Regularization from Superpositions of Time Evolutions
Abstract
Short-time approximations and path integrals can be dominated by high-energy or large-field contributions, especially in the presence of singular interactions, motivating regulators that are suppressive yet removable. Standard regulators typically impose such suppressions by hand (e.g. cutoffs, higher-derivative terms, heat-kernel smearing, lattice discretizations), while here we show that closely related smooth filters can arise as the conditional map produced by interference in a coherently controlled, postselected superposition of evolutions. A successful postselection implements a single heralded operator that is a coherent linear combination of time-evolution operators. For a Gaussian superposition of time translations in quantum mechanics, the postselected step is , i.e.\ the desired unitary step multiplied by a Gaussian energy filter suppressing energies above order . This renders short-time kernels in time-sliced path-integral approximations well behaved for singular potentials, while the target unitary dynamics is recovered as and (for fixed ) also as at fixed . In scalar QFT, a local Gaussian smearing of the quartic coupling induces a positive term in the Euclidean action, providing a symmetry-compatible large-field stabilizer; it is naturally viewed as an irrelevant operator whose effects can be renormalized at fixed (together with a conventional UV regulator) and removed by taking . We give short-time error bounds and analyze multi-step success probabilities.
Cite
@article{arxiv.2601.04685,
title = {Regularization from Superpositions of Time Evolutions},
author = {Yakir Aharonov and Eliahu Cohen and Tomer Shushi},
journal= {arXiv preprint arXiv:2601.04685},
year = {2026}
}
Comments
Updated version, 13 pages