Measurement-Based Long-Range Entangling Gates in Constant Depth
Abstract
The depth of quantum circuits is a critical factor when running them on state-of-the-art quantum devices due to their limited coherence times. Reducing circuit depth decreases noise in near-term quantum computations and reduces overall computation time, thus, also benefiting fault-tolerant quantum computations. Here, we show how to reduce the depth of quantum sub-routines that typically scale linearly with the number of qubits, such as quantum fan-out and long-range CNOT gates, to a constant depth using mid-circuit measurements and feed-forward operations, while only requiring a 1D line topology. We compare our protocols with existing ones to highlight their advantages. Additionally, we verify the feasibility by implementing the measurement-based quantum fan-out gate and long-range CNOT gate on real quantum hardware, demonstrating significant improvements over their unitary implementations.
Cite
@article{arxiv.2408.03064,
title = {Measurement-Based Long-Range Entangling Gates in Constant Depth},
author = {Elisa Bäumer and Stefan Woerner},
journal= {arXiv preprint arXiv:2408.03064},
year = {2025}
}
Comments
6 pages, 8 figures (main text) + 5 pages, 7 figures (appendix)