超导电性
动电感
凝聚态物理
铌
物理
谐振器
量化(信号处理)
动能
磁场
电感
材料科学
光电子学
量子力学
计算机科学
计算机视觉
电压
冶金
作者
Lukas Nulens,Davi A. D. Chaves,Omar J. Y. Harb,Jeroen E. Scheerder,Nicolas Lejeune,Kamal Brahim,Bart Raes,A. V. Silhanek,M. J. Van Bael,Joris Van de Vondel
出处
期刊:Nano Letters
[American Chemical Society]
日期:2024-08-28
卷期号:24 (36): 11149-11155
被引量:3
标识
DOI:10.1021/acs.nanolett.4c01039
摘要
The energy landscape of multiply connected superconducting structures is ruled by fluxoid quantization due to the implied single-valuedness of the complex wave function. The transitions and interaction between these energy states, each defined by a specific phase winding number, are governed by classical and/or quantum phase slips. Understanding these events requires the ability to probe, noninvasively, the state of the ring. Here, we employ a niobium resonator to examine the superconducting properties of an aluminum loop. By applying a magnetic field, adjusting temperature, and altering the loop's dimensions via focused ion beam milling, we correlate resonance frequency shifts with changes in the loop's kinetic inductance. This parameter is an indicator of the superconducting condensate's state, facilitating the detection of phase slips in nanodevices and providing insights into their dynamics. Our method presents a proof-of-principle spectroscopic technique with promising potential for investigating Cooper pair density in inductively coupled superconducting nanostructures.
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