Effect of phonon scattering on exciton transport in solid pentacene
ORAL
Abstract
Exciton decay and diffusion mechanisms are rooted in material structure and linked to the electronic, excitonic,
and phononic bandstructures. These processes underlie energy transfer and the associated functionality
of energy conversion, as they determine state coherence and lifetime in excitonic materials. These properties are
broadly explored by spatiotemporal spectroscopy and are commonly understood within a kinetic rate equation
picture. A theoretical understanding of the underlying mechanisms and structural origins dominating the associated
rates from first principles is still lacking, and of emerging interest. In this study we present a many-body
perturbation theory scheme to describe exciton transport in solid pentacene. Starting from the GW and Bethe
Salpeter equation (GW-BSE) formalism combined with Density Functional Perturbation Theory (DFPT), we
compute exciton-phonon coupling from ab initio, and the associated phonon-mediated exciton scattering. We
apply our approach on the pentacene molecular crystal to study bright-to-dark exciton transitions as a pathway
to increased efficiency of nonradiative decay processes in this system. We derive a detailed kinetic description
of the intra- and inter-state exciton-phonon scattering, and analyze the exciton propagation upon these relaxation
pathways. We use our results to extend our recent work [1] and trace the relation between the exciton
wavepacket propagation in both the ballistic and the diffusive regimes to crystal symmetry and anisotropy.
[1] D. Y. Qiu, G. Cohen, D. Novichkova, and S. Refaely-Abramson, “Signatures of dimensionality and symmetry in exciton band
structure: Consequences for exciton dynamics and transport,” Nano Letters, vol. 21, no. 18, pp. 7644–7650, 2021.
and phononic bandstructures. These processes underlie energy transfer and the associated functionality
of energy conversion, as they determine state coherence and lifetime in excitonic materials. These properties are
broadly explored by spatiotemporal spectroscopy and are commonly understood within a kinetic rate equation
picture. A theoretical understanding of the underlying mechanisms and structural origins dominating the associated
rates from first principles is still lacking, and of emerging interest. In this study we present a many-body
perturbation theory scheme to describe exciton transport in solid pentacene. Starting from the GW and Bethe
Salpeter equation (GW-BSE) formalism combined with Density Functional Perturbation Theory (DFPT), we
compute exciton-phonon coupling from ab initio, and the associated phonon-mediated exciton scattering. We
apply our approach on the pentacene molecular crystal to study bright-to-dark exciton transitions as a pathway
to increased efficiency of nonradiative decay processes in this system. We derive a detailed kinetic description
of the intra- and inter-state exciton-phonon scattering, and analyze the exciton propagation upon these relaxation
pathways. We use our results to extend our recent work [1] and trace the relation between the exciton
wavepacket propagation in both the ballistic and the diffusive regimes to crystal symmetry and anisotropy.
[1] D. Y. Qiu, G. Cohen, D. Novichkova, and S. Refaely-Abramson, “Signatures of dimensionality and symmetry in exciton band
structure: Consequences for exciton dynamics and transport,” Nano Letters, vol. 21, no. 18, pp. 7644–7650, 2021.
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Publication: Diana Y. Qiu, Galit Cohen, Dana Novichkova, and Sivan Refaely-Abramson, "Signatures of dimensionality and symmetry in exciton band structure: Consequences for exciton dynamics and transport," Nano Letters, vol. 21, no. 18, pp. 7644–7650, 2021.
Presenters
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Galit Cohen
Weizmann Institute of Science
Authors
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Galit Cohen
Weizmann Institute of Science
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Diana Y Qiu
Yale University
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Sivan Refaely-Abramson
Weizmann Institute of Science