A 25-micron single photon sensitive kinetic inductance detector
Peter K. Day, Nicholas F. Cothard, Christopher Albert, Logan Foote, Elijah Kane, Byeong H. Eom, Ritoban Basu Thakur, Reinier M. J. Janssen, Andrew Beyer, Pierre Echternach, Sven van Berkel, Steven Hailey-Dunsheath, Thomas R. Stevenson, Shahab Dabironezare, Jochem J. A. Baselmans, Jason Glenn, C. Matt Bradford, Henry G. Leduc
arXiv:2404.10246v1 Announce Type: new
Abstract: We report measurements characterizing the performance of a kinetic inductance detector array designed for a wavelength of 25 microns and very low optical background level suitable for applications such as a far-infrared instrument on a cryogenically cooled space telescope. In a pulse counting mode of operation at low optical flux, the detectors can resolve individual 25-micron photons. In an integrating mode, the detectors remain photon noise limited over more than six orders of magnitude in absorbed power from 70 zW to 200 fW, with a limiting NEP of 4.6 x 10^-20 W/rtHz at 1 Hz. In addition, the detectors are highly stable with flat power spectra under optical load down to 1 mHz. Operational parameters of the detector are determined including the efficiency of conversion of the incident optical power into quasiparticles in the aluminum absorbing element and the quasiparticle self-recombination constant.arXiv:2404.10246v1 Announce Type: new
Abstract: We report measurements characterizing the performance of a kinetic inductance detector array designed for a wavelength of 25 microns and very low optical background level suitable for applications such as a far-infrared instrument on a cryogenically cooled space telescope. In a pulse counting mode of operation at low optical flux, the detectors can resolve individual 25-micron photons. In an integrating mode, the detectors remain photon noise limited over more than six orders of magnitude in absorbed power from 70 zW to 200 fW, with a limiting NEP of 4.6 x 10^-20 W/rtHz at 1 Hz. In addition, the detectors are highly stable with flat power spectra under optical load down to 1 mHz. Operational parameters of the detector are determined including the efficiency of conversion of the incident optical power into quasiparticles in the aluminum absorbing element and the quasiparticle self-recombination constant.