Recycling qubits in near-term quantum computers
Abstract
Quantum computers are capable of efficiently contracting unitary tensor networks, a task that is likely to remain difficult for classical computers. For instance, networks based on matrix product states or the multi-scale entanglement renormalization ansatz (MERA) can be contracted on a small quantum computer to aid the simulation of a large quantum system. However, without the ability to selectively reset qubits, the associated spatial cost can be exorbitant. In this paper, we propose a protocol that can unitarily reset qubits when the circuit has a common convolutional form, thus dramatically reducing the spatial cost for implementing the contraction algorithm on general near-term quantum computers. This protocol generates fresh qubits from used ones by partially applying the time-reversed quantum circuit over qubits that are no longer in use. In the absence of noise, we prove that the state of a subset of these qubits becomes , up to an error exponentially small in the number of gates applied. We also provide a numerical evidence that the protocol works in the presence of noise. We also provide a numerical evidence that the protocol works in the presence of noise, and formulate a condition under which the noise-resilience follows rigorously.
Cite
@article{arxiv.2012.01676,
title = {Recycling qubits in near-term quantum computers},
author = {Galit Anikeeva and Isaac H. Kim and Patrick Hayden},
journal= {arXiv preprint arXiv:2012.01676},
year = {2021}
}
Comments
7+4 pages, 9 figures. Corollary A.2 fixed. Also, the mathematical statement about noise-resilience is added