par Banks, Peter A.;D'Avino, Gabriele;Schweicher, Guillaume 
;Armstrong, Jeff;Ruzié, Christian ;Chung, Jong Won;Park, Jeong-Il;Sawabe, Chizuru;Okamoto, Toshihiro;Takeya, Jun;Sirringhaus, Henning;Ruggiero, Michael T.
Référence Advanced functional materials, 33, 38, 2303701
Publication Publié, 2023-05-26
;Armstrong, Jeff;Ruzié, Christian ;Chung, Jong Won;Park, Jeong-Il;Sawabe, Chizuru;Okamoto, Toshihiro;Takeya, Jun;Sirringhaus, Henning;Ruggiero, Michael T.Référence Advanced functional materials, 33, 38, 2303701
Publication Publié, 2023-05-26
Article révisé par les pairs
| Résumé : | Organic semiconductors with distinct molecular properties and large carrier mobilities are constantly developed in attempt to produce highly-efficient electronic materials. Recently, designer molecules with unique structural modifications have been expressly developed to suppress molecular motions in the solid state that arise from low-energy phonon modes, which uniquely limit carrier mobilities through electron–phonon coupling. However, such low-frequency vibrational dynamics often involve complex molecular dynamics, making comprehension of the underlying electronic origins of electron–phonon coupling difficult. In this study, first a mode-resolved picture of electron–phonon coupling in a series of materials that are specifically designed to suppress detrimental vibrational effects, is generated. From this foundation, a method is developed based on the crystalline orbital Hamiltonian population (COHP) analyses to resolve the origins—down to the single atomic-orbital scale—of surprisingly large electron–phonon coupling constants of particular vibrations, explicitly detailing the manner in which the intermolecular wavefunction overlap is perturbed. Overall, this approach provides a comprehensive explanation into the unexpected effects of less-commonly studied molecular vibrations, revealing new aspects of molecular design that should be considered for creating improved organic semiconducting materials. |
