Your search keyword '"Han, Jiajia"' showing total 3 results

1. Resolving the Origins of Superior Cycling Performance of Antimony Anode in Sodium‐ion Batteries: A Comparison with Lithium‐ion Batteries.

Author

Shao, Ruiwen, Sun, Zhefei, Wang, Lei, Pan, Jianhai, Yi, Luocai, Zhang, Yinggan, Han, Jiajia, Yao, Zhenpeng, Li, Jie, Wen, Zhenhai, Chen, Shuangqiang, Chou, Shu‐Lei, Peng, Dong‐Liang, and Zhang, Qiaobao

Subjects

ALUMINUM-lithium alloys, LITHIUM-ion batteries, CYCLING, SODIUM ions, ANTIMONY, ANODES, CYCLING competitions

Abstract

Alloying‐type antimony (Sb) with high theoretical capacity is a promising anode candidate for both lithium‐ion batteries (LIBs) and sodium‐ion batteries (SIBs). Given the larger radius of Na+ (1.02 Å) than Li+ (0.76 Å), it was generally believed that the Sb anode would experience even worse capacity degradation in SIBs due to more substantial volumetric variations during cycling when compared to LIBs. However, the Sb anode in SIBs unexpectedly exhibited both better electrochemical and structural stability than in LIBs, and the mechanistic reasons that underlie this performance discrepancy remain undiscovered. Here, using substantial in situ transmission electron microscopy, X‐ray diffraction, and Raman techniques complemented by theoretical simulations, we explicitly reveal that compared to the lithiation/delithiation process, sodiation/desodiation process of Sb anode displays a previously unexplored two‐stage alloying/dealloying mechanism with polycrystalline and amorphous phases as the intermediates featuring improved resilience to mechanical damage, contributing to superior cycling stability in SIBs. Additionally, the better mechanical properties and weaker atomic interaction of Na−Sb alloys than Li−Sb alloys favor enabling mitigated mechanical stress, accounting for enhanced structural stability as unveiled by theoretical simulations. Our finding delineates the mechanistic origins of enhanced cycling stability of Sb anode in SIBs with potential implications for other large‐volume‐change electrode materials. [ABSTRACT FROM AUTHOR]

Published

2024

2. Unraveling the Origin of Enhanced K+ Storage of Carbonaceous Anodes Enabled by Nitrogen/Sulfur Co‐Doping.

Author

Zhang, Hehe, Chen, Zhilin, Sun, Zhefei, Cai, Mengting, Liu, Weicheng, Ye, Weibin, Gao, Haowen, Han, Jiajia, Cheng, Yong, Zhang, Qiaobao, and Wang, Ming‐Sheng

Subjects

ANODES, SULFUR, CATALYSIS, STRUCTURAL stability, ENERGY storage, NITROGEN

Abstract

N‐doped carbons, as promising anode materials for energy storage, are generally modified by the additional heteroatoms (B, P, and S) doping to further promote the electrochemical performance. However, the promotion mechanism by such additional doping, especially its interplay with N‐containing species, remains unclear. Herein, by adopting N/S co‐doped carbon as a model system, it is found that S‐doping can significantly improve the content of pyridinic‐N, i.e., the most energetically favorable N type for K+ storage. Theoretical calculations reveal that such S‐induced pyridinic‐N improvement possibly originates from its catalytic effect that can facilitate the transition from edge quaternary‐N to pyridinic‐N. The resultant high content of pyridinic‐N, together with the additional S species, ensures abundant active sites for K+ storage. Accordingly, the N/S co‐doped carbon anode delivers both a high reversible capacity (422.9 mA h g−1 at 0.05 A g−1) and an impressive cyclic stability (249.6 mA h g−1 at 1 A g−1 over 4000 cycles). Moreover, in/ex situ characterizations further verify the merits of N/S co‐doped carbon from the perspective of compositional evolution and structural stability. This study unravels the origin of enhanced K+ storage by N/S co‐doping, which also helps to understand the synergistic effects of other heteroatoms co‐doping systems. [ABSTRACT FROM AUTHOR]

Published

2023

3. Designing and Understanding the Superior Potassium Storage Performance of Nitrogen/Phosphorus Co‐Doped Hollow Porous Bowl‐Like Carbon Anodes.

Author

Chen, Jiamin, Cheng, Yong, Zhang, Qiaobao, Luo, Chong, Li, Hong‐Yang, Wu, Ying, Zhang, Hehe, Wang, Xiang, Liu, Haodong, He, Xin, Han, Jiajia, Peng, Dong‐Liang, Liu, Meilin, and Wang, Ming‐Sheng

Subjects

POTASSIUM, ANODES, RAMAN microscopy, TRANSMISSION electron microscopy, POTASSIUM ions, PHOSPHORUS

Abstract

Potassium‐ion batteries (PIBs) are promising alternatives to lithium‐ion batteries because of the advantage of abundant, low‐cost potassium resources. However, PIBs are facing a pivotal challenge to develop suitable electrode materials for efficient insertion/extraction of large‐radius potassium ions (K+). Here, a viable anode material composed of uniform, hollow porous bowl‐like hard carbon dual doped with nitrogen (N) and phosphorus (P) (denoted as N/P‐HPCB) is developed for high‐performance PIBs. With prominent merits in structure, the as‐fabricated N/P‐HPCB electrode manifests extraordinary potassium storage performance in terms of high reversible capacity (458.3 mAh g−1 after 100 cycles at 0.1 A g−1), superior rate performance (213.6 mAh g−1 at 4 A g−1), and long‐term cyclability (205.2 mAh g−1 after 1000 cycles at 2 A g−1). Density‐functional theory calculations reveal the merits of N/P dual doping in favor of facilitating the adsorption/diffusion of K+ and enhancing the electronic conductivity, guaranteeing improved capacity, and rate capability. Moreover, in situ transmission electron microscopy in conjunction with ex situ microscopy and Raman spectroscopy confirms the exceptional cycling stability originating from the excellent phase reversibility and robust structure integrity of N/P‐HPCB electrode during cycling. Overall, the findings shed light on the development of high‐performance, durable carbon anodes for advanced PIBs. [ABSTRACT FROM AUTHOR]

Published

2021