Superconducting Nanowire Detection of Neutral Atoms and Molecules via Their Internal and Kinetic Energy in the eV Range

IF 2.8 Advanced Physics Research Pub Date : 2024-12-13 DOI:10.1002/apxr.202400133

M. Strauß, R. Gourgues, M. F. X. Mauser, L. Kulman, M. Castaneda, A. Fognini, A. Shayeghi, P. Geyer, M. Arndt

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Abstract

Superconducting nanowires are widely recognized as exceptional sensors in photonics, information processing, and astronomy. Even a single infrared photon can break Cooper pairs, generate a hot spot and trigger a measurable quantum phase transition. Here, it is demonstrated that this detection capability is far more versatile. Ultrathin nanowires are shown to be sensitive to the internal energy of atoms as well as to the kinetic energy of neutral molecules, here within the energy range of 10–20 and 3–6 eV, respectively. Superconducting nanowires achieve higher detection quantum yields than channel electron multipliers in the detection of metastable atoms and they surpass the efficiency of secondary electron detectors by more than a factor of 10⁶ in the detection of molecules at impact energies below 5 eV. This remarkable sensitivity paves the way for new applications in atomic and molecular beam physics, establishing nanowires as a crucial tool for future precision measurements.

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利用超导纳米线在eV范围内的内能和动能检测中性原子和分子

超导纳米线被广泛认为是光子学、信息处理和天文学领域的特殊传感器。即使是单个红外光子也可以破坏库珀对，产生热点并触发可测量的量子相变。在这里，它证明了这种检测能力要通用得多。超薄纳米线对原子的内能和中性分子的动能非常敏感，分别在10-20 eV和3-6 eV的能量范围内。超导纳米线在检测亚稳原子方面比通道电子倍增器获得更高的检测量子产率，在检测冲击能量低于5 eV的分子时，它们的效率超过二次电子探测器的106倍以上。这种卓越的灵敏度为原子和分子束物理学的新应用铺平了道路，使纳米线成为未来精密测量的关键工具。

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Advanced Physics Research

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