Highly sensitive phase- and frequency-resolved detection of microwave electric fields is of central importance in a wide range of fields, including cosmology^1,2, meteorology³, communication⁴ and microwave quantum technology⁵. Atom-based electrometers^6,7 promise traceable standards for microwave electrometry, but their best sensitivity is currently limited to a few μV cm⁻¹ Hz^−1/2 (refs. ^8,9) and they only yield information about the field amplitude and polarization¹⁰. Here, we demonstrate a conceptually new microwave electric field sensor—the Rydberg-atom superheterodyne receiver (superhet). The sensitivity of this technique scales favourably, achieving even 55 nV cm⁻¹ Hz^−1/2 with a modest set-up. The minimum detectable field of 780 pV cm⁻¹ is three orders of magnitude smaller than what can be reached by existing atomic electrometers. The Rydberg-atom superhet allows SI-traceable measurements, reaching uncertainty levels of 10⁻⁸ V cm⁻¹ when measuring a sub-μV cm⁻¹ field, which has been inaccessible so far with atomic sensors. Our method also enables phase and frequency detection. In sensing Doppler frequencies, sub-μHz precision is reached for fields of a few hundred nV cm⁻¹. This work is a first step towards realizing electromagnetic-wave quantum sensors with quantum projection noise-limited sensitivity. Such a device will impact diverse areas like radio astronomy, radar technology and metrology.

The Rydberg-atom superhet, based on microwave-dressed Rydberg atoms and a tailored electromagnetically induced transparency spectrum, allows SI-traceable measurements of microwave electric fields with unprecedented sensitivity.