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Trapped Ion Quantum Computing
Quantum Simulation
Learning State Preparation Circuits for Quantum Phases of Matter
arXiv
Authors: Hyun-Soo Kim, Isaac H. Kim, Daniel Ranard
Year
2024
Paper ID
37420
Status
Preprint
Abstract Read
~2 min
Abstract Words
157
Citations
N/A
Abstract
Many-body ground state preparation is an important subroutine used in the simulation of physical systems. In this paper, we introduce a flexible and efficient framework for obtaining a state preparation circuit for a large class of many-body ground states. We introduce polynomial-time classical algorithms that take reduced density matrices over mathcal{O}(1)-sized balls as inputs, and output a circuit that prepares the global state. We introduce algorithms applicable to (i) short-range entangled states (e.g., states prepared by shallow quantum circuits in any number of dimensions, and more generally, invertible states) and (ii) long-range entangled ground states (e.g., the toric code on a disk). Both algorithms can provably find a circuit whose depth is asymptotically optimal. Our approach uses a variant of the quantum Markov chain condition that remains robust against constant-depth circuits. The robustness of this condition makes our method applicable to a large class of states, whilst ensuring a classically tractable optimization landscape.
Why This Paper Matters
- This paper contributes to the Quantum Simulation research area in the Quantum Articles archive.
- It adds a 2024 reference point for readers tracking recent quantum research.
- Many-body ground state preparation is an important subroutine used in the simulation of physical systems.
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