通过耗散稳定格规理论的量子模拟

Tobias Schmale, Hendrik Weimer
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引用次数: 0

摘要

由于实现模拟的底层物理系统存在相干和非相干误差,在噪声量子硬件上对晶格规理论的模拟本身就存在违反规对称性的问题。这些违反规对称性的现象会导致模拟变得不物理,从而要求放弃模拟结果。我们研究了一种主动校正方案,它依赖于在局部检测量规违反,然后通过耗散驱动系统回到物理量规部门来校正它们。我们的研究表明,这种修正方案不仅能确保保护量规对称性,还能延长模拟结果的有效性,甚至在量规不变部门也是如此。最后,我们讨论了该方案的进一步应用,如模拟系统多体基态的制备。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Stabilizing quantum simulations of lattice gauge theories by dissipation

Stabilizing quantum simulations of lattice gauge theories by dissipation
Simulations of lattice gauge theories on noisy quantum hardware inherently suffer from violations of the gauge symmetry due to coherent and incoherent errors of the underlying physical system that implements the simulation. These gauge violations cause the simulations to become unphysical requiring the result of the simulation to be discarded. We investigate an active correction scheme that relies on detecting gauge violations locally and subsequently correcting them by dissipatively driving the system back into the physical gauge sector. We show that the correction scheme not only ensures the protection of the gauge symmetry, but it also leads to a longer validity of the simulation results even within the gauge-invariant sector. Finally, we discuss further applications of the scheme such as preparation of the many-body ground state of the simulated system.
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CiteScore
8.60
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