Femtosecond intersystem crossing to the reactive triplet state of the 2,6-dithiopurine skin cancer photosensitizer
Luis A. Ortiz‐Rodríguez, Sean J. Hoehn, Chris Acquah, Nadia J Abbass, Lidia Waidmann, Carlos E. Crespo‐Hernández
Abstract
. In this study, we elucidated the electronic relaxation pathways leading to the population of the reactive triplet state of 2,6-dithiopurine. 2,6-Dithiopurine populates the triplet manifold in less than 150 fs, reaching the nπ* triplet state minimum within a lifetime of 280 ± 50 fs. Subsequently, the population in the nπ* triplet state minimum internally converts to the long-lived ππ* triplet state within a lifetime of 3 ± 1 ps. The relatively slow internal conversion lifetime is associated with major conformational relaxation in going from the nπ* to ππ* triplet state minimum. A unity triplet yield of 1.0 ± 0.1 is measured.
Topics & Concepts
Triplet stateIntersystem crossingChemistryNucleobaseSinglet oxygenQuantum yieldPhotochemistrySinglet statePopulationPhotosensitizerExcited stateFluorescenceMoleculeAtomic physicsOxygenPhysicsOrganic chemistryDNABiochemistrySociologyQuantum mechanicsDemographyPhotodynamic Therapy Research StudiesNanoplatforms for cancer theranosticsAdvanced Photocatalysis Techniques