The tautomer-specific excited state dynamics of 2,6-diaminopurine using REMPI and quantum chemical calculations

16 November 2023, Version 2
This content is a preprint and has not undergone peer review at the time of posting.

Abstract

2,6-diaminopurine (2,6-dAP) is an alternative nucleobase that potentially played a role in prebiotic chemistry. We studied its excited state dynamics in the gas phase by REMPI, IR-UV hole burning, and ps pump-probe spectroscopy and performed quantum chemical calculations at the SCS-ADC(2) level of theory to interpret the experimental results. We found the 9H tautomer to have a small barrier to ultrafast relaxation via puckering of its 6-membered ring. The 7H tautomer has a larger barrier to reach a conical intersection and also has a sizable triplet yield. These results are discussed relative to other purines, for which 9H tautomerization appears to be more photostable than 7H and homosubstituted purines appear to be less photostable than heterosubstituted or singly substituted purines.

Keywords

DNA
nucleobases
excited states
photostability
photodynamics
pump probe spectroscopy

Supplementary materials

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Supporting Information
Description
Additional experimental and computational results including spectra, excited-state potential energy surfaces calcualted at the NEVPT2/SA-CASSCF level of theory, composition of active spaces and description of the experimental work.
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