N. Pokhrel, T. Weingartner, Robert J. Burwell, E. Patrick, M. Law
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引用次数: 3
摘要
约瑟夫森结器件通过在超导和电阻状态之间切换来实现二进制数据的计算。开关是由流过结的电流低于或高于临界极限$(I_{c})$触发的,这对结的物理特性很敏感。模拟这些隧道结的物理性质随加工条件的变化,对于理解芯片上$I_{c}$的变化和模拟器件的电气特性至关重要。本研究的目的是模拟用于大规模集成超导电路的Nb/Al- o /Nb约瑟夫森结的制造步骤,主要包括:(i)在Nb基电极上溅射沉积Al (ii)氧化Al层形成Al- o隧道势垒(~1nm)和(iii)阳极氧化结。通过从基础层实现制造步骤来开发过程TCAD工具将最终补充器件仿真并为优化提供有用的见解。
Simulating the Fabrication of Nb/Al-O/Nb Josephson Junction for Superconductive Electronics Application
Josephson junction devices enable computation of binary data by switching between superconductive and resistive states. The switching is triggered by a current flowing through the junction below or above the critical limit $(I_{c})$, which is sensitive to the physical features of the junction. Modeling the variation in the physical properties of these tunnel junctions due to processing conditions is crucial to understanding the variation in $I_{c}$ across the chip and simulating the electrical characteristics of the device. The aim of this research is to model the steps involved in the fabrication of Nb/Al-O/Nb Josephson Junction for large scale integrated superconductive circuits, which consists of mainly: (i) sputter deposition of Al on top of the Nb base electrode (ii) oxidation of the Al layer to form Al-O tunnel barrier (~1nm] and (iii) anodization of the junction. Developing a process TCAD tool by implementing the fabrication steps from the base layer will ultimately complement device simulation and offer useful insights for optimization.
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