Dynamical Simulations of Carotenoid Photoexcited States Using Density Matrix Renormalization Group Techniques

Manawadu, Dilhan; Valentine, D. J.; Barford, William

doi:10.1021/acs.jpca.3c00988

J. Phys. Chem. A

2023

DOI: 10.1021/acs.jpca.3c00988

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Dynamical Simulations of Carotenoid Photoexcited States Using Density Matrix Renormalization Group Techniques

Dilhan Manawadu

D. J. Valentine

William Barford

Abstract: We present a dynamical simulation scheme to model the highly correlated excited state dynamics of linear polyenes. We apply it to investigate the internal conversion processes of carotenoids following their photoexcitation. We use the extended Hubbard-Peierls model, H UVP , to describe the π-electronic system coupled to nuclear degrees of freedom. This is supplemented by a Hamiltonian, H , that explicitly breaks both the particle-hole and two-fold rotation symmetries of idealized carotenoid structures. The ele… Show more

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Cited by 4 publications

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References 114 publications

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“…Using time-dependent DMRG calculations of the Hubbard-UV-Peierls model, Manawadu and co-workers , simulated the internal conversion from the bright state in the related carotenoid, zeaxanthin. Zeaxanthin has 18 conjugated C atoms (i.e., 9 double bonds) and, like lycopene (shown in Figure ), possesses C 2 h symmetry.…”

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Singlet Fission in Lycopene H-Aggregates

Barford

2023

J. Phys. Chem. Lett.

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A theory of singlet fission (SF) in carotenoid dimers is applied to explain the SF in lycopene H-aggregates observed after high-energy photoexcitation. The explanation proposed here is that a high energy, delocalized bright 1 B u + state first relaxes and localizes onto a single lycopene monomer. The high-energy intramonomer state then undergoes internal conversion to the 1 1 B u − state. Once populated, the 1 1 B u − state allows exothermic bimolecular singlet fission, while its internal conversion to the 2 1 A g − state is symmetry forbidden. The simulation of SF predicts that the intramonomer triplet-pair state undergoes almost complete population transfer to the intermonomer singlet-pair state within 100 ps. Simultaneously, ZFS interactions begin to partially populate the intermonomer quintet triplet-pair state up to ca. 2 ns, after which hyperfine interactions thermally equilibrate the triplet-pair states, thus forming free single triplets within 50 ns.

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Singlet Fission in Lycopene H-Aggregates

Barford

2023

J. Phys. Chem. Lett.

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Photoexcited State Dynamics and Singlet Fission in Carotenoids

Manawadu

Barford

2023

J. Phys. Chem. A

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We describe our simulations of the excited state dynamics of the carotenoid neurosporene, following its photoexcitation into the "bright" (nominally 1 1 B u + ) state. To account for the experimental and theoretical uncertainty in the relative energetic ordering of the nominal 1 1 B u + and 2 1 A g − states at the Franck−Condon point, we consider two parameter sets. In both cases, there is ultrafast internal conversion from the "bright" state to a "dark" singlet triplet-pair state, i.e., to one member of the "2A g " family of states. For one parameter set, internal conversion from the 1 1 B u + to 2 1 A g − states occurs via the dark, intermediate 1 1 B u − state. In this case, there is a cross over of the 1 1 B u + and 1 1 B u − diabatic energies within 5 fs and an associated avoided crossing of the S 2 and S 3 adiabatic energies. After the adiabatic evolution of the S 2 state from predominately 1 1 B u + character to predominately 1 1 B u − character, there is a slower nonadiabatic transition from S 2 to S 1 , accompanied by an increase in the population of the 2 1 A g − state. For the other parameter set, the 2 1 A g − energy lies higher than the 1 1 B u + energy at the Franck−Condon point. In this case, there is cross over of the 2 1 A g − and 1 1 B u + energies and an avoided crossing of the S 1 and S 2 energies, as the S 1 state evolves adiabatically from being of 1 1 B u + character to 2 1 A g − character. We make a direct connection from our predictions to experimental observables by calculating the time-resolved excited state absorption. For the case of direct 1 1 B u + to 2 1 A g − internal conversion, we show that the dominant transition at ca. 2 eV, being close to but lower in energy than the T 1 to T 1 * transition, can be attributed to the 2 1 A g − component of S 1 . Moreover, we show that it is the charge-transfer exciton component of the 2 1 A g − state that is responsible for this transition (to a higher-lying exciton state), and not its triplet-pair component. These simulations are performed using the adaptive tDMRG method on the extended Hubbard model of π-conjugated electrons. The Ehrenfest equations of motion are used to simulate the coupled nuclei dynamics. We next discuss the microscopic mechanism of "bright" to "dark" state internal conversion and emphasize that this occurs via the exciton components of both states. Finally, we describe a mechanism relying on torsional relaxation whereby the strongly bound intrachain triplet-pairs of the "dark" state may undergo interchain exothermic dissociation.

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Theory of singlet fission in carotenoid dimers

Barford,

Chambers

2023

The Journal of Chemical Physics

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We develop a theory of singlet fission in carotenoid dimers. Following photoexcitation of the “bright” state (i.e., a singlet electron–hole pair) in a single carotenoid, the first step in the singlet fission process is ultrafast intramolecular conversion into the highly correlated “dark” (or 2Ag) state. This state has both entangled singlet triplet-pair and charge-transfer character. Our theory is predicated on the assumption that it is the singlet triplet-pair component of the “dark” state that undergoes bimolecular singlet fission. We use valence bond theory to develop a minimal two-chain model of the triplet-pair states. The single and double chain triplet-pair spectra are described, as this helps explain the dynamics and the equilibrated populations. We simulate the dynamics of the initial entangled pair state using the quantum Liouville equation, including both spin-conserving and spin-nonconserving dephasing processes. By computing the intrachain and interchain singlet, triplet, and quintet triplet-pair populations, we show that singlet fission critically depends on the interchain coupling and the driving potential (that determines endothermic vs exothermic fission).

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Dynamical Simulations of Carotenoid Photoexcited States Using Density Matrix Renormalization Group Techniques

Cited by 4 publications

References 114 publications

Singlet Fission in Lycopene H-Aggregates

Singlet Fission in Lycopene H-Aggregates

Photoexcited State Dynamics and Singlet Fission in Carotenoids

Theory of singlet fission in carotenoid dimers

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