# Electronic Structure and Vibrational Properties of Indenotetracene‐Based Crystal

**Authors:** Federico Coppola, Raoul Carfora, Nadia Rega

PMC · DOI: 10.1002/jcc.70141 · Journal of Computational Chemistry · 2025-05-24

## TL;DR

This study investigates the properties of a new organic crystal material and finds that its structure significantly affects its electronic and optical behavior.

## Contribution

The paper identifies two distinct dimeric species in the crystal and shows how they influence electronic and vibrational properties.

## Key findings

- Two dimeric species in the crystal exhibit different intermolecular arrangements affecting electronic and vibrational properties.
- Theoretical absorption spectrum shows three main electronic transitions at 530, 360, and 275 nm.
- Transition electric dipole moments vary significantly between the dimeric species, affecting optical response.

## Abstract

Asymmetrically substituted indenotetracene crystals are promising nonfullerene electron transport materials for organic photovoltaics, offering potential improvements in efficiency and stability. In this work, we present a first‐principle investigation of the electronic and vibrational properties of a diarylindenotetracene system functionalized with two methoxy groups (hereafter DimethoxyASI). Single‐crystal X‐ray diffraction analysis [reported in J. Org. Chem. 2018, 83, 4, 1828] reveals a monoclinic P21/c structure with an interplanar distance of 3.76 Å, providing insight into the molecular packing and intermolecular interactions that govern the solid‐state organization. Notably, for the first time, in this work we identify two distinct dimeric species within the crystalline lattice by a structural and electronic analysis, each exhibiting different intermolecular arrangements that significantly influence both the electronic structure and vibrational properties of the material. Density functional theory (DFT) and time‐dependent density functional theory (TDDFT) calculations provide insight into the molecular packing, electronic states, and vibrational characteristics of the crystal. The theoretical absorption spectrum, obtained from TDDFT calculations, features three main electronic transitions centered at 530, 360, and 275 nm, displaying a mixed character of localized excitations and charge‐transfer contributions. The vibrational properties, investigated through phonon density of states calculations at the DFT level, highlight well‐defined spectral features. While most vibrational modes remain consistent between monomeric and dimeric configurations, significant deviations emerge in the low‐frequency region, where intermolecular interactions and crystal packing effects play a crucial role. Furthermore, the two dimeric species exhibit distinct electronic properties beyond their geometric differences. A key distinguishing factor is the transition electric dipole moments (TEDMs), which governs the probability and polarization of electronic transitions. Our analysis reveals that the TEDMs magnitude and orientation vary significantly between the two dimeric species, suggesting that they may interact differently with polarized light. These differences provide new insight into the role of molecular aggregation in shaping the optical response of organic semiconductors and highlight the impact of polymorphism on their electronic properties. Overall, this study underscores the intricate relationship between molecular packing, electronic structure, and vibrational properties in indenotetracene‐based materials, contributing to a deeper understanding of their potential applications in optoelectronic devices.

This study explores the electronic, vibrational, and optical properties of dimethoxy‐substituted indenotetracene crystals using DFT and TDDFT. We identify two distinct dimeric structures, highlighting their impact on molecular packing, transition dipole moments, and electronic states, providing new insights into the role of polymorphism in organic semiconductors.

## Full-text entities

- **Chemicals:** DimethoxyASI (-)

## Full text

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## References

121 references — full list in the complete paper: https://tomesphere.com/paper/PMC12102687/full.md

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Source: https://tomesphere.com/paper/PMC12102687