中文

Qubit Readout via State-Dependent Radiative Linewidths

量子物理 2026-06-30 v1

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 O(t)O(t), whereas standard dispersive readout starts at O(t2)O(t^2) 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