Guangdong University of Technology Materials and Energy Science courtyard
Professor Li Na’s Research Group
Professor Biography:
Li Na is an associate professor at the School of Materials and Energy of Guangdong University of Technology. To date, she has published 22 SCI papers in leading international journals such as Nano Letters, Nano Energy, and ACS Nano, all classified in JCR Zone 1. Among these, three have an impact factor (IF) of 10 or higher, and seven have an IF of 7 or higher. One paper was featured in a special report by the global science and technology news platform PHYS.org. Her work has been cited a total of 236 times in prestigious journals in the materials and energy-storage fields, including Advanced Materials, Nano Letters, Nature Communications, Energy & Environmental Science, and Advanced Energy Materials, with a single paper receiving up to 48 citations. She currently leads one project funded by the National Natural Science Foundation of China’s Young Scientists Fund and one project funded by the Guangdong Provincial Natural Science Foundation.
Paper Introduction:
The paper “Plasma-Promoted Surface-Regulation of A Novel Integrative Carbon Network For Boosting the Rate and Cycle Capability of Sodium-Ion Storage” by Professor Li Na’s research group at Guangdong University of Technology has been published in Carbon, a top-tier journal with an impact factor of 9.594. This paper was awarded the First Prize under our company’s Paper Award Program.
Central Instruments:
The PECVD system used in this paper was supplied by Tianjin Zhonghuan Electric Furnace Co., Ltd., which is specifically acknowledged in the manuscript. We would like to express our gratitude to the faculty for their recognition of Tianjin Zhonghuan Instruments. Tianjin Zhonghuan remains committed to supporting researchers in their scientific investigations and technological innovations.
Equipment Introduction:
A PECVD system uses radio frequency to ionize gases containing the atoms that constitute the thin film, thereby generating a localized plasma. The plasma is highly chemically reactive and readily undergoes reactions, leading to the deposition of the desired thin film on the substrate. This technique is suitable for the preparation of two-dimensional materials, graphene growth, TMDs synthesis, thin-film fabrication, and the growth of nanostructures, among other applications.
For more product information, please visit the official website of Tianjin Zhonghuan Electric Furnace: http://www.ctjzh.com/
