Quantum circuits for solving local fermion-to-qubit mappings

• URL: http://arxiv.org/abs/2208.07192v1
• Date: Mon, 15 Aug 2022 13:50:33 GMT
• Title: Quantum circuits for solving local fermion-to-qubit mappings
• Authors: Jannes Nys, Giuseppe Carleo
• Abstract summary: Local Hamiltonians of fermionic systems on a lattice can be mapped onto local qubit Hamiltonians. Maintaining locality comes at the expense of increasing the Hilbert space with auxiliary degrees of freedom. We demonstrate how maintaining locality allows one to carry out a Trotterized time-evolution with constant circuit depth per time step.
• Score: 0.0
• License: http://creativecommons.org/licenses/by/4.0/
• Abstract: Local Hamiltonians of fermionic systems on a lattice can be mapped onto local qubit Hamiltonians. Maintaining the locality of the operators comes at the expense of increasing the Hilbert space with auxiliary degrees of freedom. In order to retrieve the lower-dimensional physical Hilbert space that represents fermionic degrees of freedom, one must satisfy a set of constraints. In this work, we introduce quantum circuits that exactly satisfy these stringent constraints. We demonstrate how maintaining locality allows one to carry out a Trotterized time-evolution with constant circuit depth per time step. Our construction is particularly advantageous to simulate the time evolution operator of fermionic systems in d>1 dimensions. We also discuss how these families of circuits can be used as variational quantum states, focusing on two approaches: a first one based on general constant-fermion-number gates, and a second one based on the Hamiltonian variational ansatz where the eigenstates are represented by parametrized time-evolution operators. We apply our methods to the problem of finding the ground state and time-evolved states of the spinless 2D Fermi-Hubbard model.

Related papers

• Shortcut to adiabaticity and holonomic transformation are the same thing [0.0]
  We construct a universal control framework based on the system dynamics within an ancillary picture. We demonstrate that our control framework can be reduced to the nonadiabatic holonomic quantum transformation. For the state engineering over a finite-dimensional quantum system, our work can provide a full-rank nonadiabatic time-evolution operator.
  arXiv  Detail & Related papers  (2024-06-23T05:11:56Z)
• Quantum Random Walks and Quantum Oscillator in an Infinite-Dimensional Phase Space [45.9982965995401]
  We consider quantum random walks in an infinite-dimensional phase space constructed using Weyl representation of the coordinate and momentum operators. We find conditions for their strong continuity and establish properties of their generators.
  arXiv  Detail & Related papers  (2024-06-15T17:39:32Z)
• Exact real time dynamics with free fermions in disguise [0.0]
  We consider quantum spin chains with a hidden free fermionic structure, distinct from the Jordan-Wigner transformation and its generalizations. We build quantum circuits that can be implemented on a quantum computer.
  arXiv  Detail & Related papers  (2024-05-31T14:23:20Z)
• Quantum dynamics via a hidden Liouville space [0.0]
  We introduce a nonstandard iterative technique where time interval is divided into a large number of discrete subintervals with an ultrashort duration. We choose two-state spin raising and lowering operators for virtual space operators because of their simple algebra. We implement our technique for an example of a charged particle in both harmonic and anharmonic potentials.
  arXiv  Detail & Related papers  (2023-04-18T20:12:06Z)
• Measurement phase transitions in the no-click limit as quantum phase transitions of a non-hermitean vacuum [77.34726150561087]
  We study phase transitions occurring in the stationary state of the dynamics of integrable many-body non-Hermitian Hamiltonians. We observe that the entanglement phase transitions occurring in the stationary state have the same nature as that occurring in the vacuum of the non-hermitian Hamiltonian.
  arXiv  Detail & Related papers  (2023-01-18T09:26:02Z)
• Simulating scalar field theories on quantum computers with limited resources [62.997667081978825]
  We present a quantum algorithm for implementing $phi4$ lattice scalar field theory on qubit computers. The algorithm allows efficient $phi4$ state preparation for a large range of input parameters in both the normal and broken symmetry phases.
  arXiv  Detail & Related papers  (2022-10-14T17:28:15Z)
• Growth of entanglement of generic states under dual-unitary dynamics [77.34726150561087]
  Dual-unitary circuits are a class of locally-interacting quantum many-body systems. In particular, they admit a class of solvable" initial states for which, in the thermodynamic limit, one can access the full non-equilibrium dynamics. We show that in this case the entanglement increment during a time step is sub-maximal for finite times, however, it approaches the maximal value in the infinite-time limit.
  arXiv  Detail & Related papers  (2022-07-29T18:20:09Z)
• Variational solutions to fermion-to-qubit mappings in two spatial dimensions [0.0]
  We present a variational Monte-Carlo framework to study fermionic systems through higher-dimensional (>1D) Jordan-Wigner transformations. We provide exact solutions to the parity and Gauss-law constraints that are encountered in bosonization procedures.
  arXiv  Detail & Related papers  (2022-05-02T08:38:00Z)
• Algebraic Compression of Quantum Circuits for Hamiltonian Evolution [52.77024349608834]
  Unitary evolution under a time dependent Hamiltonian is a key component of simulation on quantum hardware. We present an algorithm that compresses the Trotter steps into a single block of quantum gates. This results in a fixed depth time evolution for certain classes of Hamiltonians.
  arXiv  Detail & Related papers  (2021-08-06T19:38:01Z)
• Fast-forwarding quantum evolution [0.2621730497733946]
  We show that certain quantum systems can be simulated with gate complexity that is sublinear in the evolution time. We provide a definition of fast-forwarding that considers the model of quantum computation, the Hamiltonians that induce the evolution, and the properties of the initial states.
  arXiv  Detail & Related papers  (2021-05-15T22:41:28Z)
• Non-equilibrium stationary states of quantum non-Hermitian lattice models [68.8204255655161]
  We show how generic non-Hermitian tight-binding lattice models can be realized in an unconditional, quantum-mechanically consistent manner. We focus on the quantum steady states of such models for both fermionic and bosonic systems.
  arXiv  Detail & Related papers  (2021-03-02T18:56:44Z)

This list is automatically generated from the titles and abstracts of the papers in this site.

This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.