An anti-maser for quantum-limited cooling of a microwave cavity

TL;DR

This paper demonstrates an 'anti-maser' device that cools a microwave cavity to the quantum limit at moderate cryogenic temperatures, potentially simplifying cooling requirements for quantum circuits.

Contribution

It introduces an experimental method to generate a low positive temperature state in condensed matter, enabling efficient microwave photon removal and cavity cooling.

Findings

Achieved quantum-limited cooling of a microwave cavity

Demonstrated generation of a low positive temperature state

Potential to operate superconducting circuits at higher temperatures

Abstract

The maser, a microwave (MW) analog of the laser, is a well-established method for generating and amplifying coherent MW irradiation with ultra-low noise. This is accomplished by creating a state of population inversion between two energy levels separated by MW frequency. Thermodynamically, such a state corresponds to a small but negative temperature. The reverse condition, where only the lower energy level is highly populated, corresponds to a very low positive temperature. In this work, we experimentally demonstrate how to generate such a state in condensed matter at moderate cryogenic temperatures. This state is then used to efficiently remove microwave photons from a cavity, continuously cooling it to the quantum limit, well below its ambient temperature. Such an "anti-maser" device could be extremely beneficial for applications that would normally require cooling to millikelvin temperatures to eliminate any MW photons. For instance, superconducting MW quantum circuits (such as qubits and amplifiers) could, with the use of this device, operate efficiently at liquid helium temperatures.