Phonon-Induced Localization of Excitons in Molecular Crystals from First Principles.

The spatial extent of excitons in molecular systems underpins their photophysics and utility for optoelectronic applications. Phonons are reported to lead to both exciton localization and delocalization. However, a microscopic understanding of phonon-induced (de)localization is lacking, in particular, how localized states form, the role of specific vibrations, and the relative importance of quantum and thermal nuclear fluctuations. Here, we present a first-principles study of these phenomena in solid pentacene, a prototypical molecular crystal, capturing the formation of bound excitons, exciton-phonon coupling to all orders, and phonon anharmonicity, using density functional theory, the ab initio GW-Bethe-Salpeter equation approach, finite-difference, and path integral techniques. We find that for pentacene zero-point nuclear motion causes uniformly strong localization, with thermal motion providing additional localization only for Wannier-Mott-like excitons. Anharmonic effects drive temperature-dependent localization, and, while such effects prevent the emergence of highly delocalized excitons, we explore the conditions under which these might be realized.

[1]  M. Knupfer,et al.  Strong exciton bandwidth reduction in pentacene as a function of temperature , 2022, Physical Review B.

[2]  A. Rao,et al.  A New Frontier in Exciton Transport: Transient Delocalization , 2022, The journal of physical chemistry letters.

[3]  Y. Diskin‐Posner,et al.  Chemical Modifications Suppress Anharmonic Effects in the Lattice Dynamics of Organic Semiconductors , 2022, ACS Materials Au.

[4]  Edgar A. Engel,et al.  Importance of vibrational anharmonicity for electron-phonon coupling in molecular crystals , 2022, Physical Review B.

[5]  J. Blumberger,et al.  Exciton transport in molecular organic semiconductors boosted by transient quantum delocalization , 2022, Nature Communications.

[6]  M. Rohlfing,et al.  Finite-momentum excitons in rubrene single crystals , 2021, Physical Review B.

[7]  J. Brédas,et al.  Molecular Packing in the Active Layers of Organic Solar Cells Based on Non-Fullerene Acceptors: Impact of Isomerization on Charge Transport, Exciton Dissociation, and Nonradiative Recombination , 2021 .

[8]  D. Qiu,et al.  Signatures of Dimensionality and Symmetry in Exciton Band Structure: Consequences for Exciton Dynamics and Transport , 2021, Nano letters.

[9]  Edgar A. Engel,et al.  A complete description of thermodynamic stabilities of molecular crystals , 2021, Proceedings of the National Academy of Sciences.

[10]  J. Pflaum,et al.  Nuclear dynamics of singlet exciton fission in pentacene single crystals , 2020, Science Advances.

[11]  S. Louie,et al.  Predominance of non-adiabatic effects in zero-point renormalization of the electronic band gap , 2020, npj Computational Materials.

[12]  C. Brabec,et al.  Organic photovoltaic modules with new world record efficiencies , 2020, Progress in Photovoltaics: Research and Applications.

[13]  R. Friend,et al.  Efficient energy transport in an organic semiconductor mediated by transient exciton delocalization , 2020, Science Advances.

[14]  R. Friend,et al.  Impact of exciton delocalization on exciton-vibration interactions in organic semiconductors , 2020, 2006.03604.

[15]  F. Giustino,et al.  Theory of the special displacement method for electronic structure calculations at finite temperature , 2019, Physical Review Research.

[16]  J. Blumberger,et al.  Quantum localization and delocalization of charge carriers in organic semiconducting crystals , 2019, Nature Communications.

[17]  D. Beratan Why Are DNA and Protein Electron Transfer So Different? , 2019, Annual review of physical chemistry.

[18]  H. Sirringhaus,et al.  Chasing the “Killer” Phonon Mode for the Rational Design of Low‐Disorder, High‐Mobility Molecular Semiconductors , 2019, Advanced materials.

[19]  Steven Vandenbrande,et al.  i-PI 2.0: A universal force engine for advanced molecular simulations , 2018, Comput. Phys. Commun..

[20]  Michele Ceriotti,et al.  A Data-Driven Construction of the Periodic Table of the Elements , 2018, 1807.00236.

[21]  S. Louie,et al.  Origins of Singlet Fission in Solid Pentacene from an ab initio Green's Function Approach. , 2017, Physical review letters.

[22]  Jörg Behler,et al.  High order path integrals made easy. , 2016, The Journal of chemical physics.

[23]  F. Giustino,et al.  One-shot calculation of temperature-dependent optical spectra and phonon-induced band-gap renormalization , 2016, 1604.02394.

[24]  A. Troisi,et al.  Regimes of Exciton Transport in Molecular Crystals in the Presence of Dynamic Disorder , 2016 .

[25]  Kristian Berland,et al.  Structural and excited-state properties of oligoacene crystals from first principles , 2016, 1604.00041.

[26]  B. Monserrat Correlation effects on electron-phonon coupling in semiconductors: Many-body theory along thermal lines , 2016, 1603.00551.

[27]  B. Monserrat Vibrational averages along thermal lines , 2015, 1512.06377.

[28]  Arthur Zimek,et al.  Hierarchical Density Estimates for Data Clustering, Visualization, and Outlier Detection , 2015, ACM Trans. Knowl. Discov. Data.

[29]  S. Ciuchi,et al.  The Transient Localization Scenario for Charge Transport in Crystalline Organic Materials , 2015, 1505.02686.

[30]  Cathy Y. Wong,et al.  Relating the Physical Structure and Optoelectronic Function of Crystalline TIPS‐Pentacene , 2015 .

[31]  Á. Rubio,et al.  Exciton dispersion in molecular solids , 2015, Journal of physics. Condensed matter : an Institute of Physics journal.

[32]  F. Giustino,et al.  Unified theory of electron–phonon renormalization and phonon-assisted optical absorption , 2014, Journal of physics. Condensed matter : an Institute of Physics journal.

[33]  D. Beratan,et al.  Biological charge transfer via flickering resonance , 2014, Proceedings of the National Academy of Sciences.

[34]  Jeffrey B. Neaton,et al.  Low-Energy Charge-Transfer Excitons in Organic Solids from First-Principles: The Case of Pentacene , 2013 .

[35]  R. Kondor,et al.  On representing chemical environments , 2012, 1209.3140.

[36]  David A. Strubbe,et al.  BerkeleyGW: A massively parallel computer package for the calculation of the quasiparticle and optical properties of materials and nanostructures , 2011, Comput. Phys. Commun..

[37]  Michele Parrinello,et al.  Efficient stochastic thermostatting of path integral molecular dynamics. , 2010, The Journal of chemical physics.

[38]  Stefano de Gironcoli,et al.  QUANTUM ESPRESSO: a modular and open-source software project for quantum simulations of materials , 2009, Journal of physics. Condensed matter : an Institute of Physics journal.

[39]  Gregor Schwartz,et al.  White organic light-emitting diodes with fluorescent tube efficiency , 2009, Nature.

[40]  A. Tkatchenko,et al.  Accurate molecular van der Waals interactions from ground-state electron density and free-atom reference data. , 2009, Physical review letters.

[41]  B. Batlogg,et al.  Large uniaxial negative thermal expansion in pentacene due to steric hindrance , 2007, 0707.0450.

[42]  John E. Anthony,et al.  Electronic interactions and thermal disorder in molecular crystals containing cofacial pentacene units , 2005 .

[43]  Burke,et al.  Generalized Gradient Approximation Made Simple. , 1996, Physical review letters.

[44]  Georg Kresse,et al.  Ab initio Force Constant Approach to Phonon Dispersion Relations of Diamond and Graphite , 1995 .

[45]  Yehoshua Y. Zeevi,et al.  The farthest point strategy for progressive image sampling , 1994, Proceedings of the 12th IAPR International Conference on Pattern Recognition, Vol. 2 - Conference B: Computer Vision & Image Processing. (Cat. No.94CH3440-5).

[46]  Steve Plimpton,et al.  Fast parallel algorithms for short-range molecular dynamics , 1993 .

[47]  Louie,et al.  Electron correlation in semiconductors and insulators: Band gaps and quasiparticle energies. , 1986, Physical review. B, Condensed matter.

[48]  H. Monkhorst,et al.  SPECIAL POINTS FOR BRILLOUIN-ZONE INTEGRATIONS , 1976 .

[49]  N. Mott Conduction in polar crystals. II. The conduction band and ultra-violet absorption of alkali-halide crystals , 1938 .