Conformational Effect of Catechol-Terephthalonitrile Emitters Leading to Ambient Violet Phosphorescence.
Raktim DekaSuvendu DeyManoj UpadhyaySakshi ChawlaDebdas RayPublished in: The journal of physical chemistry. A (2024)
Organic ambient violet phosphorescent (AVP) materials are of great interest due to their involvement of high energy and longer-lived triplet excitons. Here, we show three fused ring functionalized donor-acceptor-donor (D-A-D/D-A-D') emitters ( BPT1-BPT3 ), in which two catechol-based donors (3,4-dihydroxybenzophenone, catechol, or 3,5-di tert -butylcatechol) are covalently fused to the terephthalonitrile acceptor via four O-C single bonds. Spectroscopic analysis revealed that all the molecules show AVP (∼390-394 nm, τ AVP = 73-101 μs) with phosphorescence quantum yields (ϕ P ) of 1.8-27.4% due to low singlet-triplet gaps (0.036-0.046 eV) and conformational effects. BPT3 with bulky tert -butyl groups increases AVP (ϕ P = 27.4%). Quantum chemistry calculations reveal flat (F1) and twisted (F2) conformers (ground state) with a low energy difference (∼4-5 kcal/mol) for all molecules; the F1 conformer is responsible for efficient AVP, while weak blue thermally activated delayed fluorescence with longer-lived delayed components is realized from the F2 conformer. This approach may provide important clues for the design of high-energy organic phosphorescent materials.