Related papers: Boson sampling enhanced quantum chemistry

Boson sampling enhanced quantum chemistry

URL: http://arxiv.org/abs/2403.16698v2
Date: Thu, 18 Apr 2024 06:17:26 GMT
Title: Boson sampling enhanced quantum chemistry
Authors: Zhong-Xia Shang, Han-Sen Zhong, Yu-Kun Zhang, Cheng-Cheng Yu, Xiao Yuan, Chao-Yang Lu, Jian-Wei Pan, Ming-Cheng Chen,
Abstract summary: We give a hybrid quantum-classical algorithm for solving electronic structure problems of molecules using only linear quantum optical systems. The variational ansatz we proposed is a hybrid of non-interacting Boson dynamics and classical computational chemistry methods.
Score: 2.9658894202299626
License: http://creativecommons.org/licenses/by/4.0/
Abstract: In this work, we give a hybrid quantum-classical algorithm for solving electronic structure problems of molecules using only linear quantum optical systems. The variational ansatz we proposed is a hybrid of non-interacting Boson dynamics and classical computational chemistry methods, specifically, the Hartree-Fock method and the Configuration Interaction method. The Boson part is built by a linear optical interferometer which is easier to realize compared with the well-known Unitary Coupled Cluster (UCC) ansatz composed of quantum gates in conventional VQE and the classical part is merely classical processing acting on the Hamiltonian. We called such ansatzes Boson Sampling-Classic (BS-C). The appearance of permanents in the Boson part has its physical intuition to provide different kinds of resources from commonly used single-, double-, and higher-excitations in classical methods and the UCC ansatz to exploring chemical quantum states. Such resources can help enhance the accuracy of methods used in the classical parts. We give a scalable hybrid homodyne and photon number measurement procedure for evaluating the energy value which has intrinsic abilities to mitigate photon loss errors and discuss the extra measurement cost induced by the no Pauli exclusion principle for Bosons with its solutions. To demonstrate our proposal, we run numerical experiments on several molecules and obtain their potential energy curves reaching chemical accuracy.

Related papers

Solving an Industrially Relevant Quantum Chemistry Problem on Quantum Hardware [31.15746974078601]
We calculate the lowest energy eigenvalue of active space Hamiltonians of industrially relevant and strongly correlated metal chelates on trapped ion quantum hardware. We are able to achieve chemical accuracy by training a variational quantum algorithm on quantum hardware, followed by a classical diagonalization in the subspace of states measured as outputs of the quantum circuit.
arXiv Detail & Related papers (2024-08-20T12:50:15Z)
Non-unitary Coupled Cluster Enabled by Mid-circuit Measurements on Quantum Computers [37.69303106863453]
We propose a state preparation method based on coupled cluster (CC) theory, which is a pillar of quantum chemistry on classical computers. Our approach leads to a reduction of the classical computation overhead, and the number of CNOT and T gates by 28% and 57% on average.
arXiv Detail & Related papers (2024-06-17T14:10:10Z)
A Theory of Quantum Jumps [44.99833362998488]
We study fluorescence and the phenomenon of quantum jumps'' in idealized models of atoms coupled to the quantized electromagnetic field. Our results amount to a derivation of the fundamental randomness in the quantum-mechanical description of microscopic systems.
arXiv Detail & Related papers (2024-04-16T11:00:46Z)
Exact Ansatz of Fermion-Boson Systems for a Quantum Device [5.915403570478968]
An exact ansatz for the eigenstate problem of mixed fermion-boson systems can be implemented on quantum devices. Our results demonstrate that the CSE is a powerful tool in the development of quantum algorithms for solving general fermion-boson many-body problems.
arXiv Detail & Related papers (2024-02-19T16:38:57Z)
Solving the Lipkin model using quantum computers with two qubits only with a hybrid quantum-classical technique based on the Generator Coordinate Method [0.0]
We discuss the possibility of using the generator coordinate method (GCM) using hybrid quantum-classical algorithms with reduced quantum resources. We show that, ultimately, only two qubits is enough to solve the problem regardless of the particle number. As an alternative to this technique, we also explored how the quantum state deflation method can be adapted to the GCM problem.
arXiv Detail & Related papers (2023-12-07T21:18:27Z)
Simulating polaritonic ground states on noisy quantum devices [0.0]
We introduce a general framework for simulating electron-photon coupled systems on small, noisy quantum devices. To achieve chemical accuracy, we exploit various symmetries in qubit reduction methods. We measure two properties: ground-state energy, fundamentally relevant to chemical reactivity, and photon number.
arXiv Detail & Related papers (2023-10-03T14:45:54Z)
Quantum Information Driven Ansatz (QIDA): shallow-depth empirical quantum circuits from Quantum Chemistry [0.0]
We propose a new approach for constructing variational quantum circuits, leveraging quantum mutual information associated with classical Quantum Chemistry states. The proposed methodology gives rise to highly effective ans"atze, surpassing the standard empirical ladder-entangler ansatz in performance.
arXiv Detail & Related papers (2023-09-26T21:50:02Z)
Physics-Informed Neural Networks for an optimal counterdiabatic quantum computation [32.73124984242397]
We introduce a novel methodology that leverages the strength of Physics-Informed Neural Networks (PINNs) to address the counterdiabatic (CD) protocol in the optimization of quantum circuits comprised of systems with $N_Q$ qubits. The main applications of this methodology have been the $mathrmH_2$ and $mathrmLiH$ molecules, represented by a 2-qubit and 4-qubit systems employing the STO-3G basis.
arXiv Detail & Related papers (2023-09-08T16:55:39Z)
A Hybrid Quantum-Classical Method for Electron-Phonon Systems [40.80274768055247]
We develop a hybrid quantum-classical algorithm suitable for this type of correlated systems. This hybrid method tackles with arbitrarily strong electron-phonon coupling without increasing the number of required qubits and quantum gates. We benchmark the new method by applying it to the paradigmatic Hubbard-Holstein model at half filling, and show that it correctly captures the competition between charge density wave and antiferromagnetic phases.
arXiv Detail & Related papers (2023-02-20T08:08:51Z)
Quantum-Classical Hybrid Algorithm for the Simulation of All-Electron Correlation [58.720142291102135]
We present a novel hybrid-classical algorithm that computes a molecule's all-electron energy and properties on the classical computer. We demonstrate the ability of the quantum-classical hybrid algorithms to achieve chemically relevant results and accuracy on currently available quantum computers.
arXiv Detail & Related papers (2021-06-22T18:00:00Z)
Quantum limit-cycles and the Rayleigh and van der Pol oscillators [0.0]
Self-oscillating systems are emerging as canonical models for driven dissipative nonequilibrium open quantum systems. We derive an exact analytical solution for the steady-state quantum dynamics of the simplest of these models. Our solution is a generalization to arbitrary temperature of existing solutions for very-low, or zero, temperature.
arXiv Detail & Related papers (2020-11-05T08:51:51Z)

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