Designs from magic-augmented Clifford circuits
Abstract
We introduce magic-augmented Clifford circuits -- architectures in which Clifford circuits are preceded and/or followed by constant-depth circuits of non-Clifford (``magic") gates -- as a resource-efficient way to realize approximate -designs, with reduced circuit depth and usage of magic. We prove that shallow Clifford circuits, when augmented with constant-depth circuits of magic gates, can generate approximate unitary and state -designs with relative error. The total circuit depth for these constructions on qubits is in one dimension and in all-to-all circuits using ancillas, which improves upon previous results for small . Furthermore, our construction of relative-error state -designs only involves states with strictly local magic. The required number of magic gates is parametrically reduced when considering -designs with bounded additive error. As an example, we show that shallow Clifford circuits followed by single-qubit magic gates, independent of system size, can generate an additive-error state -design. We develop a classical statistical mechanics description of our random circuit architectures, which provides a quantitative understanding of the required depth and number of magic gates for additive-error state -designs. We also prove no-go theorems for various architectures to generate designs with bounded relative error.
Cite
@article{arxiv.2507.02828,
title = {Designs from magic-augmented Clifford circuits},
author = {Yuzhen Zhang and Sagar Vijay and Yingfei Gu and Yimu Bao},
journal= {arXiv preprint arXiv:2507.02828},
year = {2026}
}
Comments
61 pages