Qubit Readout via State-Dependent Radiative Linewidths
摘要
Fast qubit readout conventionally encodes state information in a dispersive frequency shift. Here we formulate a linewidth-encoded quantum non-demolition measurement channel in which the qubit state enters the external radiative amplitude, equivalently a state-dependent Lindblad jump operator. Starting from an empty cavity, we show analytically that this dissipative channel imprints state information on the output field at , whereas standard dispersive readout starts at because it requires intracavity buildup and conditional phase accumulation. This short-time scaling produces faster matched-filter signal-to-noise ratio accumulation and persists in finite-resource comparisons, including photon-number limits, external-linewidth budgets, cavity depletion, and pulse-optimized dispersive baselines. We further outline an auxiliary-mode route that converts a qubit-state-dependent auxiliary susceptibility into a state-dependent linewidth. These results identify engineered dissipation as an information-carrying resource for fast quantum non-demolition readout.
引用
@article{arxiv.2606.31011,
title = {Qubit Readout via State-Dependent Radiative Linewidths},
author = {Yiming Yu and Xinyu Zhao and Jia-Wen Yu and Ke-Xiong Yan and Wei Qin and Ye-Hong Chen and Yan Xia and Franco Nori},
journal= {arXiv preprint arXiv:2606.31011},
year = {2026}
}
备注
7 pages, 4 figures