High-temperature solar cell for concentrated solar-power hybrid systems

被引:20
|
作者
Yang, Yang [1 ]
Yang, Wenzheng [1 ]
Tang, Weidong [1 ]
Sun, Chuandong [1 ]
机构
[1] Chinese Acad Sci, Xian Inst Opt & Precis Mech, State Key Lab Transient Opt & Photon, Xian 710119, Peoples R China
来源
APPLIED PHYSICS LETTERS | 2013年 / 103卷 / 08期
关键词
PERFORMANCE; EFFICIENCY;
D O I
10.1063/1.4819201
中图分类号
O59 [应用物理学];
学科分类号
摘要
A high-temperature solar cell is proposed that harvests solar energy at elevated temperatures. Carrier separation is achieved by selective contacts that preferentially extract electrons or holes. The theoretical conversion efficiency of the proposed device is 38.6% at 600K and an incident solar radiation concentration of 1000. The waste heat of this cell could be used by a secondary thermal converter boosting the total efficiency of the hybrid system above 55%. (C) 2013 AIP Publishing LLC.
引用
收藏
页数:5
相关论文
共 50 条
  • [31] Phase change material with graphite foam for applications in high-temperature latent heat storage systems of concentrated solar power plants
    Zhao, Weihuan
    France, David M.
    Yu, Wenhua
    Kim, Taeil
    Singh, Dileep
    [J]. RENEWABLE ENERGY, 2014, 69 : 134 - 146
  • [32] Selection of a molten salt mixture for thermal storage in high temperature concentrated solar power systems
    Kim, Young
    Yoon, Seok Ho
    Choi, Jun Seok
    Noh, Yundo
    Kim, Dong Ho
    Song, Chan Ho
    [J]. HIGH TEMPERATURES-HIGH PRESSURES, 2016, 45 (5-6) : 461 - 469
  • [33] Optimizing Concentrated Solar Power: High-Temperature Molten Salt Thermal Energy Storage for Enhanced Efficiency
    Boretti, Alberto
    [J]. ENERGY STORAGE, 2024, 6 (07)
  • [34] Assessing the prospective environmental performance of hydrogen from high-temperature electrolysis coupled with concentrated solar power
    Puig-Samper, Gonzalo
    Bargiacchi, Eleonora
    Iribarren, Diego
    Dufour, Javier
    [J]. RENEWABLE ENERGY, 2022, 196 : 1258 - 1268
  • [35] Development of a High-Band Gap High Temperature III-Nitride Solar Cell for Integration with Concentrated Solar Power Technology
    Williams, Joshua J.
    McFavilen, Heather
    Fischer, Alec M.
    Ding, Ding
    Young, Steven R.
    Vadiee, Ehsan
    Ponce, Fernando A.
    Arena, Chantal
    Honsberg, Christiana B.
    Goodnick, Stephen M.
    [J]. 2016 IEEE 43RD PHOTOVOLTAIC SPECIALISTS CONFERENCE (PVSC), 2016, : 193 - 195
  • [36] Solar 'tower reflector' systems: A new approach for high-temperature solar plants
    Yogev, A
    Epstein, M
    Kogan, A
    Kribus, A
    [J]. HYDROGEN ENERGY PROGRESS XI, VOLS 1-3, 1996, : 467 - 477
  • [37] Solar "tower reflector" systems: A new approach for high-temperature solar plants
    Yogev, A
    Kribus, A
    Epstein, M
    Kogan, A
    [J]. INTERNATIONAL JOURNAL OF HYDROGEN ENERGY, 1998, 23 (04) : 239 - 245
  • [38] High-temperature stable spinel nanocomposite solar selective absorber coating for concentrated solar thermal application
    Atchuta, S. R.
    Barshilia, Harish C.
    Sakthivel, S.
    [J]. PROCEEDINGS OF THE ISES SOLAR WORLD CONFERENCE 2019 AND THE IEA SHC SOLAR HEATING AND COOLING CONFERENCE FOR BUILDINGS AND INDUSTRY 2019, 2019, : 4 - 7
  • [39] WHATEVER HAPPENED TO SOLAR-POWER SATELLITES
    不详
    [J]. IEEE SPECTRUM, 1983, 20 (07) : 22 - 22
  • [40] Solar hydrogen production: Technoeconomic analysis of a concentrated solar-powered high-temperature electrolysis system
    Muhammad, Hafiz Ali
    Naseem, Mujahid
    Kim, Jonghwan
    Kim, Sundong
    Choi, Yoonseok
    Lee, Young Duk
    [J]. ENERGY, 2024, 298
12345