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Improved Conversion Efficiency of GaN/InGaN Thin-Film Solar Cells
IEEE Electron Device Letters (July 2009), 30 (7), pg. 724-726 
 Ray-Hua Horng;  Shih-Ting Lin;  Yu-Li Tsai;  Mu-Tao Chu;  Wen-Yih Liao;  Ming-Hsien Wu;  Ray-Ming Lin;  Yuan-Chieh Lu

wafer bonding |  current density |  gallium compounds |  III-V semiconductors |  indium compounds |  laser materials processing |  photoconductivity |  semiconductor thin films |  solar cells |  thin film devices |  GaN-InGaN |  thin-film solar cells |  photovoltaic characteristics |  laser lift-off technique |  p-i-n structure |  mirror-coated substrate |  wafer bonding |  light absorption |  thin absorption layer |  enhancement factor |  current density |  conversion efficiency |  photocurrent enhancement |  light multireflection |  Gallium nitride |  Transistors |  Photovoltaic cells |  PIN photodiodes |  Mirrors |  Absorption |  Optical device fabrication |  Photovoltaic systems |  Solar power generation |  Semiconductor thin films |  wafer bonding |  Laser lift-off |  thin-film solar cell
 

In this letter, we report on the fabrication and photovoltaic characteristics of p-i-n GaN/InGaN thin-film solar cells. The thin-film solar cells were fabricated by removing sapphire using a laser lift-off technique and, then, transferring the remaining p-i-n structure onto a Ti/Ag mirror-coated Si substrate via wafer bonding. The mirror structure is helpful to enhance light absorption for a solar cell with a thin absorption layer. After the thin-film process for a conventional sapphire-based p-i-n solar cell, the device exhibits an enhancement factor of 57.6% in current density and an increment in conversion efficiency from 0.55% to 0.80%. The physical origin for the photocurrent enhancement in the thin-film solar cell is related to multireflection of light by the mirror structure.


   

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Improved Conversion Efficiency of GaN/InGaN Thin-Film Solar Cells