Zeptojoule Calorimetry

TL;DR

This paper demonstrates a metallic SNS sensor achieving sub-zeptojoule energy resolution for microwave pulses, advancing calorimetry towards single-photon detection in the GHz range with applications in quantum tech and fundamental physics.

Contribution

It reports the first experimental realization of a calorimeter with energy resolution below 1 zJ, surpassing previous estimates and enabling real-time single-photon detection at microwave frequencies.

Findings

Achieved 0.95 zJ energy resolution for 8.4 GHz microwave pulses.

Demonstrated calorimetry capable of resolving 170 photons at 8.4 GHz.

Provides a pathway for quantum state measurement and fundamental physics experiments.

Abstract

The measurement of energy is a fundamental tool used, for example, in exploring the early universe, characterizing particle decay processes, as well as in quantum technology and computing. Some of the most sensitive energy detectors are thermal, i.e., bolometers and calorimeters, which operate by absorbing incoming energy, converting it into heat, and reading out the resulting temperature change electrically using a thermometer. Extremely sensitive calorimeters, including transition edge sensors, magnetic microcalorimeters and devices based on 2D conductors such as graphene, have been shown to reach impressive energy resolutions of 17.6 zJ. Very recently superconductor--normal-conductor--superconductor (SNS) radiation sensors with metallic and graphene absorbers have resulted in predictions of full-width-at-half-maximum (FWHM) energy resolutions of 0.75 zJ and 0.05 zJ = 71 GHz$\times h$, respectively, where $h$ is the Planck constant. However, since these estimates are only mathematically extracted from steady-state noise and responsivity measurements, no calorimetry reaching single-zeptojoule energy resolution or beyond has been demonstrated. Here, we use a metallic SNS sensor to measure the energy of 1-$\mu$s-long 8.4-GHz microwave pulses with a FWHM energy resolution finer than (0.95 $\pm$ 0.02) zJ = (5.9 $\pm$ 0.12) meV, corresponding to 170 photons at 8.4 GHz. The techniques of this work, combined with graphene-based sensors, provide a promising path to real-time calorimetric detection of single photons in the 10 GHz range. Such a device has potential in operating as an accurate measurement device of quantum states such as those of superconducting qubits, or used in fundamental physics explorations including quantum thermodynamics, and the search for axions.