DocumentCode
1990799
Title
Fabrication and simulation of antireflective nanostructures on c-Si solar cells
Author
Kao, Ming-Hsuan ; Chen, Ting-Gang ; Tsai, Min-An ; Chen, Hsin-Chu ; Lai, Fang-I ; Kuo, Shou-Yi ; Yu, Pei-Chen ; Kuo, Hao-Chung
Author_Institution
Dept. of Photonics Eng., Yuan Ze Univ., Taoyuan, Taiwan
fYear
2011
fDate
Aug. 28 2011-Sept. 1 2011
Firstpage
1529
Lastpage
1531
Abstract
The enhanced photoelectric conversion is demonstrated in nanostructured photovoltaics using colloidal lithography and reactive-ion-etching (RIE) techniques. From the reflectance spectroscopy, trapezoid-cone arrays (TCAs) Si with SiNx passivation layer effectively suppress the reflection in the wavelength range from 400 nm to 1000 nm. The power conversion shows the TCAs Si solar cell with 120 nm thickness of SiNx passivation layer achieves 13.736%, which is 8.87% and 2.56% enhancement compared to the conventional KOH-textured photovoltaics and TCAs with 80-nm-thick SiNx, respectively. An optical simulation based on RCWA describes the optimized shape of nano structure to further reduce reflectance for maximum light absorption.
Keywords
colloidal crystals; elemental semiconductors; light absorption; nanofabrication; nanolithography; nanostructured materials; passivation; photovoltaic effects; power conversion; silicon; silicon compounds; sputter etching; RIE techniques; Si; SiNx; antireflective nanostructures; c-Si solar cells; colloidal lithography; conventional textured photovoltaics; enhanced photoelectric conversion; maximum light absorption; nanostructured photovoltaics; optical simulation; optimized shape; passivation layer; power conversion; reactive-ion-etching techniques; reflectance spectroscopy; size 120 nm; trapezoid-cone arrays; wavelength 400 nm to 1000 nm; Current density; Nanostructures; Photovoltaic cells; Reflectivity; Silicon; Surface treatment; Surface waves;
fLanguage
English
Publisher
ieee
Conference_Titel
Quantum Electronics Conference & Lasers and Electro-Optics (CLEO/IQEC/PACIFIC RIM), 2011
Conference_Location
Sydney, NSW
Print_ISBN
978-1-4577-1939-4
Type
conf
DOI
10.1109/IQEC-CLEO.2011.6193978
Filename
6193978
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