Stacked Intrinsic Josephson Junction Bi2 Sr2 CaCu2 O8 Terahertz Sources: Design Issues for Achieving High Power Output Close to Tc

2020 International Conference on UK-China Emerging Technologies (UCET) Pub Date : 2020-08-01 DOI:10.1109/UCET51115.2020.9205486

T. Benseman, K. Kihlstrom, A. Koshelev, U. Welp, W. Kwok, K. Kadowaki

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Abstract

The high-temperature superconductor Bi2 Sr2 CaCu2 O8 contains stacked ‘intrinsic’ Josephson junctions, with unrivaled packing density and a high superconducting gap energy. Cuboid ‘mesa’ devices constructed from this material are consequently a promising technology for coherent, continuouswave radiation in the ‘terahertz gap’ range, spanning from approximately 0.3-1.5 THz. A key issue for practical applications of such devices is their cryocooling requirements, and it is therefore highly desirable to optimize their performance at temperatures that can be achieved by nitrogen cryogenics. Here we report generation of 0.13 milliwatts of coherent emission power at 0.461 THz, at a bath temperature of 77.4 Kelvin. This was achieved by exciting the (3, 0) cavity mode of a stack containing 579 junctions, and with Tc of 86.5 Kelvin. In order to minimize selfheating, the THz source was mounted on a copper substrate using PbSn solder. We will discuss the choice of mesa dimensions and cavity mode, and implications for the design of devices which are intended to operate close to the material’s superconducting critical temperature.

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堆叠内禀约瑟夫森结Bi2 Sr2 cu2 O8太赫兹源:实现接近Tc的高功率输出的设计问题

高温超导体Bi2 Sr2 CaCu2 O8包含堆叠的“本禀”约瑟夫森结，具有无与伦比的包装密度和高超导间隙能。因此，由这种材料构建的长方体“台面”设备是一种很有前途的技术，用于在“太赫兹间隙”范围内(大约0.3-1.5太赫兹)的相干连续波辐射。这类装置实际应用的一个关键问题是它们的低温冷却要求，因此，在氮低温可以达到的温度下优化它们的性能是非常可取的。在这里，我们报告了在0.461太赫兹下，在77.4开尔文的浴温下产生0.13毫瓦的相干发射功率。这是通过激发包含579个结的堆栈(3,0)腔模式实现的，并且Tc为86.5开尔文。为了减少自热，太赫兹源用PbSn焊料安装在铜衬底上。我们将讨论台面尺寸和腔模式的选择，以及设计接近材料超导临界温度的器件的意义。

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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2020 International Conference on UK-China Emerging Technologies (UCET)

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