Balaji Nagarajan, Park Cheolmin, Chung Sungyoun, Ju Minkyu, Raja Jayapal, Yi Junsin
J Nanosci Nanotechnol. 2016 May;16(5):4783-7. doi: 10.1166/jnn.2016.12178.
High quality surface passivation has gained a significant importance in photovoltaic industry for reducing the surface recombination and hence fabricating low cost and high efficiency solar cells using thinner wafers. The formation of good-quality SiO2 films and SiO2/Si interfaces at low processing temperatures is a prerequisite for improving the conversion efficiency of industrial solar cells with better passivation. High-temperature annealing in inert ambient is promising to improve the SiO2/Si interface. However, annealing treatments could cause negative effects on SiO2/Si interfaces due to its chemical at high temperatures. Low temperature post oxidation annealing has been carried out to investigate the structural and interface properties of Si-SiO2 system. Quasi Steady State Photo Conductance measurements shows a promising effective carrier lifetime of 420 μs, surface recombination velocity of 22 cm/s and a low interface trap density (D(it)) of 4 x 10(11) states/cm2/eV after annealing. The fixed oxide charge density was reduced to 1 x 10(11)/cm2 due to the annealing at 500 degrees C. The FWHM and the Si-O peak wavenumber corresponding to the samples annealed at 500 degrees C reveals that the Si dangling bonds in the SiO2 films due to the oxygen defects was reduced by the low temperature post oxidation annealing.
高质量的表面钝化在光伏产业中变得极为重要,它可减少表面复合,从而使用更薄的晶片制造低成本、高效率的太阳能电池。在低温工艺条件下形成高质量的二氧化硅(SiO₂)薄膜以及SiO₂/硅(Si)界面,是提高具有更好钝化效果的工业太阳能电池转换效率的前提条件。在惰性环境中进行高温退火有望改善SiO₂/Si界面。然而,由于高温下的化学反应,退火处理可能会对SiO₂/Si界面产生负面影响。已开展低温后氧化退火来研究Si-SiO₂系统的结构和界面特性。准稳态光电导测量结果显示,退火后有效载流子寿命有望达到420微秒,表面复合速度为22厘米/秒,界面陷阱密度(D(it))低至4×10¹¹态/厘米²/电子伏特。由于在500摄氏度下进行退火,固定氧化物电荷密度降低至1×10¹¹/厘米²。对应于在500摄氏度下退火样品的半高宽(FWHM)和Si-O峰波数表明,低温后氧化退火减少了因氧缺陷导致的SiO₂薄膜中的硅悬空键。