High barrier height Schottky diodes on n-InP by low temperature deposition

Z. Shi, R. Wallace, W. Anderson
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Abstract

The formation of ultra-high barrier height ( phi /sub B/=0.96 eV) Schottky contacts to n-InP, without an intentionally grown interfacial oxide, using metal deposition on a substrate cooled to as low as 77 K is discussed. Values of phi /sub B/=0.46-0.52 eV for diodes deposited at room temperature (RT=300 K) agree and give an ideality factor near unity. For diodes deposited at a low temperature (LT) of 77 K, the leakage current density (J/sub 0/) is reduced by more than 6-7 orders of magnitude with respect to the RT diodes. The phi /sub B/ for the LT diodes is increased from 0.48 to 0.96 eV for Pd metal and from 0.51 to 0.85 eV for Au metal, respectively. The conduction mechanisms for the LT and RT diodes are found to be controlled by thermionic-field emission (TFE) and thermionic emission (TE), respectively. It is shown that an alteration of the metal-induced interface states, inhibition of surface segregation of the released In and P atoms, and very uniform metal coverage may be responsible for the distinct differences between the RT and LT diodes.<>
n-InP上低温沉积高势垒肖特基二极管
本文讨论了在冷却至77k的衬底上使用金属沉积,在没有有意生长界面氧化物的情况下,与n-InP形成超高势垒高度(phi /sub B/=0.96 eV)的肖特基触点。在室温下(RT=300 K)沉积的二极管的phi /sub B/=0.46-0.52 eV值一致,并给出了接近统一的理想因子。对于在77 K低温下沉积的二极管,泄漏电流密度(J/sub 0/)相对于RT二极管降低了6-7个数量级以上。对于钯金属,LT二极管的phi /sub B/分别从0.48 eV增加到0.96 eV,而对于金金属,则从0.51 eV增加到0.85 eV。热离子场发射(TFE)和热离子发射(TE)分别控制了LT和RT二极管的传导机制。结果表明,金属诱导的界面态的改变、释放的In和P原子的表面偏析的抑制以及非常均匀的金属覆盖可能是造成RT和LT二极管之间明显差异的原因。
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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