基本信息
浏览量:10
职业迁徙
个人简介
RESEARCH INTERESTS
Microbatteries: With the rise of the Internet of Things, the trends shaping the world of microelectronics are clear—miniaturization, flexibility, and integration are at the forefront. Notably, various microelectronic devices, ranging from wearables and implants to micro-robots and micro-sensors, have made remarkable strides and are poised to become integral parts of our daily lives. These tiny devices excel at intricate tasks like data processing and wireless signal transmission, promising significant advancements in fields such as health monitoring, medical diagnosis, and disease treatment. However, to enable the seamless operation of these devices, a critical component is the energy supply unit. My research focuses on the development of microscale batteries known as Micro-batteries, with a specific emphasis on 3D electrode designs aimed at enhancing energy storage performance within the constrained footprint of microscale devices.
Aqueous rechargeable batteries: Lithium-ion batteries have emerged as the predominant energy storage systems today, finding applications across a wide spectrum, from automobiles to personal gadgets, owing to their high energy density and lightweight properties. However, concerns regarding their availability, cost-effectiveness, and safety have led to a demand for cost-effective and safer alternatives in certain applications, such as mini-grid and off-grid energy storage. Among these alternatives, Zn-ion batteries stand out as promising candidates due to their high capacity, environmental safety and cost-effectiveness. Our research endeavors are centered on the development of 3D cathodes for Zn-ion batteries and the mitigation of Zn dendrite growth on Zn anodes.
Photo-accelerated batteries: Some battery materials exhibit semiconductive properties and are optically active, generating photocurrent when exposed to light. My research delves into the understanding of the interaction between light and semiconducting battery materials during the charge storage process. Furthermore, it involves the design of photoelectrode materials that facilitate efficient charge transfer. These systems can operate in a "photo-accelerated" mode, enabling faster charging capabilities and continuous power generation, even in discharge conditions under light illumination.
Microbatteries: With the rise of the Internet of Things, the trends shaping the world of microelectronics are clear—miniaturization, flexibility, and integration are at the forefront. Notably, various microelectronic devices, ranging from wearables and implants to micro-robots and micro-sensors, have made remarkable strides and are poised to become integral parts of our daily lives. These tiny devices excel at intricate tasks like data processing and wireless signal transmission, promising significant advancements in fields such as health monitoring, medical diagnosis, and disease treatment. However, to enable the seamless operation of these devices, a critical component is the energy supply unit. My research focuses on the development of microscale batteries known as Micro-batteries, with a specific emphasis on 3D electrode designs aimed at enhancing energy storage performance within the constrained footprint of microscale devices.
Aqueous rechargeable batteries: Lithium-ion batteries have emerged as the predominant energy storage systems today, finding applications across a wide spectrum, from automobiles to personal gadgets, owing to their high energy density and lightweight properties. However, concerns regarding their availability, cost-effectiveness, and safety have led to a demand for cost-effective and safer alternatives in certain applications, such as mini-grid and off-grid energy storage. Among these alternatives, Zn-ion batteries stand out as promising candidates due to their high capacity, environmental safety and cost-effectiveness. Our research endeavors are centered on the development of 3D cathodes for Zn-ion batteries and the mitigation of Zn dendrite growth on Zn anodes.
Photo-accelerated batteries: Some battery materials exhibit semiconductive properties and are optically active, generating photocurrent when exposed to light. My research delves into the understanding of the interaction between light and semiconducting battery materials during the charge storage process. Furthermore, it involves the design of photoelectrode materials that facilitate efficient charge transfer. These systems can operate in a "photo-accelerated" mode, enabling faster charging capabilities and continuous power generation, even in discharge conditions under light illumination.
研究兴趣
论文共 48 篇作者统计合作学者相似作者
按年份排序按引用量排序主题筛选期刊级别筛选合作者筛选合作机构筛选
时间
引用量
主题
期刊级别
合作者
合作机构
Yujia Fan,Tianlei Wang, Rica Asrosa, Bing Li, Nibagani Naresh, Xiaopeng Liu, Shaoliang Guan, Ruixiang Li,Mingqing Wang,Ivan P. Parkin,Buddha Deka Boruah
Chemical Engineering Journalpp.150672, (2024)
SMALLno. 14 (2024): e2308869-e2308869
Chemical Engineering Journal (2024): 150384
Xueqing Hu,Joanna Borowiec, Yijia Zhu, Xiaopeng Liu, Ruiqi Wu,Alex M. Ganose,Ivan P. Parkin,Buddha Deka Boruah
SMALLpp.e2306827-e2306827, (2023)
引用0浏览0WOS引用
0
0
加载更多
作者统计
合作学者
合作机构
D-Core
- 合作者
- 学生
- 导师
数据免责声明
页面数据均来自互联网公开来源、合作出版商和通过AI技术自动分析结果,我们不对页面数据的有效性、准确性、正确性、可靠性、完整性和及时性做出任何承诺和保证。若有疑问,可以通过电子邮件方式联系我们:report@aminer.cn