Electron and hole injection barriers between silicon substrate and RF magnetron sputtered In2O3 : Er films

K. Feklistov, A. Lemzyakov, A. Shklyaev, D. Protasov, A. Deryabin, E. V. Spesivsev, D. Gulyaev, A. Pugachev, D. G. Esaev
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引用次数: 0

Abstract

In2O3 : Er films have been synthesized on silicon substrates by RF magnetron sputter deposition. The currents through the synthesized metal/oxide/semiconductor (MOS) structures (Si/In2O3 : Er/In-contact) have been measured for n and p type conductivity silicon substrates and described within the model of majority carrier thermoemission through the barrier, with bias voltage correction to the silicon potential drop. The electron and hole injection barriers between the silicon substrate and the film have been found to be 0.14 and 0.3 eV, respectively, by measuring the temperature dependence of the forward current at a low sub-barrier bias. The resulting low hole injection barrier is accounted for by the presence of defect state density spreading from the valence band edge into the In2O3 : Er band gap to form a hole conduction channel. The presence of defect state density in the In2O3 : Er band gap is confirmed by photoluminescence data in the respective energy range 1.55–3.0 eV. The band structure of the Si/In2O3 : Er heterojunction has been analyzed. The energy gap between the In2O3 : Er conduction band electrons and the band gap conduction channel holes has been estimated to be 1.56 eV.
硅衬底与射频磁控溅射In2O3: Er薄膜之间的电子和空穴注入势垒
采用射频磁控溅射沉积方法在硅衬底上制备了In2O3: Er薄膜。通过合成金属/氧化物/半导体(MOS)结构(Si/In2O3: Er/In-contact)对n型和p型导电性硅衬底的电流进行了测量,并在通过势垒的多数载流子热发射模型中进行了描述,并对硅电位下降进行了偏置电压校正。通过测量低亚势垒偏压下正向电流的温度依赖性,发现硅衬底和薄膜之间的电子和空穴注入势垒分别为0.14和0.3 eV。导致低空穴注入势垒的原因是缺陷态密度从价带边缘扩散到In2O3: Er带隙中,形成空穴传导通道。在1.55 ~ 3.0 eV范围内的光致发光数据证实了In2O3: Er禁带中存在缺陷态密度。分析了Si/In2O3: Er异质结的能带结构。In2O3: Er导带电子与带隙导通道空穴之间的能隙估计为1.56 eV。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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