Optimized proximity thermometer for ultrasensitive detection : Role of an ohmic electromagnetic environment
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We propose a mesoscopic thermometer for ultrasensitive detection based on the proximity effect in superconductor (S)-normal-metal (N) heterostructures. The device is based on the zero-bias anomaly (ZBA) due to the inelastic Cooper pair tunneling in an SNIS junction (I stands for an insulator) coupled to an ohmic electromagnetic (EM) environment. The theoretical model is done in the framework of the quasiclassical Usadel Green's formalism and the dynamical Coulomb blockade. The usage of an ohmic EM environment makes the thermometer highly sensitive and not saturating down to very low temperatures, T≲5 mK. Moreover, defined in this way, the thermometer is stable against small but non-vanishing voltage amplitudes typically used for measuring the zero-bias differential conductance in experiments. Finally, we proposed a simplified view, based on an analytic treatment, which is in very good agreement with numerical results and can serve as a tool for the development, calibration, and optimization of such devices in future experiments in quantum calorimetry.
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NIKOLIĆ, Danilo, Bayan KARIMI, Diego Subero RENGEL, Jukka P. PEKOLA, Wolfgang BELZIG, 2023. Optimized proximity thermometer for ultrasensitive detection : Role of an ohmic electromagnetic environmentBibTex
@unpublished{Nikolic2023-03-10Optim-66407, year={2023}, title={Optimized proximity thermometer for ultrasensitive detection : Role of an ohmic electromagnetic environment}, author={Nikolić, Danilo and Karimi, Bayan and Rengel, Diego Subero and Pekola, Jukka P. and Belzig, Wolfgang} }
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