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http://dx.doi.org/10.1016/j.cap.2018.07.004

Potential of chemical rounding for the performance enhancement of pyramid textured p-type emitters and bifacial n-PERT Si cells  

Song, Inseol (KU-KIST Green School, Graduate School of Energy and Environment, Korea University)
Lee, Hyunju (Toyota Technological Institute)
Lee, Sang-Won (Department of Materials Science and Engineering, Korea University)
Bae, Soohyun (Department of Materials Science and Engineering, Korea University)
Hyun, Ji Yeon (Department of Materials Science and Engineering, Korea University)
Kang, Yoonmook (KU-KIST Green School, Graduate School of Energy and Environment, Korea University)
Lee, Hae-Seok (KU-KIST Green School, Graduate School of Energy and Environment, Korea University)
Ohshita, Yoshio (Toyota Technological Institute)
Ogurad, Atsushi (School of Science and Technology, Meiji University)
Kim, Donghwan (KU-KIST Green School, Graduate School of Energy and Environment, Korea University)
Publication Information
Current Applied Physics / v.18, no.11, 2018 , pp. 1268-1274 More about this Journal
Abstract
We have investigated the effects of chemical rounding (CR) on the surface passivation and/or antireflection performance of $AlO_{x^-}$ and $AlO_x/SiN_x:H$ stack-passivated pyramid textured $p^+$-emitters with two different boron doping concentrations, and on the performance of bifacial n-PERT Si solar cells with a front pyramid textured $p^+$-emitter. From experimental results, we found that chemical rounding markedly enhances the passivation performance of $AlO_x$ layers on pyramid textured $p^+$-emitters, and the level of performance enhancement strongly depends on boron doping concentration. Meanwhile, chemical rounding increases solar-weighted reflectance ($R_{SW}$) from ~2.5 to ~3.7% for the $AlO_x/SiN_x:H$ stack-passivated pyramid textured $p^+$-emitters after 200-sec chemical rounding. Consequently, compared to non-rounded bifacial n-PERT Si cells, the short circuit current density Jsc of 200-sec-rounded bifacial n-PERT Si cells with ~60 and ${\sim}100{\Omega}/sq$ $p^+$-emitters is reduced by 0.8 and $0.6mA/cm^2$, respectively under front $p^+$-emitter side illumination. However, the loss in the short circuit current density Jsc is fully offset by the increased fill factor FF by 0.8 and 1.5% for the 200-sec-rounded cells with ~60 and ${\im}100{\Omega}/sq$ $p^+$-emitters, respectively. In particular, the cell efficiency of the 200-sec-rounded cells with a ${\sim}100{\Omega}/sq$ $p^+$-emitter is enhanced as a result, compared to that of the non-rounded cells. Based on our results, it could be expected that the cell efficiency of bifacial n-PERT Si cells would be improved without additional complicated and costly processes if chemical rounding and boron doping processes can be properly optimized.
Keywords
Chemical rounding; Pyramid texturing; $p^+$-emitter; Solar-weighted reflectance; $AlO_x$ passivation; Bifacial n-PERT solar cell;
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