Optoelectronics Letters, Volume. 17, Issue 12, 734(2021)
Simulation and analysis of polycrystalline silicon photovoltaic cells surface color differences based on transfer matrix method
[1] [1] CHAPIN D M, FULLER C S, PEARSON G L. A new silicon p-n junction photocell for converting solar radiation into electrical power[J]. Journal of applied physics, 1954, 25(5):676-677.
[2] [2] GREEN M A. The path to 25% silicon solar cell efficiency :history of silicon cell evolution[J]. Progress in photovoltaics:research and applications, 2009, 17(3): 183-189.
[3] [3] DUERINCKX F, SZLUFCIK J. Defect passivation of industrial multicrystalline solar cells based on PECVD silicon nitride[J]. Solar energy materials and solar cells, 2002, 72(1-4):231-246.
[4] [4] SELJ J H, MONGSTAD T T, SONDENA R, et al. Reduction of optical losses in colored solar cells with multilayer antireflection coatings[J]. Solar energy materials and solar cells, 2011, 95(9):2576-2582.
[5] [5] LUMB M P, YOON W, BAILEY C G, et al. Modeling and analysis of high-performance, multicolored anti-reflection coatings for solar cells[J]. Optics express, 2013, 21(S4): A585-A594.
[6] [6] JIA H, LUO L, LI B, et al. Performance of polycrystal silicon color solar cells[J]. Acta physica sinica, 2013, 62(16):487-491. (in Chinese)
[7] [7] BASHER M K, MISHAN R, BISWAS S, et al. Study and analysis the Cu nanoparticle assisted texturization forming low reflective silicon surface for solar cell application[ J]. AIP advances, 2019, 9(7):075118.
[8] [8] SOBHANI F, HEIDARZADEH H, BAHADOR H. Photocurrent improvement of an ultra-thin silicon solar cell using the localized surface plasmonic effect of clustering nanoparticles[J]. Chinese physics B, 2020, 29(6): 068401.
[9] [9] MIN S K, JU H L, KWAK M K. Review:surface texturing methods for solar cell efficiency enhancement[ J]. International journal of precision engineering and manufacturing, 2020, 21(7):1-10.
[10] [10] LU W, QIU X, ZHAO Q, et al. Enhanced optoelectronic conversion performance of nano-textured multi-crystalline silicon solar cells through optimizing emitter sheet resistivity[J]. Journal of optoelectronics?lasers, 2020, 31(7):675-681. (in Chinese)
[11] [11] DENG K, LI L. Optical design in perovskite solar cells[J]. Small methods, 2019:1900150.
[12] [12] EDWARD D P. Handbook of optical constants of solids[ M]. New York:Academic Press, 1985.
[13] [13] WANG H,: ZHU H,: FAN D,: et al. Application of transfer matrix method in the teaching of wave optics in college physics[J]. Physics and engineering, 2019, 29(05):118-122. (in Chinese)
[14] [14] CHEN Z, WANG S, ZHANG L, et al. Design and research of a color discrimination method for polycrystalline silicon cells based on laser detection system[J]. Applied sciences, 2019, 9(20):4468.
[15] [15] Photovoltaic devices - Part 3:Measurement principles for terrestrial photovoltaic (PV) solar devices with reference spectral irradiance data:IEC 60904-3:2019[S/OL]. [2019-02-15]. http://webstore.iec.ch/public ation/64682# additionalinfo.
Get Citation
Copy Citation Text
CHEN Zijian, MA Zenghong, JIA Haoyuan, ZHANG Lian, SUN Yan, WANG Shiyu. Simulation and analysis of polycrystalline silicon photovoltaic cells surface color differences based on transfer matrix method[J]. Optoelectronics Letters, 2021, 17(12): 734
Received: Jul. 4, 2021
Accepted: Aug. 26, 2021
Published Online: Jan. 10, 2022
The Author Email: Zijian CHEN (492680311@qq.com)