Beyond the standard quantum limit for parametric amplification of broadband signals
Michael Renger, Stefan Pogorzalek, Qiming Chen, Yuki Nojiri, K. Inomata, Yasunobu Nakamura, Matti Partanen, Achim Marx, R. Gross, Frank Deppe, Kirill G. Fedorov
Abstract
Abstract The low-noise amplification of weak microwave signals is crucial for countless protocols in quantum information processing. Quantum mechanics sets an ultimate lower limit of half a photon to the added input noise for phase-preserving amplification of narrowband signals, also known as the standard quantum limit (SQL). This limit, which is equivalent to a maximum quantum efficiency of 0.5, can be overcome by employing nondegenerate parametric amplification of broadband signals. We show that, in principle, a maximum quantum efficiency of unity can be reached. Experimentally, we find a quantum efficiency of 0.69 ± 0.02, well beyond the SQL, by employing a flux-driven Josephson parametric amplifier and broadband thermal signals. We expect that our results allow for fundamental improvements in the detection of ultraweak microwave signals.