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Main Authors: Motlagh, Danial, Lang, Robert A., Jain, Paarth, Campos-Gonzalez-Angulo, Jorge A., Maxwell, William, Zeng, Tao, Aspuru-Guzik, Alan, Arrazola, Juan Miguel
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2411.13669
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author Motlagh, Danial
Lang, Robert A.
Jain, Paarth
Campos-Gonzalez-Angulo, Jorge A.
Maxwell, William
Zeng, Tao
Aspuru-Guzik, Alan
Arrazola, Juan Miguel
author_facet Motlagh, Danial
Lang, Robert A.
Jain, Paarth
Campos-Gonzalez-Angulo, Jorge A.
Maxwell, William
Zeng, Tao
Aspuru-Guzik, Alan
Arrazola, Juan Miguel
contents Vibronic interactions between nuclear motion and electronic states are critical for the accurate modeling of photochemistry. However, accurate simulations of fully quantum non-adiabatic dynamics are often prohibitively expensive for classical methods beyond small systems. In this work, we present a quantum algorithm based on product formulas for simulating time evolution under a general vibronic Hamiltonian in real space, capable of handling an arbitrary number of electronic states and vibrational modes. We develop the first trotterization scheme for vibronic Hamiltonians beyond two electronic states and introduce an array of optimization techniques for the exponentiation of each fragment in the product formula, resulting in a remarkably low cost of implementation. To demonstrate practical relevance, we outline a proof-of-principle integration of our algorithm into a materials discovery pipeline for designing more efficient singlet fission-based organic solar cells. We estimate that $100$ fs of propagation using a second-order Trotter product formula for a $6$-state, $21$-mode model of exciton transport at an anthracene dimer requires $154$ qubits and $2.76 \times 10^6$ Toffoli gates. While a $4$-state, $246$-mode model describing charge transfer at an anthracene-fullerene interface requires $1053$ qubits and $2.66 \times 10^7$ Toffoli gates.
format Preprint
id arxiv_https___arxiv_org_abs_2411_13669
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Quantum Algorithm for Vibronic Dynamics: Case Study on Singlet Fission Solar Cell Design
Motlagh, Danial
Lang, Robert A.
Jain, Paarth
Campos-Gonzalez-Angulo, Jorge A.
Maxwell, William
Zeng, Tao
Aspuru-Guzik, Alan
Arrazola, Juan Miguel
Quantum Physics
Vibronic interactions between nuclear motion and electronic states are critical for the accurate modeling of photochemistry. However, accurate simulations of fully quantum non-adiabatic dynamics are often prohibitively expensive for classical methods beyond small systems. In this work, we present a quantum algorithm based on product formulas for simulating time evolution under a general vibronic Hamiltonian in real space, capable of handling an arbitrary number of electronic states and vibrational modes. We develop the first trotterization scheme for vibronic Hamiltonians beyond two electronic states and introduce an array of optimization techniques for the exponentiation of each fragment in the product formula, resulting in a remarkably low cost of implementation. To demonstrate practical relevance, we outline a proof-of-principle integration of our algorithm into a materials discovery pipeline for designing more efficient singlet fission-based organic solar cells. We estimate that $100$ fs of propagation using a second-order Trotter product formula for a $6$-state, $21$-mode model of exciton transport at an anthracene dimer requires $154$ qubits and $2.76 \times 10^6$ Toffoli gates. While a $4$-state, $246$-mode model describing charge transfer at an anthracene-fullerene interface requires $1053$ qubits and $2.66 \times 10^7$ Toffoli gates.
title Quantum Algorithm for Vibronic Dynamics: Case Study on Singlet Fission Solar Cell Design
topic Quantum Physics
url https://arxiv.org/abs/2411.13669