Fluorescence Quenching by Oxygen: “Debunking” a Classic Rule

FRANCO M. CABRERIZO; JACOB ARNBJERG; M. PAULA DENOFRIO; ROSA ERRA-BALSELLS; PETER R. OGILBY

Chemphyschem

WILEY-VCH Verlag GmbH & Co. KGaA

Lugar: Weinheim; Año: 2010 vol. 11 p. 796 - 798

1439-4235

New clothes for an old player: Oxygen-induced deactivation of a fluorescent state can, in fact, proceed via S1!S0 internal conversion and effectively compete with S1!T1 intersystem crossing (see figure). It has long been considered that only the latter process occurs. An O2-dependent process that does not produce a triplet excited state can have significant photochemical and photobiological consequences. 1!S0 internal conversion and effectively compete with S1!T1 intersystem crossing (see figure). It has long been considered that only the latter process occurs. An O2-dependent process that does not produce a triplet excited state can have significant photochemical and photobiological consequences. 1!T1 intersystem crossing (see figure). It has long been considered that only the latter process occurs. An O2-dependent process that does not produce a triplet excited state can have significant photochemical and photobiological consequences. 2-dependent process that does not produce a triplet excited state can have significant photochemical and photobiological consequences.1!S0 internal conversion and effectively compete with S1!T1 intersystem crossing (see figure). It has long been considered that only the latter process occurs. An O2-dependent process that does not produce a triplet excited state can have significant photochemical and photobiological consequences. 1!T1 intersystem crossing (see figure). It has long been considered that only the latter process occurs. An O2-dependent process that does not produce a triplet excited state can have significant photochemical and photobiological consequences. 2-dependent process that does not produce a triplet excited state can have significant photochemical and photobiological consequences.