Ultra-short pulsed laser for nano-texturization associated to plasma immersion implantation for 3D shallow doping: Application to silicon photovoltaic structures.
M. Halbwax, T. Sarnet, M. Sentis, H. Etienne, F. Torregrosa, V. Vervisch, I. Périchaud, S. Martinuzzi, Laboratoire Lp
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引用次数: 2
Abstract
It has been recently shown (Mazur et al) (1-7) that a simple way to improve the photocurrent of a silicon-based solar cell is to irradiate the silicon surface with a series of femtosecond laser pulses, in the presence of a sulfur containing gas. This improves the formation of micro- spikes on the silicon surface that strongly reduces the reflectivity of the illuminated surface for the incident solar light (Black Silicon). We have prepared photovoltaic structures with different nano-texturization obtained by means of a femtosecond laser, without the use of corrosive gas (under vacuum). To take in account the 3D structured front surface, the emitter doping has been realized by using Plasma Immersion Ion Implantation (so-called PULSION). The results show a photocurrent increase of about 30 % in the laser textured zones.
最近有研究表明(Mazur et al)(1-7)改善硅基太阳能电池光电流的一种简单方法是在含硫气体存在的情况下,用一系列飞秒激光脉冲照射硅表面。这改善了硅表面上微尖峰的形成,从而大大降低了入射太阳光(黑硅)照射表面的反射率。我们在不使用腐蚀性气体(真空条件下)的情况下,利用飞秒激光制备了具有不同纳米纹理的光伏结构。考虑到三维结构的前表面,利用等离子体浸没离子注入(所谓的斥力)实现了发射极掺杂。结果表明,激光织构区光电流增加约30%。