Quantum Hamiltonian complexity in thermal equilibrium

The physical properties of a quantum many-body system in thermal equilibrium are determined by its partition function and free energy. Here we study the computational complexity of approximating these quantities for n -qubit local Hamiltonians. First, we report a classical algorithm with poly( n ) r...

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Veröffentlicht in:Nature physics Jg. 18; H. 11; S. 1367 - 1370
Hauptverfasser: Bravyi, Sergey, Chowdhury, Anirban, Gosset, David, Wocjan, Pawel
Format: Journal Article
Sprache:Englisch
Veröffentlicht: London Nature Publishing Group UK 01.11.2022
Nature Publishing Group
Schlagworte:
639/766/483/481
639/766/530/2804
639/766/530/951
Algorithms
Approximation
Atomic
Circuits
Classical and Continuum Physics
Complex Systems
Complexity
Condensed Matter Physics
Energy
Equilibrium
Free energy
Hamiltonian functions
Ising model
Mathematical analysis
Mathematical and Computational Physics
Molecular
Optical and Plasma Physics
Optimization
Partitions (mathematics)
Physical properties
Physics
Physics and Astronomy
Polynomials
Quantum computing
Qubits (quantum computing)
Run time (computers)
Theoretical
ISSN:1745-2473, 1745-2481
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Zusammenfassung:The physical properties of a quantum many-body system in thermal equilibrium are determined by its partition function and free energy. Here we study the computational complexity of approximating these quantities for n -qubit local Hamiltonians. First, we report a classical algorithm with poly( n ) runtime, which approximates the free energy of a given 2-local Hamiltonian provided that it satisfies a certain denseness condition. Our algorithm contributes to a body of work investigating the hardness of approximation for difficult optimization problems. Specifically, this extends existing efficient approximation algorithms for dense instances of the ground energy of 2-local quantum Hamiltonians and the free energy of classical Ising models. Second, we establish polynomial-time equivalence between the problem of approximating the free energy of local Hamiltonians and several other natural tasks ubiquitous in condensed-matter physics and quantum computing, such as the problem of approximating the number of input states accepted by a polynomial-size quantum circuit. These results suggest that the simulation of quantum many-body systems in thermal equilibrium may precisely capture the complexity of a broad family of computational problems that have yet to be defined or characterized in terms of known complexity classes. Finally, we summarize state-of-the-art classical and quantum algorithms for approximating the free energy and show how to improve their runtime and memory footprint. A quantum many-body system’s equilibrium behaviour is described by its partition function, which is hard to compute. Now it has been shown that the easier task of finding an approximation could define a distinct class of computational problems.
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ISSN:1745-2473
1745-2481
DOI:10.1038/s41567-022-01742-5