Accelerated Diradical Character Assessment in Large Datasets of Polybenzenoid Hydrocarbons Using xTB Fractional Occupation

04 November 2024, Version 2
This content is a preprint and has not undergone peer review at the time of posting.

Abstract

Polybenzenoid hydrocarbons (PBHs) have gar- nered significant attention in the field of or- ganic electronics due to their unique electronic properties. To facilitate the design and discov- ery of new functional organic materials based on these compounds, it is necessary to assess their diradical character. However, this usually requires expensive multireference calculations. In this study, we introduce a novel approach for rapidly identifying and quantifying open- shell character in PBHs using the fractional occupation number weighted electron density metric (NFOD) calculated with the semiempir- ical xTB method. We apply this approach to the entire chemical space of PBHs containing up to 10 rings, a total of over 19k molecules. Our findings reveal a strong correlation be- tween xTB-calculated NFOD and the more com- putationally expensive Yamaguchi y and DFT- calculated NFOD, validating the use of this effi- cient method for large-scale screening. Addi- tionally, we identify a linear relationship be- tween size and NFOD value and implement a size-dependent threshold for open-shell charac- ter, which significantly improves the accuracy of diradical identification across the chemical space of PBHs. This size-aware approach re- duces false positive identifications from 6.97% to 0.38% compared to using a single thresh- old value. Overall, this work demonstrates that xTB-calculated NFOD provides a rapid and cost- effective alternative for large-scale screening of open-shell character in PBHs.

Keywords

polycyclic aromatic hydrocarbons
database
computational chemistry
structure-property relationships
diradical character

Supplementary materials

Title
Description
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Title
Supporting Information for Accelerated Diradical Character Assessment in Large Datasets of Polybenzenoid Hydrocarbons Using xTB Fractional Occupation
Description
General computational details, further analysis of the effect of the longest linear stretch in cc-PBHs, supplementary tables and figures for the identification of the size-aware thresholds, and analysis on the effect of geometry on NFOD.
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Supplementary weblinks

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