Litcius/Paper detail

Enhanced Red Persistent Room-Temperature Phosphorescence Induced by Orthogonal Structure Disruption during Electronic Relaxation

Kei Fukasawa, Yuma Sugawara, Rana Tsuru, Takashi Yamashita, Shuzo Hirata

2022The Journal of Physical Chemistry Letters19 citationsDOI

Abstract

autofluorescence. However, efficient long-wavelength RTP is difficult. Here, enhanced red RTP based on a unique mechanism was observed from deuterated dibenzo[g.p]chrysenes substituted with a phenoxazine. The yield was 16%, with an average lifetime of 1.8 s. An orthogonal dihedral angle between the dibenzo[g.p]chrysene and the phenoxazine in the lowest excited singlet state allowed a forbidden fluorescence to increase triplet generation. When the dihedral angle changed, disengagement of the forbidden fluorescence from the excited singlet state occurred, and the lowest triplet excited state had a facilitated phosphorescence rate without increasing its nonradiative transition rate. The facilitated phosphorescence rate as well as the large triplet yield led to the enhanced red RTP.

Topics & Concepts

PhosphorescenceExcited stateFluorescencePhotochemistryQuantum yieldChemistryPhenoxazineDihedral angleSinglet stateTriplet stateAtomic physicsOpticsMoleculeHydrogen bondPharmacologyOrganic chemistryPhysicsPhenothiazineMedicineLuminescence and Fluorescent MaterialsPhotoreceptor and optogenetics researchNanoplatforms for cancer theranostics