双叠层硅基薄膜光伏电池性能的理论模拟任务书
2020-05-01 08:48:26
1. 毕业设计(论文)的内容和要求
非晶硅薄膜太阳能电池经过将近40年的发展有了长足的进步。
最初,非晶硅太阳电池商业应用的问题是光致衰退效应(s-w效应)比较严重和能量转换效率偏低。
1994年瑞士imt的meier首次提出了非晶/微晶双叠层硅基薄膜光伏电池的概念,使电池在提高效率和稳定性上有了很大的改进。
2. 参考文献
[1] Spear W E, Lecomber P G. Substitutional doping of amorphous silicon[J]. Solid State Communications, 1975, 17: 1193-1196. [2] Carlson D E. Recent developments in amorphous silicon solar cells[J]. Solar Energy Materials, 1980, 3: 503-518. [3] Meier J, Fluckiger F, Keppner H, et al. Complete microcrystalline p-i-n solar cell - crystalline or amorphous cell behavior[J]. Applied Physics Letters, 1994, 65: 860-862. [4] Meier J, Dubail S, Cuperus J, et al. Recent progress in micromorph solar cell[J]. Non-Cryst Solids, 1998, 227-230: 1250. [5] Fischer D, Dubail S, Selvan J A, et al. The micromorph solar cells extending a-Si:H technology towards thin film crystalline silicon[J]. Proc. of 25th IEEE Photovoltaic Specialists Conference, IEEE New York, 1996: 1053. [6] Repmann T, Sehrbrock B, Zahren C, et al. Microcrystalline silicon thin film solar modules on glass[J]. Solar Energy Materials and Solar Cells, 2006, 18, 3004-3053. [7] Meier J, Dubail S, Fluckiger R, et al. Intrinsic microcrystalline silicon (μc-Si:H)- a promising new thin film solar cell material[A]. Hawaii:IEEE, 1994: 409-412. [8] Pellaton V N, Nagel J L, Platz R. Controlled nucleation of thin microcrystalline layers for the recombination junction in a-Si stacked cells[A]. Proc.2nd WCPEC[C]. Vienna, 1998, 728-731. [9] Shah A V, Bailat J, Vallat S E, et al. Microcrystalline and micromorph solar cells and modules: status and potential[A]. Proc. 31st IEEE PSC[C]. Osaka, 2005, 1353-1358. [10] Yamamoto K, Yoshimi M, Tawada Y, et al. Large area thin film Si module[J]. Solar Energy Materials Solar Cells, 2002, 74: 449-455. [11] Yang J, Banerjee A, and Guha S. Triple-junction amorphous silicon alloy solar cell with 14.6 % initial and 13.0 % stable conversion efficiencies[J]. Applied Physics Letters, 1997, 70: 2975-2977. [12] Kabir M I, Seyed A S, Victor L, et al. Amorphous silicon single-junction thin-film solar cell exceeding 10 % efficiency by design optimization[J], International Journal of Photoenergy, 2012, 2012:1-7. [13] Kabir M I, Zahari I, Kamaruzzaman S, et al. Effect of structural variations in amorphous silicon based single and multi-junction solar cells from numerical analysis[J]. Solar Energy Materials Solar Cells, 2010, 94: 1542-1545. [14] Vukadinovic M, Smole F, Schropp R E I, et al. Transport in tunneling recombination junctions: a combined computer simulation study[J]. Journal of Applied Physics, 2004, 96, 7289-7299. [15] Ihsanul A Y, Kobsak S, Shuichi H, et al. Effects of temperature and spectral irradiance on performance of silicon-based thin film multijunction solar cells[J]. Japanese Journal of Applied Physics, 2007, 46, 1398-1403. [16] Ihsanul A Y, Akira Y, Makoto K. Theoretical analysis of amorphous silicon alloy based triple junction solar cells[J]. Japanese Journal of Applied Physics, 2007, 46, 1152#8211;1154. [17] 张勇, 刘艳, 吕斌, 等, 前端接触势垒高度对非晶硅和微晶硅异质结太阳电池的影响[J], 物理学报, 2009, 58: 2829-2834.
3. 毕业设计(论文)进程安排
2018.12.17-2019.1.11, 文献调研,完成开题报告 1.12-1.18, 完成英文翻译 2.25-4.7, 深刻理解双叠层硅基薄膜电池原理,学习和掌握AMPS-1D 4.8-5.5, 进行模拟、初步分析结果和中期检查 5.6-5.26, 进一步完善模拟结果,并分析全部数据 5.27-6.2, 论文撰写 6.3-6.6, 论文修改 6.7-6.10, 准备PPT,答辩