy and Nanosystems Chinese Academy of Sciences Beijing 100083 China ORCID (unauthenticated)
Abstract
Cite
Wang, Aurelia C., et al. “Unraveling Temperature‐Dependent Contact Electrification Between Sliding‐Mode Triboelectric Pairs”. Advanced Functional Materials, vol. 30, no. 12, 2020, https://doi.org/10.1002/adfm.201909384.
Wang, A. C., Zhang, B., Xu, C., Zou, H., Lin, Z., & Wang, Z. L. (2020). Unraveling Temperature‐Dependent Contact Electrification between Sliding‐Mode Triboelectric Pairs. Advanced Functional Materials, 30(12). https://doi.org/10.1002/adfm.201909384
Wang AC, Zhang B, Xu C, Zou H, Lin Z, Wang ZL. Unraveling Temperature‐Dependent Contact Electrification between Sliding‐Mode Triboelectric Pairs. Advanced Functional Materials. 2020;30(12).
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Refrences
| Title | Journal | Journal Categories | Citations | Publication Date |
|---|---|---|---|---|
| Design and Construction of a Laboratory Scale Cyclone Tribocharger | 2008 | |||
| Contact and Frictional Electrification | 1967 | |||
Theoretical Comparison, Equivalent Transformation, and Conjunction Operations of Electromagnetic Induction Generator and Triboelectric Nanogenerator for Harvesting Mechanical Energy | Advanced Materials |
| 468 | 2014 |
| Ultrahigh charge density realized by charge pumping at ambient conditions for triboelectric nanogenerators | Nano Energy |
| 256 | 2018 |
Achieving ultrahigh triboelectric charge density for efficient energy harvesting | Nature Communications |
| 476 | 2017 |
Citations
| Title | Journal | Journal Categories | Citations | Publication Date |
|---|---|---|---|---|
Advanced Dielectric Materials for Triboelectric Nanogenerators: Principles, Methods, and Applications | Advanced Materials |
| 2024 | |
Rotary Wind‐driven Triboelectric Nanogenerator for Self‐Powered Airflow Temperature Monitoring of Industrial Equipment | Advanced Science |
| 3 | 2024 |
Graphene Nanoplatelet Integrated Thermally Drawn PVDF Triboelectric Nanocomposite Fibers for Extreme Environmental Conditions | Advanced Electronic Materials |
| 2024 | |
| Customizing temperature-resistant cellulosic triboelectric materials for energy harvesting and emerging applications | Nano Energy |
| 5 | 2024 |
| Review of triboelectricity-controlled fluid technologies for enhancing the lubrication performance on the coupled surface | Tribology International |
| 2024 |
Citations Analysis
The category
Science: Chemistry 35
is the most commonly referenced area in studies that cite this article. The first research to cite this article was titled Programmed-triboelectric nanogenerators—A multi-switch regulation methodology for energy manipulation and was published in 2020. The most recent citation comes from a 2024 study titled Contact-electro-catalysis (CEC). This article reached its peak citation in 2023, with 12 citations. It has been cited in 27 different journals, 7% of which are open access. Among related journals, the Nano Energy cited this research the most, with 7 citations. The chart below illustrates the annual citation trends for this article.