S P Benz, Kevin J Coakley, N. Flowers-Jacobs, Horst Rogalla, W. Tew, J F Qu, D. R. White, C. Gaiser, Alessio Pollarollo, Chiharu Urano
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引用次数: 0
摘要
约翰逊噪声测温(JNT)是一种纯电子的热力学温度测量方法。在初级约翰逊噪声测温法中,温度是通过比较未知温度下电阻器的约翰逊噪声电压与量子电压噪声源(QVNS)合成的伪随机噪声而推断出来的。该方法的优点是完全依赖电子测量,而且由于 QVNS 能够生成可编程、可扩展和精确的参考信号,因此可以在很宽的温度范围内使用。其缺点是要求 QVNS 在低温下运行,需要匹配感应电阻器和 QVNS 引线的频率响应,以及测量时间长。本综述整理了目前基于开关相关器和 QVNS 的初级约翰逊噪声温度计的最佳实践建议。该方法可在 300 K 附近实现约 1 mK 的不确定性,适用于 4 K 至 1000 K 之间的操作。
Practical realisation of the kelvin by Johnson noise thermometry
Johnson noise thermometry (JNT) is a purely electronic method of thermodynamic thermometry. In primary JNT, the temperature is inferred from a comparison of the Johnson noise voltage of a resistor at the unknown temperature with a pseudo-random noise synthesized by a quantum-based voltage-noise source (QVNS). The advantages of the method are that it relies entirely on electronic measurements, and it can be used over a wide range of temperatures due to the ability of the QVNS to generate programmable, scalable, and accurate reference signals. The disadvantages are the requirement of cryogenic operation of the QVNS, the need to match the frequency responses of the leads of the sense resistor and the QVNS, and long measurement times. This review collates advice on current best practice for a primary Johnson noise thermometer based on the switched correlator and QVNS. The method achieves an uncertainty of about 1 mK near 300 K and is suited to operation between 4 K and 1000 K.
期刊介绍:
ACS Applied Bio Materials is an interdisciplinary journal publishing original research covering all aspects of biomaterials and biointerfaces including and beyond the traditional biosensing, biomedical and therapeutic applications.
The journal is devoted to reports of new and original experimental and theoretical research of an applied nature that integrates knowledge in the areas of materials, engineering, physics, bioscience, and chemistry into important bio applications. The journal is specifically interested in work that addresses the relationship between structure and function and assesses the stability and degradation of materials under relevant environmental and biological conditions.
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