动电感
材料科学
超导电性
微波食品加热
纳米晶材料
铌
谐振器
共面波导
钽
光电子学
薄膜
凝聚态物理
原子层沉积
蓝宝石
堆栈(抽象数据类型)
电阻率和电导率
沉积(地质)
氧化钇钡铜
氮化铌
氮化钽
图层(电子)
电感
邻近效应(电子束光刻)
高温超导
微波腔
动能
宽禁带半导体
Ⅱ型超导体
作者
Iliya Shiravand,Moeid Jamalzadeh,Man Nguyen,Christopher Nadeau,Miguel Manzo-Perez,Soo-yeon Hwang,Xiao Tong,Dmytro Nykypanchuk,Matthew LaHaye,Davood Shahrjerdi
摘要
The promise of tantalum for realizing superconducting quantum devices has generated interest in its compound films, particularly nitrides. Among these, cubic-phase tantalum carbonitride (TaCxN1−x) offers reduced susceptibility to oxidation and a high critical temperature, yet its microwave properties remain largely unexplored. Here, we investigate plasma-enhanced atomic layer deposition of cubic-phase TaCxN1−x thin films for superconducting microwave circuits. Structural and transport measurements reveal nanocrystalline morphology with sub-10 nm grains and superconductivity in the dirty limit. Coplanar waveguide resonators exhibit moderately high kinetic inductance (16.8 pH/sq for 30 nm films) with potential for enhancement through dimensional scaling. The films also support high internal quality factors exceeding 105 at 50 mK in the single-photon regime, comparable to granular aluminum. Loss analysis identifies the two-level systems as the dominant limiting mechanism, with potential for further reduction through interface engineering. These results establish atomic layer deposited TaCxN1−x as a promising material for scalable, low-loss, high-inductance superconducting circuits.
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