The Distribution of Chromium in Multicrystalline Silicon

被引:0
|
作者
Jensen, Mallory Ann [1 ]
Hofstetter, Jasmin [1 ]
Fenning, David P. [1 ]
Morishige, Ashley E. [1 ]
Coletti, Gianluca [2 ]
Lai, Barry [3 ]
Buonassisi, Tonio [1 ]
机构
[1] MIT, Cambridge, MA 02139 USA
[2] ECN Solar Energy, NL-1755 LE Petten, Netherlands
[3] Argonne Natl Lab, Adv Photon Source, Argonne, IL 60439 USA
来源
2014 IEEE 40TH PHOTOVOLTAIC SPECIALIST CONFERENCE (PVSC) | 2014年
关键词
chromium; synchrotron-based micro-X-ray fluorescence; photovoltaics; precipitation; multicrystalline silicon;
D O I
暂无
中图分类号
TE [石油、天然气工业]; TK [能源与动力工程];
学科分类号
0807 ; 0820 ;
摘要
Metallic impurities such as chromium form Shockley-Read-Hall recombination centers in both p- and n-type silicon, limiting minority-carrier lifetimes and reducing solar cell efficiencies. Much effort has been focused on understanding the distribution and evolution of iron-silicide precipitates during phosphorous diffusion gettering. As interest in n-type silicon grows, other impurities including chromium require similar attention. We elucidate the spatial distribution of chromium-rich particles in intentionally-contaminated multicrystalline silicon using micro-X-ray fluorescence. We find that observed chromium-rich particles are, on average, smaller and in lower density than observed iron-rich particles, likely because of the lower Cr solubility and diffusivity compared to Fe. These experimental observations could enable more accurate modeling of the behavior of chromium in silicon.
引用
收藏
页码:2938 / 2940
页数:3
相关论文
共 50 条
  • [31] Growth optimization of multicrystalline silicon
    Moeller, H. J.
    Funke, C.
    Kressner-Kiel, D.
    Wuerzner, S.
    EMRS-C: MATERIALS DEVICES AND ECONOMICS ISSUES FOR TOMORROW'S PHOTOVOLTAICS, 2011, 3
  • [32] Hall mobility in multicrystalline silicon
    Schindler, F.
    Geilker, J.
    Kwapil, W.
    Warta, W.
    Schubert, M. C.
    JOURNAL OF APPLIED PHYSICS, 2011, 110 (04)
  • [33] Recombination and trapping in multicrystalline silicon
    Cuevas, A
    Stocks, M
    Macdonald, D
    Kerr, M
    Samundsett, C
    IEEE TRANSACTIONS ON ELECTRON DEVICES, 1999, 46 (10) : 2026 - 2034
  • [34] Origin of trapping in multicrystalline silicon
    Gundel, Paul
    Schubert, Martin C.
    Warta, Wilhelm
    JOURNAL OF APPLIED PHYSICS, 2008, 104 (07)
  • [35] Effect of the Silicon Nitride Coating of Quartz Crucible on Impurity Distribution in Ingot-Cast Multicrystalline Silicon
    Li, Jiayan
    Liu, Mei
    Tan, Yi
    Wen, Lishi
    INTERNATIONAL JOURNAL OF APPLIED CERAMIC TECHNOLOGY, 2013, 10 (01) : 40 - 44
  • [36] Multicrystalline silicon assisted by polycrystalline silicon slabs as seeds
    Huang, Chunlai
    Zhang, Huali
    Yuan, Shuai
    Wu, Yihua
    Zhang, Xinhao
    You, Da
    Wang, Lei
    Yu, Xuegong
    Wan, Yuepeng
    Yang, Deren
    SOLAR ENERGY MATERIALS AND SOLAR CELLS, 2018, 179 : 312 - 318
  • [37] High-performance Multicrystalline Silicon Ingots Assisted by Recycled Multicrystalline Silicon Block Tailing as Seeds
    Yunfei Xu
    Liang He
    Qi Lei
    Hongzhi Luo
    Cheng Zhou
    Wei Mao
    Xiaojuan Cheng
    Jianmin Li
    Guifu Zou
    Silicon, 2021, 13 : 1641 - 1646
  • [38] Acidic texturing of multicrystalline silicon wafers
    Marstein, ES
    Solheim, HJ
    Wright, DN
    Holt, A
    CONFERENCE RECORD OF THE THIRTY-FIRST IEEE PHOTOVOLTAIC SPECIALISTS CONFERENCE - 2005, 2005, : 1309 - 1312
  • [39] High-performance Multicrystalline Silicon Ingots Assisted by Recycled Multicrystalline Silicon Block Tailing as Seeds
    Xu, Yunfei
    He, Liang
    Lei, Qi
    Luo, Hongzhi
    Zhou, Cheng
    Mao, Wei
    Cheng, Xiaojuan
    Li, Jianmin
    Zou, Guifu
    SILICON, 2021, 13 (05) : 1641 - 1646
  • [40] Understanding the distribution of iron in multicrystalline silicon after emitter formation: Theoretical model and experiments
    Schoen, J.
    Habenicht, H.
    Schubert, M. C.
    Warta, W.
    JOURNAL OF APPLIED PHYSICS, 2011, 109 (06)
12345