Symmetry breaking and excitonic effects on optical properties of defective nanographenes

Noguchi, Yuichi; Sugino, Osamu

doi:10.1063/1.4907751

Cited by 18 publications

(7 citation statements)

References 52 publications

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“…Based on the DFT‐RPA calculations this peak was attributed to the

π \to π *

interband transitions determined by topology‐induced resonant

π

states as well as

π

*–

σ

* hybridization at the cone apex. A change in the optical absorption of a hydrogen‐terminated graphene fragment with the incorporation of various topological defects was studied using the GW‐BSE approach . One of the goals of that article was to interpret the spectrum measured for grossly warped nanographene C 80 H 30 .…”

Section: Shaped Graphenementioning

confidence: 99%

“…A change in the optical absorption of a hydrogen-terminated graphene fragment with the incorporation of various topological defects was studied using the GW-BSE approach. [62] One of the goals of that article was to interpret the spectrum measured for grossly warped nanographene C 80 H 30 . [63] This structure was modeled by a fragment containing a pentagonal ring at the center and five heptagonal rings (inset in Fig.…”

Section: Finite-size Configurationsmentioning

confidence: 99%

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Many‐body effects in optical response of graphene‐based structures

Bulusheva

Sedelnikova

Окотруб

2015

Int J of Quantum Chemistry

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Graphene is an exciting material for optoelectronics and plasmonics. Its optical response may be changed under mechanical action, such as stretching or corrugation, and with confinement of a size in a certain direction. Theoretical investigations play an important role in interpretation of experimental data and stimulating a search for novel graphene architectures. Thereby, it is important to analyze restrictions of modern approaches in calculation of optical properties of graphene-based objects and, particularly, to reveal an impact of electron-electron and electron-hole interactions on the position and shape of optical features. Here, we review the recent progress in quantum-chemical calculations of monolayer and few-layer graphenes, graphene ripples, and dots in a light of optical excitations.

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“…Based on the DFT‐RPA calculations this peak was attributed to the

π \to π *

interband transitions determined by topology‐induced resonant

π

states as well as

π

*–

σ

Section: Shaped Graphenementioning

confidence: 99%

Section: Finite-size Configurationsmentioning

confidence: 99%

Many‐body effects in optical response of graphene‐based structures

Bulusheva

Sedelnikova

Окотруб

2015

Int J of Quantum Chemistry

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“…It centers at a C5 ring that is surrounded by five C6 rings, and then by five C7 rings. The computed averaged r 56 , r 66 and r 67 are 1.405, 1.406, and 1.448 Å, respectively, which are quite different from the C-C distances in C 60 (1.45 AE 0.015 Å for r 56 It is apparent that the delocalization in the HOMO and LUMO orbitals of C 78 H 30 is more significant than that of C 80 H 30 . At the outermost of C 80 H 30 are ten C6 rings that are adjacent to the C7 rings.…”

Section: Structure and Optical Absorption Of C 80 H 30 And C 78 H 30mentioning

confidence: 79%

“…The second (444 nm) and the strongest (435 nm) bands also match well with the measurement (452 nm and 418 nm), 33 respectively. The GW (Green's function G and screened Coulomb interaction W) + BSE (Bethe-Salpeter equation) approach was used by Noguchi and Sugino 56 to compute the absorption spectra of C 80 H 30 , giving the first three bands at 460, 422 and 393 nm, respectively. Therefore, B3LYP was selected to compute the optical absorption of the C 80 H 30 derivative in the subsequent TDDFT calculations.…”

Section: Structure and Optical Absorption Of C 80 H 30 And C 78 H 30mentioning

confidence: 99%

Optical absorption of warped nanographenes tuned by five- and seven-membered carbon rings

Wang

Lou

et al. 2015

Phys. Chem. Chem. Phys.

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The introduction of multiple carbon rings is one of the common ways for graphene modification. Starting from warped C80H30 nanographene, which consists of a number of six- and seven-membered carbon rings (C6 and C7) centering at a five-membered carbon ring (C5), we explored the structure and property variations of its derivatives in which their C7 rings were gradually replaced with C6 rings. With reducing number of C7 rings, their curved boundary with the C6 rings becomes flat until a bowl-like structure is formed when all the C7 rings disappear. The optical absorption spectra vary accordingly. Both the α-bands and the maximum absorption bands in the visible region are related to the number and location of the C7 rings. Further analysis of the excited states of the C80H30 derivatives, as well as on the designed model systems, revealed that the C7 rings affect the electron excitations in two ways. In addition to their participation in electronic transitions, they control the composition of molecular orbitals that are involved in the excitations. The highest occupied molecular orbitals are mainly contributed by atoms on the C6 and C7 rings, while the lowest unoccupied molecular orbitals by atoms on the C5 and C6 rings. Our study sheds some light on how the multiple carbon rings affect the optical absorption of nanographenes and provides information for the preparation of nanographenes with tunable structural and optical properties.

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“…We employ a standard one-shot GW+BSE method in which BSE is solved within GWA to simulate the optical properties of TADF molecules from first-principles. The GW+BSE method has been implemented into our original program code employing an all-electron mixed-basis approach ,− (the detailed calculation condition is given in Supporting Information S1). We follow the conventional scheme of adopting the Tamm–Dancoff approximation and convert BSE into an eigenvalue problem of the Hermitian BSE Hamiltonian ( H BSE ), The eigenvalue (Ω i ) corresponding to the i th excitation energy is denoted as S i for the singlet excitation energy without spin flip and T i for the triplet excitation energy with spin flip.…”

Section: Methodsmentioning

confidence: 99%

High-Lying Triplet Excitons of Thermally Activated Delayed Fluorescence Molecules

Noguchi

Sugino

2017

J. Phys. Chem. C

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We investigate high-lying triplet excitons involving a transition from the highest-occupied molecular orbital (HOMO) to the lowest-unoccupied molecular orbital (LUMO) for 18 thermally activated delayed fluorescence (TADF) molecules, within the first-principles one-shot GW +Bethe−Salpeter method. On the basis of our exciton analysis using the exciton wave functions, detailed exciton features are discussed in terms of exciton size, exciton binding energy, electron−hole separation distance, exciton map, and the overlap strength between the electron and hole wave functions. Contrary to our expectation, no exciton that could be purely classified as a charge-transfer exciton is found in our exciton map; moreover, the energy difference between the lowest singlet exciton and the high-lying triplet exciton is nearly zero for some TADF molecules. Our simulation strongly suggests that the hot-exciton process involving a high-lying triplet exciton is more likely to occur in the TADF mechanism than the conventionally considered process between the lowest singlet and triplet excitons, and our results support those of recent experiments. We propose a new method for calculating the energy difference between singlet and triplet excitons from the expectation value of the exchange bare Coulomb interaction and demonstrate that the combined use with exciton map is efficient and accurate for screening TADF molecules.

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Symmetry breaking and excitonic effects on optical properties of defective nanographenes

Cited by 18 publications

References 52 publications

Many‐body effects in optical response of graphene‐based structures

Many‐body effects in optical response of graphene‐based structures

Optical absorption of warped nanographenes tuned by five- and seven-membered carbon rings

High-Lying Triplet Excitons of Thermally Activated Delayed Fluorescence Molecules

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