Quantum chemistry beyond Born-Oppenheimer approximation on a quantum computer: A simulated phase estimation study

The well-known algorithm for quantum phase estimation requires that the considered unitary is available as a conditional transformation depending on the quantum state of an ancilla register. We present an algorithm converting an unknown n-qubit pair-interaction Hamiltonian into a conditional one such that standard phase estimation can be applied to measure the energy. Our essential assumption is that the considered system can be brought into interaction with a quantum computer. For large n the algorithm could still be applicable for estimating the density of energy states and might therefore be useful for finding energy gaps in solid states.

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Qubit Coupled Cluster Method: A Systematic Approach to Quantum Chemistry on a Quantum Computer

Journal of Chemical Theory and Computation ◽

10.1021/acs.jctc.8b00932 ◽

2018 ◽

Vol 14 (12) ◽

pp. 6317-6326 ◽

Cited By ~ 30

Author(s):

Ilya G. Ryabinkin ◽

Tzu-Ching Yen ◽

Scott N. Genin ◽

Artur F. Izmaylov

Keyword(s):

Quantum Chemistry ◽

Systematic Approach ◽

Quantum Computer ◽

Cluster Method ◽

Coupled Cluster ◽

Coupled Cluster Method

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Quantum simulation of chemistry with sublinear scaling in basis size

npj Quantum Information ◽

10.1038/s41534-019-0199-y ◽

2019 ◽

Vol 5 (1) ◽

Cited By ~ 14

Author(s):

Ryan Babbush ◽

Dominic W. Berry ◽

Jarrod R. McClean ◽

Hartmut Neven

Keyword(s):

Electronic Structure ◽

Plane Wave ◽

Quantum Chemistry ◽

Plane Waves ◽

Quantum Algorithm ◽

Discretization Error ◽

Rotating Frame ◽

Interaction Picture ◽

Basis Size ◽

Oppenheimer Approximation

Abstract We present a quantum algorithm for simulating quantum chemistry with gate complexity $$\tilde {\cal{O}}(N^{1/3}\eta ^{8/3})$$ O ̃ ( N 1 ∕ 3 η 8 ∕ 3 ) where η is the number of electrons and N is the number of plane wave orbitals. In comparison, the most efficient prior algorithms for simulating electronic structure using plane waves (which are at least as efficient as algorithms using any other basis) have complexity $$\tilde {\cal{O}}(N^{8/3}{\mathrm{/}}\eta ^{2/3})$$ O ̃ ( N 8 ∕ 3 ∕ η 2 ∕ 3 ) . We achieve our scaling in first quantization by performing simulation in the rotating frame of the kinetic operator using interaction picture techniques. Our algorithm is far more efficient than all prior approaches when N ≫ η, as is needed to suppress discretization error when representing molecules in the plane wave basis, or when simulating without the Born-Oppenheimer approximation.

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A Full Quantum Eigensolver for Quantum Chemistry Simulations

Research ◽

10.34133/2020/1486935 ◽

2020 ◽

Vol 2020 ◽

pp. 1-11 ◽

Cited By ~ 7

Author(s):

Shijie Wei ◽

Hang Li ◽

GuiLu Long

Keyword(s):

Quantum Computing ◽

Quantum Chemistry ◽

Gradient Descent ◽

Materials Science ◽

Hybrid Methods ◽

Quantum Computer ◽

Rapid Development ◽

System Size ◽

Near Term ◽

Full Quantum

Quantum simulation of quantum chemistry is one of the most compelling applications of quantum computing. It is of particular importance in areas ranging from materials science, biochemistry, and condensed matter physics. Here, we propose a full quantum eigensolver (FQE) algorithm to calculate the molecular ground energies and electronic structures using quantum gradient descent. Compared to existing classical-quantum hybrid methods such as variational quantum eigensolver (VQE), our method removes the classical optimizer and performs all the calculations on a quantum computer with faster convergence. The gradient descent iteration depth has a favorable complexity that is logarithmically dependent on the system size and inverse of the precision. Moreover, the FQE can be further simplified by exploiting a perturbation theory for the calculations of intermediate matrix elements and obtaining results with a precision that satisfies the requirement of chemistry application. The full quantum eigensolver can be implemented on a near-term quantum computer. With the rapid development of quantum computing hardware, the FQE provides an efficient and powerful tool to solve quantum chemistry problems.

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Quantum Chemistry on a Quantum Computer: First Steps and Prospects

Frontiers in Optics 2009/Laser Science XXV/Fall 2009 OSA Optics & Photonics Technical Digest ◽

10.1364/fio.2009.jwd3 ◽

2009 ◽

Author(s):

B. P. Lanyon ◽

J. D. Whitfield ◽

G. G. Gillett ◽

M. E. Goggin ◽

M. P. Almeida ◽

...

Keyword(s):

Quantum Chemistry ◽

Quantum Computer

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Quantum chemistry beyond the Born-Oppenheimer approximation

Journal of Molecular Structure THEOCHEM ◽

10.1016/0166-1280(91)85170-c ◽

1991 ◽

Vol 230 ◽

pp. 17-46 ◽

Cited By ~ 42

Author(s):

R.G. Woolley

Keyword(s):

Quantum Chemistry ◽

Oppenheimer Approximation

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Optimizing qubit resources for quantum chemistry simulations in second quantization on a quantum computer

Journal of Physics A Mathematical and Theoretical ◽

10.1088/1751-8113/49/29/295301 ◽

2016 ◽

Vol 49 (29) ◽

pp. 295301 ◽

Cited By ~ 27

Author(s):

Nikolaj Moll ◽

Andreas Fuhrer ◽

Peter Staar ◽

Ivano Tavernelli

Keyword(s):

Quantum Chemistry ◽

Quantum Computer ◽

Second Quantization

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Corrected quantum walk for optimal Hamiltonian simulation

Quantum Information and Computation ◽

10.26421/qic16.15-16-3 ◽

2016 ◽

Vol 16 (15&16) ◽

pp. 1295-1317

Author(s):

Dominic Berry ◽

Leonardo Novo

Keyword(s):

Lower Bound ◽

Quantum Chemistry ◽

Taylor Series ◽

Quantum Computer ◽

Quantum Walk ◽

Query Complexity ◽

Hamiltonian Simulation ◽

Hamiltonian Evolution

We describe a method to simulate Hamiltonian evolution on a quantum computer by repeatedly using a superposition of steps of a quantum walk, then applying a correction to the weightings for the numbers of steps of the quantum walk. This correction enables us to obtain complexity which is the same as the lower bound up to doublelogarithmic factors for all parameter regimes. The scaling of the query complexity is given. This technique should also be useful for improving the scaling of the Taylor series approach to simulation, which is relevant to applications such as quantum chemistry.

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Quantum algorithm for measuring the eigenvalues of UÄU-1 for a black-box unitary transformation U

Quantum Information and Computation ◽

10.26421/qic2.3-2 ◽

2002 ◽

Vol 2 (3) ◽

pp. 192-197

Author(s):

D. Janzing ◽

T. Beth

Keyword(s):

Energy Spectrum ◽

Quantum System ◽

Autocorrelation Function ◽

Unitary Transformation ◽

Quantum Computer ◽

Quantum Algorithm ◽

Black Box ◽

Phase Estimation

Estimating the eigenvalues of a unitary transformation U by standard phase estimation requires the implementation of controlled-U-gates which are not available if U is only given as a black box. We show that a simple trick allows to measure eigenvalues of U\otimesU^\deggar even in this case. Running the algorithm several times allows therefore to estimate the autocorrelation function of the density of eigenstates of U. This can be applied to find periodicities in the energy spectrum of a quantum system with unknown Hamiltonian if it can be coupled to a quantum computer.

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Evaluating Energy Differences on a Quantum Computer with Robust Phase Estimation

Physical Review Letters ◽

10.1103/physrevlett.126.210501 ◽

2021 ◽

Vol 126 (21) ◽

Author(s):

A. E. Russo ◽

K. M. Rudinger ◽

B. C. A. Morrison ◽

A. D. Baczewski

Keyword(s):

Quantum Computer ◽

Phase Estimation

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