The Hamiltonian, which determines the evolution of a quantum system, is fundamental in quantum
physics. Therefore, it is crucial to implement high-precision generation and measurement of the
Hamiltonian in a practical quantum system. Here, we experimentally demonstrate ultrahigh-precision
Hamiltonian parameter estimation with a significant quantum advantage in a superconducting circuit via
sequential control. We first observe the commutation relation for noncommuting operations determined by
the system Hamiltonian, both with and without adding quantum control, verifying the commuting property
of controlled noncommuting operations. Based on this control-induced commuting property, we further
demonstrate Hamiltonian parameter estimation for polar and azimuth angles in superconducting circuits,
achieving ultrahigh metrological gains in measurement precision exceeding the standard quantum limit by
up to 16.0 and 16.1 dB at N ¼ 100, respectively.
Article: https://journals.aps.org/prl/abstract/10.1103/PhysRevLett.132.250204