搜索结果: 1-15 共查到“Energy Storage”相关记录36条 . 查询时间(0.453 秒)
与插层型锂离子电池(LIB)相比,转换型锂硫(Li-S)电池因为其高理论能量密度(2600 Wh kg-1)而受到越来越多的关注。但是,多硫化物穿梭效应、缓慢的反应动力学和锂金属枝晶生长等问题阻碍了锂硫电池的进一步应用。硫正极的多步转化反应涉及电极/电解质之间一系列Li+的交换,这些反应也亟需克服脱溶剂和电荷载体扩散的能量势垒,这导致了缓慢的转化动力学以及多硫化物中间体的积累。
近日,潍坊学院化学化工与环境工程学院杨帆博士与四川大学材料科学与工程学院傅雪薇副教授合作,在Energy Storage Materials期刊上发表了题为Fibrous materials for interface engineering in durable and shape-customizable lithium metal batteries的学术论文,Energy Storage ...
Academy of Mathematics and Systems Science, CAS Colloquia & Seminars:Computation and Design of Electrochemical Energy Storage Materials
电化学 储能材料 计算设计
2023/4/25
The key to electrochemical energy storage systems such as Li/Na-ion batteries is materials. The traditional method for exploring new materials is trial-and-error, which often takes a dozen years durin...
电子设备和电动汽车日益增长的需求激发了人们对获取高能量密度电池的兴趣。锂金属电池(LMBs)具有超高的理论容量(3860mA h g-1)和极低的相对电势(-3.04 V vs. SHE),将引领下一代可充电电池的发展方向。然而,锂金属表面离子通量分布不均匀、体积变化、固体电解质界面相(SEI)不稳定导致锂枝晶生长不可控,库仑效率且锂利用率较低,甚至存在严重的安全问题。更重要的是,金属锂负极的工业...
力工学院鲍垠桦副教授在国际高水平学术期刊《Energy Storage Materials》上发表高能量密度柔性锂离子电池最新研究成果(图)
高能量 柔性锂离子电池 高水平学术期刊 固态电池
2022/5/26
近日,力学与工程科学学院鲍垠桦副教授与上海大学双聘院士、中国科学院院士、北京理工大学方岱宁教授,力学与工程科学学院吕浡,宋亦诚,张俊乾教授等人合作,在高能量密度柔性锂离子电池方面取得重要研究进展。研究成果以“Crocodile skin inspired rigid-supple integrated flexible lithium ion batteries with high energy ...
An energy-storage solution that flows like soft-serve ice cream(图)
储能解决方案 半固体 电化学化合物 风能 太阳能
2023/6/19
Batteries made from an electrically conductive mixture the consistency of molasses could help solve a critical piece of the decarbonization puzzle. An interdisciplinary team from MIT has found that an...
Cornell bioengineer Buz Barstow, Ph.D. ’09, is trying to solve a big problem: How to build a low-cost, environmentally friendly and large-scale system for storing and retrieving energy from renewable ...
The transition toward a more sustainable, environmentally sound electrical grid has driven an upsurge in renewables like solar and wind. But something as simple as cloud cover can cause grid instabili...
上海交通大学制冷与低温工程研究所在Energy Storage Materials发表“吸附储热技术:概念、过程、应用和展望”综述论文(图)
吸附储热技术 新型多孔材料 双模式闭式跨季节储热系统 两级溶液吸收系统
2022/4/18
近日,上海交通大学制冷与低温工程研究所王如竹教授领衔的能源-空气-水(ITEWA)创新团队,在Energy Storage Materials上发表了题目为“Sorption Thermal Energy Storage: Concept, Process, Applications and Perspectives”的综述论文,总结了吸附储热技术在材料、工作循环、系统设计和系统运新特性等方面的研...
上海交通大学制冷与低温工程研究所在Energy Storage Materials发表研究论文,阐释空气湿度驱动的吸附热池的稳定输出机理(图)
空气湿度驱动 吸附热池 双床吸附热池 反应波模型
2022/4/18
2020年1月22日,王如竹教授领导的能源-空气-水(ITEWA)创新团队,在Energy Storage Materials上发表了题目为“Air Humidity Assisted Sorption Thermal Battery Governed by Reaction Wave Model”的研究论文,发现吸附反应床内的反应波现象并提出反应波模型,阐释了吸附热池实现稳定输出的机理,以及新型...
Nanocellulose for Energy Storage Systems: Beyond the Limits of Synthetic Materials
bacterial cellulose cellulose nanocrystals cellulose nanofibrils energy storage systems nanocellulose
2024/3/8
The ongoing surge in demand for high-performance energy storage systems inspires the relentless pursuit of advanced materials and structures. Components of energy storage systems are generally based o...
近日,材料学院慈立杰教授课题组在高性能钾离子电池负极材料研究方面取得重要进展,相关研究成果以“Hierarchically porous carbon supported Sn4P3as a superior anode material for potassium-ion batteries”为题发表在能源材料类重要刊物Energy Storage Materials(2019,https://...
Energy storage solution combines polymers and nanosheets(图)
energy storage solution polymers nanosheets
2017/9/1
A new, lightweight composite material for energy storage in flexible electronics, electric vehicles and aerospace applications has been experimentally shown to store energy at operating temperatures w...
Entering the Fast Lane—MXene Electrodes Push Charging Rate Limits in Energy Storage
Entering the Fast Lane MXene Electrodes Charging Rate Limits Energy Storage
2017/7/24
Can you imagine fully charging your cell phone in just a few seconds? Researchers in Drexel University’s College of Engineering can, and they took a big step toward making it a reality with their rece...
2017年充电储能高容量电极材料研讨会(Symposium ES2—High-Capacity Electrode Materials for Rechargeable Energy Storage)
2017 充电储能 高容量电极材料 研讨会
2017/2/16
High-performance rechargeable batteries are essential for a wide variety of applications including portable electronics, electric vehicles, grid-level energy storage, and defense purposes. To realize ...