Understanding quantum tunneling using diffusion Monte Carlo simulations

Inack, Estelle M.; Giudici, Giuliano; Parolini, Tommaso; Santoro, Giuseppe E.; Pilati, Sebastiano

doi:10.1103/physreva.97.032307

Cited by 17 publications

(41 citation statements)

References 57 publications

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“…For the maximum bond dimension that we em- ploy (2000), the expected Z 2 symmetry is not realized below certain values of the transverse field strength h when the number of qubits is large. Furthermore, a similar phenomenon has been observed previously in studies of the relative energy in diffusion Monte Carlo [15] and a recent variational imaginary time ansatz [19]. It would be an interesting topic of future study.…”

Section: A Scaling Of the Model Parameterssupporting

confidence: 81%

“…where σ x,y,z are Pauli operators, defined over N sites (or qubits), and ij denotes nearest-neighbor pairs on a onedimensional lattice with open boundary conditions. This model is thoroughly studied in the condensed matter and quantum information literature, and serves as a standard benchmark for many numerical methods, such as quantum Monte Carlo [14,15], Tensor Networks (TNs) [16], or more recent quantum optimization algorithms [17][18][19]. We generate training data from a density matrix renormalization group (DMRG) simulation [20] for various values of h/J using the ITensor library [21].…”

Section: Defining a Scaling Studymentioning

confidence: 99%

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Learnability scaling of quantum states: Restricted Boltzmann machines

et al. 2019

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Generative modeling with machine learning has provided a new perspective on the data-driven task of reconstructing quantum states from a set of qubit measurements. As increasingly large experimental quantum devices are built in laboratories, the question of how these machine learning techniques scale with the number of qubits is becoming crucial. We empirically study the scaling of restricted Boltzmann machines (RBMs) applied to reconstruct ground-state wavefunctions of the one-dimensional transverse-field Ising model from projective measurement data. We define a learning criterion via a threshold on the relative error in the energy estimator of the machine. With this criterion, we observe that the number of RBM weight parameters required for accurate representation of the ground state in the worst case -near criticality -scales quadratically with the number of qubits. By pruning small parameters of the trained model, we find that the number of weights can be significantly reduced while still retaining an accurate reconstruction. This provides evidence that over-parametrization of the RBM is required to facilitate the learning process. arXiv:1908.07532v2 [quant-ph]

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Section: A Scaling Of the Model Parameterssupporting

confidence: 81%

Section: Defining a Scaling Studymentioning

confidence: 99%

Learnability scaling of quantum states: Restricted Boltzmann machines

et al. 2019

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“…This scaling relation has previously been identified in Ref. [26] in PQMC simulations of Ising-type models, again performed without a GWF. Next, we run DMC simulations with a GWF.…”

Section: B Tunneling Time In Diffusion Monte Carlo Simulationssupporting

confidence: 77%

Tunneling in projective quantum Monte Carlo simulations with guiding wave functions

et al. 2019

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Quantum tunneling is a valuable resource exploited by quantum annealers to solve complex optimization problems. Tunneling events also occur during projective quantum Monte Carlo (PQMC) simulations, and in a class of problems characterized by a double-well energy landscape their rate was found to scale linearly with the first energy gap, i.e., even more favorably than in physical quantum annealers, where the rate scales with the gap squared. Here we investigate how a guiding wave function -which is essential to make many-body PQMC simulations computationally feasible -affects the tunneling rate. The chosen testbeds are a continuous-space double-well problem, the ferromagnetic quantum Ising chain, and the recently introduced shamrock model. As guiding wave function, we consider an approximate Boltzmann-type ansatz, the numerically-exact ground state of the double-well model, and a neural-network wave function based on a Boltzmann machine. Remarkably, for each ansatz we find the same asymptotic linear scaling of the tunneling rate that was previously found in the PQMC simulations performed without a guiding wave function. We also provide a semiclassical theory for the double-well with exact guiding wave function that explains the observed linear scaling. These findings suggest that PQMC simulations guided by an accurate ansatz represent a valuable benchmark for physical quantum annealers and a potentially competitive quantum-inspired optimization technique.

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“…We note that the improved ground state fidelity does not stem from an increase of the minimal energy gap between ground and first excited state and cannot be understood in incoherent quantum annealing or with path integral Monte Carlo methods [66][67][68]. The additional counter-diabatic term rather compensates for the Berry curvature which causes transitions between eigenstates [30,52,69].…”

Section: Introductionmentioning

confidence: 92%

Rapid counter-diabatic sweeps in lattice gauge adiabatic quantum computing

Hartmann

Lechner

2019

New J. Phys.

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We present a coherent counter-diabatic quantum protocol to prepare ground states in the lattice gauge mapping of all-to-all Ising models (LHZ) with considerably enhanced final ground state fidelity compared to a quantum annealing protocol. We make use of a variational method to find approximate counter-diabatic Hamiltonians that has recently been introduced by Sels and Polkovnikov (2017 Proc. Natl. Acad. Sci. 114 3909). The resulting additional terms in our protocol are time-dependent local onsite y-magnetic fields. These additional Hamiltonian terms do not increase the minimal energy gap, but instead compensate for the Berry curvature. A single free parameter is introduced which is optimized via classical updates. The protocol consists only of local and nearest-neighbor terms which makes it attractive for implementation in near term experiments.

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Understanding quantum tunneling using diffusion Monte Carlo simulations

Cited by 17 publications

References 57 publications

Learnability scaling of quantum states: Restricted Boltzmann machines

Learnability scaling of quantum states: Restricted Boltzmann machines

Tunneling in projective quantum Monte Carlo simulations with guiding wave functions

Rapid counter-diabatic sweeps in lattice gauge adiabatic quantum computing

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