Quantum computing methods for electronic states of the water molecule

Bian, Teng; Murphy, Daniel C.; Xia, Rongxin; Daskin, Ammar; Kais, Sabre

doi:10.1080/00268976.2019.1580392

Cited by 47 publications

(44 citation statements)

References 48 publications

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“…A number of quantum algorithms have been developed which exhibit lower scaling than their classical counterparts [3][4][5], but emerging quantum hardware is far from being capable of long coherence times, arbitrary connectivity and low gate error, which are requirements for most of these algorithms. As a consequence, efforts to maximally utilize the available devices have taken inspiration from quantum and classical regimes alike [6][7][8][9][10]. In particular, hybrid quantum-classical algorithms have been developed, which attempt to separate efficiently quantum and classical components of a problem [11][12][13].…”

Section: Introductionmentioning

confidence: 99%

Quantum-classical hybrid algorithm using an error-mitigating N -representability condition to compute the Mott metal-insulator transition

Smart

Mazziotti

2019

Phys. Rev. A

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Quantum algorithms for molecular electronic structure have been developed with lower computational scaling than their classical counterparts, but emerging quantum hardware is far from being capable of the coherence, connectivity and gate errors required for their experimental realization. Here we propose a class of quantumclassical hybrid algorithms that compute the energy from a two-electron reduced density matrix (2-RDM). The 2-RDM is constrained by N-representability conditions, conditions for representing an N-electron wave function, that mitigates noise from the quantum circuit. We compute the strongly correlated dissociation of doublet H3 into three hydrogen atoms. The hybrid quantum-classical computer matches the energies from full configuration interaction to 0.1 kcal/mol, one-tenth of "chemical accuracy," even in the strongly correlated limit of dissociation. Furthermore, the spatial locality of the computed one-electron RDM reveals that the quantum computer accurately predicts the Mott metal-insulator transition.

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Section: Introductionmentioning

confidence: 99%

Quantum-classical hybrid algorithm using an error-mitigating N -representability condition to compute the Mott metal-insulator transition

Smart

Mazziotti

2019

Phys. Rev. A

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“…For H

, we use the Jordan–Wigner transformation [ 36 ] to get a 4-qubit Hamiltonian. We decided to apply the complete active space (CAS) approach [ 37 , 38 ], which divides the orbitals into inactive orbitals such as always occupied low energy orbitals and always unoccupied high energy orbitals, and active orbitals, to reduce the number of qubits of LiH and BeH

Hamiltonian [ 4 , 11 ] and the reduced Hamiltonian is only of the active orbitals. For LiH, we assume the first two lowest energy spin orbitals are always occupied and use the binary code transformation [ 39 ] considering spin symmetry to save two qubits.…”

Section: Resultsmentioning

confidence: 99%

“…Quantum computing has shown its great potential in advancing quantum chemistry research [ 1 ]. Many quantum algorithms have been proposed to solve quantum chemistry problems [ 2 , 3 , 4 ], such as the Phase Estimation Algorithm; Aspuru-Guzik et al [ 5 , 6 , 7 , 8 ] to calculate eigenstate energies of simple molecules; the Variational Quantum Eigensolver (VQE) [ 9 , 10 , 11 ] to solve electronic structure problems; quantum algorithms for open quantum dynamics [ 12 ]; and benchmark calculations for two-electron molecules conducted on quantum computers [ 13 ]. Using quantum computing techniques to perform machine learning tasks [ 14 ] has also received much attention recently including quantum data classification [ 15 , 16 ], quantum generative learning [ 17 , 18 ], and quantum neural network approximating nonlinear functions [ 19 ].…”

Section: Introductionmentioning

confidence: 99%

Hybrid Quantum-Classical Neural Network for Calculating Ground State Energies of Molecules

Xia

Kais

2020

Entropy

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We present a hybrid quantum-classical neural network that can be trained to perform electronic structure calculation and generate potential energy curves of simple molecules. The method is based on the combination of parameterized quantum circuits and measurements. With unsupervised training, the neural network can generate electronic potential energy curves based on training at certain bond lengths. To demonstrate the power of the proposed new method, we present the results of using the quantum-classical hybrid neural network to calculate ground state potential energy curves of simple molecules such as H2, LiH, and BeH2. The results are very accurate and the approach could potentially be used to generate complex molecular potential energy surfaces.

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“…Variational quantum eigensolver [10,11] is generally applied to the quantum chemistry problems that are represented by the electronic Hamiltonian in the second quantization by transforming the Hamiltonian to the sum of Pauli operators, which are the products of the Pauli spin matrices(e.g. [7,17,18]). Assume the electronic Hamiltonian is H = i h i H i , where H i is a Pauli operator and h i is the corresponding coefficient.…”

Section: B Use In Variational Quantum Eigensolvermentioning

confidence: 99%

“…4 shows the ground state energy curve of H 2 obtained by the simulation based on this modified VQE. In the simulation, the 4-qubit Hamiltonian of H 2 is calculated by openfermion package [20] using STO-3G basis set, and the hardware-efficient ansatz is prepared by 3layer pairwise design in [7].…”

Section: B Use In Variational Quantum Eigensolvermentioning

confidence: 99%

Context-aware quantum simulation of a matrix stored in quantum memory

Daskin

Bian

Xia

et al. 2019

Quantum Inf Process

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In this paper a storage method and a context-aware circuit simulation idea are presented for the sum of block diagonal matrices. Using the design technique for a generalized circuit for the Hamiltonian dynamics through the truncated series, we generalize the idea to (0-1) matrices and discuss the generalization for the real matrices. The presented circuit requires O(n) number of quantum gates and yields the correct output with the success probability depending on the number of elements: for matrices with poly(n), the success probability is 1/poly(n). Since the operations on the circuit are controlled by the data itself, the circuit can be considered as a context aware computing gadget. In addition, it can be used in variational quantum eigensolver and in the simulation of molecular Hamiltonians.

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Quantum computing methods for electronic states of the water molecule

Cited by 47 publications

References 48 publications

Quantum-classical hybrid algorithm using an error-mitigating N -representability condition to compute the Mott metal-insulator transition

Quantum-classical hybrid algorithm using an error-mitigating N -representability condition to compute the Mott metal-insulator transition

Hybrid Quantum-Classical Neural Network for Calculating Ground State Energies of Molecules

Context-aware quantum simulation of a matrix stored in quantum memory

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