Quantum Trajectory Distribution for Weak Measurement of a Superconducting Qubit: Experiment meets Theory

TL;DR

This paper experimentally observes and characterizes the distribution of quantum trajectories during weak measurements of a superconducting qubit, confirming theoretical stochastic models and advancing understanding of quantum measurement dynamics.

Contribution

It provides the first comprehensive experimental measurement of quantum trajectory distributions for weak measurements, validating a single-parameter stochastic process model.

Findings

Quantum trajectories follow a single-parameter white-noise stochastic process.

Experimental results align closely with theoretical predictions.

Characterization offers insights into quantum measurement dynamics.

Abstract

Quantum measurements are described as instantaneous projections in textbooks. They can be stretched out in time using weak measurements, whereby one can observe the evolution of a quantum state as it heads towards one of the eigenstates of the measured operator. This evolution can be understood as a continuous nonlinear stochastic process, generating an ensemble of quantum trajectories, consisting of noisy fluctuations on top of geodesics that attract the quantum state towards the measured operator eigenstates. The rate of evolution is specific to each system-apparatus pair, and the Born rule constraint requires the magnitudes of the noise and the attraction to be precisely related. We experimentally observe the entire quantum trajectory distribution for weak measurements of a superconducting qubit in circuit QED architecture, quantify it, and demonstrate that it agrees very well with the predictions of a single-parameter white-noise stochastic process. This characterisation of quantum trajectories is a powerful clue to unraveling the dynamics of quantum measurement, beyond the conventional axiomatic quantum theory.