Your search keyword '"Keqi Qu"' showing total 4 results

1. Two-dimensional materials as sodium-ion battery anodes: The mass transfer and storage mechanisms of 'fat' Na+

Author

Yuan Shao, Yong Zhang, Na Jiang, Yuhan Hao, Keqi Qu, You Zeng, Ziqiang Liu, Xuejun Lu, Ying Li, Qi Yang, and Jieshan Qiu

Subjects

Applied sciences, Energy storage, Nanomaterials, Science

Abstract

Summary: Sodium-ion batteries (SIBs) with abundant resource and high safety are attracting intensive interest from both research and industry communities in meeting the ever-increasing energy demands. Despite the rapid advance of SIBs, it is difficult yet necessary to enhance the cycling and rate performance at anode due to the sluggish kinetics of “fat” Na+. This review provides an overview of two-dimensional (2D) nanomaterials with a short ion diffusion pathway and a superior active sites exposure from the perspectives of synthesis, material chemistry, and structure engineering. We present the design principle of ideal carbon materials in SIBs. Moreover, we discuss the structure and chemistry regulations of different 2D materials to promote the efficient ion mass transfer and storage according to the different mechanisms of alloying, conversion, and insertion. Finally, we propose the remaining challenges and the possible solutions, in hope of guiding the future development of this booming field.

Published

2023

2. Surface atom knockout for the active site exposure of alloy catalyst.

Author

Yi Ma, Qi Yang, Jun Qi, Yong Zhang, Yuliang Gao, You Zeng, Na Jiang, Ying Sun, Keqi Qu, Wenhui Fang, Ying Li, Xuejun Lu, Chunyi Zhi, and Jieshan Qiu

Subjects

ATOMS, COPPER, ALLOYS, CATALYSTS, OXYGEN reduction, MELT spinning, CATALYTIC reforming

Abstract

The fine regulation of catalysts by the atomic-level removal of inactive atoms can promote the active site exposure for performance enhancement, whereas suffering from the difficulty in controllably removing atoms using current micro/nano-scale material fabrication technologies. Here, we developed a surface atom knockout method to promote the active site exposure in an alloy catalyst. Taking Cu3Pd alloy as an example, it refers to assemble a battery using Cu3Pd and Zn as cathode and anode, the charge process of which proceeds at about 1.1 V, equal to the theoretical potential difference between Cu2+/Cu and Zn2+/Zn, suggesting the electricity-driven dissolution of Cu atoms. The precise knockout of Cu atoms is confirmed by the linear relationship between the amount of the removed Cu atoms and the battery cumulative specific capacity, which is attributed to the inherent atom-electron-capacity correspondence. We observed the surface atom knockout process at different stages and studied the evolution of the chemical environment. The alloy catalyst achieves a higher current density for oxygen reduction reaction compared to the original alloy and Pt/C. This work provides an atomic fabrication method for material synthesis and regulation toward the wide applications in catalysis, energy, and others. [ABSTRACT FROM AUTHOR]

Published

2024

3. Integrated Instillation Technology for the Synthesis of a pH-Responsive Sodium Alginate/Biomass Charcoal Soil Conditioner for Controlled Release of Humic Acid and Soil Remediation.

Author

Weicong Wang, Keqi Qu, Xinrui Zhang, Min Teng, and Zhanhua Huang

Published

2021

4. Fungus Bran-Derived Porous N‑Doped Carbon–Zinc Manganese Oxide Nanocomposite Positive Electrodes toward High-Performance Asymmetric Supercapacitors.

Author

Keqi Qu, Yue You, Houjuan Qi, Cai Shi, Zhe Sun, Zhanhua Huang, Bingnan Yuan, and Zhanhu Guo

Published

2020