Excited-State Spectra of Strongly Correlated Molecules from a Reduced-Density-Matrix Approach

Hemmatiyan, Shayan; Sajjan, Manas; Schlimgen, Anthony W.; Mazziotti, David A.

doi:10.1021/acs.jpclett.8b02455

Cited by 15 publications

(22 citation statements)

References 33 publications

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“…We treat the excited-state energies from a version of the ES-RDM method, 26 known as the Hermitian operator method, in which the Hermitian combination of single excitations is employed to construct an effective Hamiltonian and an overlap matrix from only the knowledge of the ground-state 2-RDM. [26][27][28][29][30][31]33,34 The ES-RDM method uses regularization of the effective Hamiltonian to remove ill-conditioning in the eigenvalue equation. 26 Although the ES-RDM method generates excited-state energies from the 2-RDM from any correlated ground-state method, we employ 2-RDMs from the variational 2-RDM (v2-RDM) method.…”

Section: ■ Methodsmentioning

confidence: 99%

Unraveling the Band Gap Trend in the Narrowest Graphene Nanoribbons from the Spin-Adapted Excited-Spectra Reduced Density Matrix Method

Hemmatiyan

Mazziotti

2019

J. Phys. Chem. C

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Polybenzenes as the narrowest graphene nanoribbons with versatile electronic properties are widely studied both theoretically and technologically. Here, we examine the singlet–triplet band gap as a function of length for two members of the oligobenzene family: the acene and phenacene chains. We observe that the prediction of the band gap is highly sensitive to the accurate treatment of the electron correlation. The excited-spectra two-electron reduced density matrix (2-RDM) method, which computes the excited states from a variationally computed ground-state 2-RDM, yields finite band gaps for all finite chain lengths through 10 rings as well as in the extrapolated infinite ring limits of both acenes and phenacenes. In contrast, we find that weakly correlated methods like configuration interaction singles and time-dependent density functional theory predict a crossing of the singlet- and triplet-state energies of the acene chains at a finite ring size, with the triplet becoming the energetically lowest state at longer chain lengths. Recent experiments through decacene and 9-phenacene agree with the correlated 2-RDM calculations, showing that both acene and phenacene chains in the large polymer limit possess finite band gaps.

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Section: ■ Methodsmentioning

confidence: 99%

Unraveling the Band Gap Trend in the Narrowest Graphene Nanoribbons from the Spin-Adapted Excited-Spectra Reduced Density Matrix Method

Hemmatiyan

Mazziotti

2019

J. Phys. Chem. C

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“…n ]] |0 may not be Hermitian, the double commutator of the right-hand side is Hermitian. Note that this expression differs from the one derived for QSE [26] in two points: (i) due to the commutator form, the operators in the numerator and denominator are Hermitian allowing for a systematic reduction of the number of terms to evaluate thanks to the use of the Pauli commutation relations [36], and (ii) the solution of the EOM equations leads directly to the excitation energies rather than the absolute energies, making the approach size intensive (contrary to QSE, which is not size intensive). The EOM approach aims at finding approximate solutions to Eq.…”

Section: Theoretical Foundationmentioning

confidence: 94%

Quantum equation of motion for computing molecular excitation energies on a noisy quantum processor

Ollitrault

Kandala

Chen

et al. 2020

Phys. Rev. Research

191

202

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“…Deflation has been the cornerstone of many classical algorithms in the past for obtaining excited states 63,64 and even a quantum algorithm as well with UCC-VQE. 65 But the formal reduction of our penalty procedure in Eq.S1 based on Theorem 2.1 to deflation offers a slightly different perspective.…”

Section: Filter For Specific Excited Statesmentioning

confidence: 99%

Quantum Machine-Learning for Eigenstate Filtration in Two-Dimensional Materials

2021

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Quantum machine learning algorithms have emerged to be a promising alternative to their classical counterparts as they leverage the power of quantum computers. Such algorithms have been developed to solve problems like electronic structure calculations of molecular systems and spin models in magnetic systems. However the discussion in all these recipes focus specifically on targeting the ground state. Herein we demonstrate a quantum algorithm that can filter any energy eigenstate of the system based on either symmetry properties or on a predefined choice of the user. The work horse of our technique is a shallow neural network encoding the desired state of the system with the amplitude computed by sampling the Gibbs-Boltzmann distribution using a quantum circuit and the phase information obtained classically from the non-linear activation of a separate set of neurons. We show that the resource requirements of our algorithm is strictly quadratic. To demonstrate its efficacy, we use state-filtration in monolayer transition metal-dichalcogenides which are hitherto unexplored in any flavor of quantum 1 arXiv:2105.09488v1 [physics.chem-ph] 20 May 2021 simulations. We implement our algorithm not only on quantum simulators but also on actual IBM-Q quantum devices and show good agreement with the results procured from conventional electronic structure calculations. We thus expect our protocol to provide a new alternative in exploring band-structures of exquisite materials to usual electronic structure methods or machine learning techniques which are implementable solely on a classical computer.

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Excited-State Spectra of Strongly Correlated Molecules from a Reduced-Density-Matrix Approach

Cited by 15 publications

References 33 publications

Unraveling the Band Gap Trend in the Narrowest Graphene Nanoribbons from the Spin-Adapted Excited-Spectra Reduced Density Matrix Method

Unraveling the Band Gap Trend in the Narrowest Graphene Nanoribbons from the Spin-Adapted Excited-Spectra Reduced Density Matrix Method

Quantum equation of motion for computing molecular excitation energies on a noisy quantum processor

Quantum Machine-Learning for Eigenstate Filtration in Two-Dimensional Materials

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