Login / Signup

Short Excited-State Lifetimes Enable Photo-Oxidatively Stable Rubrene Derivatives.

Jack LyKara MartinSimil ThomasMasataka YamashitaBeihang YuCraig A PointerHiroko YamadaKenneth R CarterSean ParkinGuowei ZhangJean-Luc BredasElizabeth R YoungAlejandro L Briseno
Published in: The journal of physical chemistry. A (2019)
A series of rubrene derivatives were synthesized and the influence of the side group in enhancing photo-oxidative stability was evaluated. Photo-oxidation half-lives were determined via UV-vis absorption spectroscopy, which revealed thiophene containing derivatives to be the most stable species. The electron affinity of the compounds did not correlate with stability as previously reported in literature. Our work shows that shorter excited-state lifetimes result in increased photo-oxidative stability in these rubrene derivatives. These results confirm that faster relaxation kinetics out-compete the formation of reactive oxygen species that ultimately degrade linear oligoacenes. This report highlights the importance of using molecular design to tune excited-state lifetimes in order to generate more stable oligoacenes.
Keyphrases
  • electron transfer
  • reactive oxygen species
  • structure activity relationship
  • single molecule
  • systematic review
  • hydrogen peroxide