Measurement Results of the Superconducting-Ferromagnetic Transistor

2019 IEEE International Superconductive Electronics Conference (ISEC) Pub Date : 2019-07-01 DOI:10.1109/ISEC46533.2019.8990899

I. Nevirkovets, T. Kojima, Y. Uzawa, O. Mukhanov

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引用次数: 1

Abstract

We report on the measurement results of the superconducting-ferromagnetic transistors (SFTs) made at Northwestern University and Hypres, Inc. [IEEE Trans. Appl. Supercond. vol. 24, 1800506 (2014); vol. 25, 1800705 (2015)]. SFT is a multi-terminal device with the SIS'FIFS structure (where S, I, and F denote a superconductor, an insulator, and a ferromagnetic material, respectively) exploiting intense quasiparticle injection in order to modify the non-linear I-V curve of a superconducting tunnel junction. Potentially, SFT is capable of providing voltage, current and power amplification while having good input/output isolation. We characterized the devices at frequencies up to 5 MHz at 4 K. Our setup did not allow for accurate measurement of the voltage gain of low-impedance SFT devices because of contribution of resistance of the bias-T connected in series with the SFT. Nevertheless we observed a voltage gain above unity for some measurement configurations. It is very interesting that we confirmed that the isolation between the input and output of the device is quite good. We suggest that further improvement of the SFT device parameters is possible in optimized devices, so that the device potentially may serve as a preamplifier for readout of output signals of cryogenic detectors and be useful as an element of other superconductor-based circuits.

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超导铁磁晶体管的测量结果

我们报告了美国西北大学和Hypres公司制造的超导铁磁晶体管(SFTs)的测量结果。达成。Supercond。Vol . 24, 1800506 (2014);Vol . 25, 1800705(2015)]。SFT是一种多终端装置，具有SIS的fifs结构(其中S, I和F分别表示超导体，绝缘体和铁磁材料)，利用强准粒子注入来修改超导隧道结的非线性I- v曲线。潜在地，SFT能够提供电压、电流和功率放大，同时具有良好的输入/输出隔离。我们在4k下的频率高达5mhz的情况下对器件进行了表征。由于与SFT串联的偏置t的电阻贡献，我们的设置不允许精确测量低阻抗SFT器件的电压增益。然而，我们观察到一些测量配置的电压增益高于单位。非常有趣的是，我们确认该设备的输入和输出之间的隔离是相当好的。我们建议在优化的器件中进一步改进SFT器件参数，使该器件有可能作为读出低温探测器输出信号的前置放大器，并作为其他超导体电路的元件。

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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2019 IEEE International Superconductive Electronics Conference (ISEC)

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