Excited-State Structure Modifications Due to Molecular Substituents and Exciton Scattering in Conjugated Molecules

Li, Hao; Catanzaro, Michael J.; Tretiak, Sergei; Chernyak, Vladimir

doi:10.1021/jz4027198

Cited by 7 publications

(10 citation statements)

References 37 publications

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“…The topological charge provides useful information on how many cites in the related tight-binding model are needed to adequately describe a scattering center. Studying analytical (geometrical) properties of the scattering matrices, namely the analytical continuations of Γ(k) with k being the quasimomentum, from the Brillouin zone, represented by a unit circle in the complex plane (or its compactified version, known as the projective space CP 1 ) provide useful microscopic insights into the chemical properties of molecular substituents [49], connected to polymer backbones. The positions of poles (or zeros) of Γ(k) in CP 1 describe the energies and spectral widths of the bound and resonant states that occur in a conjugated molecule due to the presence of the substituent, with the above energies sometimes being very different form the energetics of an uncoupled fragment.…”

Section: Discussionmentioning

confidence: 99%

Exciton scattering approach for optical spectra calculations in branched conjugated macromolecules

Malinin

et al. 2016

Chemical Physics

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The exciton scattering (ES) technique is a multiscale approach based on the concept of a particle in a box and developed for efficient calculations of excited-state electronic structure and optical spectra in low-dimensional conjugated macromolecules. Within the ES method, electronic excitations in molecular structure are attributed to standing waves representing quantum quasi-particles (excitons), which reside on the graph whose edges and nodes stand for the molecular linear segments and vertices, respectively. Exciton propagation on the linear segments is characterized by the exciton dispersion, whereas exciton scattering at the branching centers is determined by the energy-dependent scattering matrices. Using these ES energetic parameters, the excitation energies are then found by solving a set of generalized "particle in a box" problems on the graph that represents the molecule. Similarly, unique energy-dependent ES dipolar parameters permit calculations of the corresponding oscillator strengths, thus, completing optical spectra modeling. Both the energetic and dipolar parameters can be extracted from quantum-chemical computations in small molecular fragments and tabulated in the ES library for further applications. Subsequently, spectroscopic modeling for any macrostructure within a considered molecular family could be performed with negligible numerical effort. We demonstrate the ES method application to molecular families of branched conjugated phenylacetylenes and ladder poly-para-phenylenes, as well as structures with electron donor and acceptor chemical substituents. Time-dependent density functional theory (TD-DFT) is used as a reference model for electronic structure. The ES calculations accurately reproduce the optical spectra compared to the reference quantum chemistry results, and make possible to predict spectra of complex macromolecules, where conventional electronic structure calculations are unfeasible.

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Section: Discussionmentioning

confidence: 99%

Exciton scattering approach for optical spectra calculations in branched conjugated macromolecules

Malinin

et al. 2016

Chemical Physics

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“…Chemical coupling between the linear segments and scattering centers modifies the excitations in the latter, resulting in bound and resonant states 8 . The resonant states that fall inside the exciton band show up as resonances in the density of states, or equivalently in sharp 2π-rotations of the det Γ a (k) in the narrow regions of k around the resonance of ω(k) with a state at the scattering center, referred to as kinks 8,10 are much harder to analyze, compared to bound states. Our counting result allows for a following interpretation: the number N res of resonant states in a finite structure is given by just the sum N res = a Q a of the topological charges, associated with the scattering centers.…”

Section: Discussionmentioning

confidence: 99%

“…The presented theory provides an explicit link between the graph topology (connectivity) of the branched system the interlining molecular electronic and optical properties defined by the spectrum of electronic excitations: The excitedstate electronic structure in a finite molecule is a result of complex interplay between excitations in linear segments, determined by the exciton band structure in infinite polymers and electronic excitations in scattering centers. Chemical coupling between the linear segments and scattering centers modifies the excitations in the latter, resulting in bound and resonant states 8 . The resonant states that fall inside the exciton band show up as resonances in the density of states, or equivalently in sharp 2π-rotations of the det Γ a (k) in the narrow regions of k around the resonance of ω(k) with a state at the scattering center, referred to as kinks 8,10 are much harder to analyze, compared to bound states.…”

Section: Discussionmentioning

confidence: 99%

“…Our previous studies have demonstrated accurate calculations of excited state transition energies 4,5 and optical spectra 6 in very large, low-dimensional molecular systems with negligible computational cost using this technique. Moreover, this framework enables an efficient characterization of excited-state electronic structure modifications due to different branching pattern and donor/acceptor substitutions 7,8 . We reiterate that all information on the system Hamiltonian and further approximations (e.g., the quantum chemistry method involved, basis sets, etc.)…”

Section: Introductionmentioning

confidence: 99%

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Counting the number of excited states in organic semiconductor systems using topology

Catanzaro

Shi

Tretiak

et al. 2015

The Journal of Chemical Physics

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Exciton Scattering (ES) theory attributes excited electronic states to standing waves in quasione-dimensional molecular materials by assuming a quasi-particle picture of optical excitations. The quasi-particle properties at branching centers are described by the corresponding scattering matrices. Here we identify the topological invariant of a scattering center, referred to as its winding number, and apply topological intersection theory to count the number of quantum states in a quasi-one-dimensional system.

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“…Already in the previous century the effects of close packing have been linked to the formation of charge transfer (CT) states. [1][2][3] With CT states being found recently in new materials [4][5][6][7][8] and their appearance in biological light-harvesting systems, [9][10][11][12] interest in modeling of CT systems persisted [13][14][15][16][17] which fuelled the need for a better understanding how the competition between various interactions leads to specific observable properties.…”

Section: Introductionmentioning

confidence: 99%

Optical Signatures of the Coupling between Excitons and Charge Transfer States in Linear Molecular Aggregates

Manrho,

Jansen,

Knoester

2022

Preprint

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Charge Transfer (CT) has enjoyed continuous interest due to increasing experimental control over molecular structure leading to applications in, for example, photovoltaics and hydrogen production. In this paper, we investigate the effect of CT states on the absorption spectrum of linear molecular aggregates using a scattering matrix technique that allows us to deal with arbitrarily large systems. The presented theory performs well for both strong and weak mixing of exciton and CT states, bridging the gap between previously employed methods which are applicable in only one of these limits. In experimental spectra the homogeneous linewidth is often too large to resolve all optically allowed transitions individually, resulting in a characteristic two-peak absorption spectrum in both the weak-and strong-coupling regime. Using the scattering matrix technique we examine the contributions of free and bound states in detail. We conclude that the skewness of the high-frequency peak may be used as a new way to identify the exciton-CT-state coupling strength.

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Excited-State Structure Modifications Due to Molecular Substituents and Exciton Scattering in Conjugated Molecules

Cited by 7 publications

References 37 publications

Exciton scattering approach for optical spectra calculations in branched conjugated macromolecules

Exciton scattering approach for optical spectra calculations in branched conjugated macromolecules

Counting the number of excited states in organic semiconductor systems using topology

Optical Signatures of the Coupling between Excitons and Charge Transfer States in Linear Molecular Aggregates

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