Quantum simulation approach to implementing nuclear density functional theory via imaginary time evolution

Li, Yang Hong; Al-Khalili, Jim; Stevenson, Paul

doi:10.1103/physrevc.109.044322

Phys. Rev. C

2024

DOI: 10.1103/physrevc.109.044322

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Quantum simulation approach to implementing nuclear density functional theory via imaginary time evolution

Yang Hong Li,

Jim Al-Khalili,

Paul Stevenson

Abstract: The quantum imaginary time evolution (QITE) algorithm is a direct implementation of the classical imaginary time evolution algorithm on quantum computer. We implement the QITE algorithm for the case of nuclear Hartree-Fock equations in a formalism equivalent to nuclear density functional theory. We demonstrate the algorithm in the case of the helium-4 nucleus with a simplified effective interaction of the Skyrme kind and demonstrate that the QITE, as implemented on simulated quantum computer, gives identical r… Show more

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Cited by 3 publications

References 53 publications

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Real-time chiral dynamics at finite temperature from quantum simulation

Ikeda,

Kang,

Kharzeev

et al. 2024

J. High Energ. Phys.

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In this study, we explore the real-time dynamics of the chiral magnetic effect (CME) at a finite temperature in the (1+1)-dimensional QED, the massive Schwinger model. By introducing a chiral chemical potential μ5 through a quench process, we drive the system out of equilibrium and analyze the induced vector currents and their evolution over time. The Hamiltonian is modified to include the time-dependent chiral chemical potential, thus allowing the investigation of the CME within a quantum computing framework. We employ the quantum imaginary time evolution (QITE) algorithm to study the thermal states, and utilize the Suzuki-Trotter decomposition for the real-time evolution. This study provides insights into the quantum simulation capabilities for modeling the CME and offers a pathway for studying chiral dynamics in low-dimensional quantum field theories.

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Real-time chiral dynamics at finite temperature from quantum simulation

Ikeda,

Kang,

Kharzeev

et al. 2024

J. High Energ. Phys.

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Shell-model study of⁵⁸Ni using quantum computing algorithm

Bhoy,

Stevenson

2024

New J. Phys.

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This study presents a simulated quantum computing approach for the investigation into the shell-model energy levels of 58Ni through the application of the variational quantum eigensolver (VQE) method in combination with a problem-specific ansatz. The primary objective is to achieve a fully accurate low-lying energy spectrum of 58Ni. The chosen isotope, 58Ni is particularly interesting in nuclear physics through its role in astrophysical reactions while also being a simple but non-trivial nucleus for shell-model study, it being two particles outside a closed shell. Our ansatz, along with the VQE method are shown to be able to reproduce exact energy values for the ground state and first and second excited states. We compare a classical shell model code, the values obtained by diagonalization of the Hamiltonian after qubit mapping, and a noiseless simulated ansatz+VQE simulation. The exact agreement between classical and qubit-mapped diagonalization shows the correctness of our method, and the high accuracy of the simulation means that the ansatz is suitable to allow a full reconstruction of the full nuclear wave function.

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Solving coupled non-linear schrödinger equations via quantum imaginary time evolution

Li,

Al-Khalili,

Stevenson

2024

Eur. Phys. J. Spec. Top.

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Coupled non-linear Schrödinger equations are crucial in describing dynamics of many-particle systems. We present a quantum imaginary time evolution (ITE) algorithm as a solution to such equations in the case of nuclear Hartree-Fock approach. Under a simplified Skyrme interaction model, we calculate the ground state energy of an oxygen-16 nucleus and demonstrate that the result is in agreement with the classical ITE algorithm. We examine bottlenecks and deficiencies in the quantum algorithm and suggest possible improvements.

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Quantum simulation approach to implementing nuclear density functional theory via imaginary time evolution

Cited by 3 publications

References 53 publications

Real-time chiral dynamics at finite temperature from quantum simulation

Real-time chiral dynamics at finite temperature from quantum simulation

Shell-model study of⁵⁸Ni using quantum computing algorithm

Solving coupled non-linear schrödinger equations via quantum imaginary time evolution

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Quantum simulation approach to implementing nuclear density functional theory via imaginary time evolution

Cited by 3 publications

References 53 publications

Real-time chiral dynamics at finite temperature from quantum simulation

Real-time chiral dynamics at finite temperature from quantum simulation

Shell-model study of58Ni using quantum computing algorithm

Solving coupled non-linear schrödinger equations via quantum imaginary time evolution

Contact Info

Product

Resources

About

Shell-model study of⁵⁸Ni using quantum computing algorithm