Journal
PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA
Volume 110, Issue 44, Pages 17697-17702Publisher
NATL ACAD SCIENCES
DOI: 10.1073/pnas.1306979110
Keywords
photochemistry; sulfur dioxide; excited electronic states; absorption spectrum
Categories
Funding
- National Aeronautics and Space Administration Exobiology Program [NNX10AR85G]
- National Natural Science Foundation of China [21133006, 91221301, 91021010]
- Ministry of Science and Technology [2013CB834601]
- Department of Energy [DF-FG02-05ER15694]
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Signatures of mass-independent isotope fractionation (MIF) are found in the oxygen (O-16, O-17, O-18) and sulfur (S-32, S-33, S-34, S-36) isotope systems and serve as important tracers of past and present atmospheric processes. These unique isotope signatures signify the breakdown of the traditional theory of isotope fractionation, but the physical chemistry of these isotope effects remains poorly understood. We report the production of large sulfur isotope MIF, with Delta S-33 up to 78% and Delta S-36 up to 110%, from the broadband excitation of SO2 in the 250-350-nm absorption region. Acetylene is used to selectively trap the triplet-state SO2 ((a) over tilde B-3(1)), which results from intersystem crossing from the excited singlet ((A) over tilde (1)A(2)/(B) over tilde B-1(1)) states. The observed MIF signature differs considerably from that predicted by isotopologue-specific absorption cross-sections of SO2 and is insensitive to the wavelength region of excitation (above or below 300 nm), suggesting that the MIF originates not from the initial excitation of SO2 to the singlet states but from an isotope selective spin-orbit interaction between the singlet ((A) over tilde (1)A(2)/(B) over tilde B-1(1)) and triplet ((a) over tilde B-3(1)) manifolds. Calculations based on high-level potential energy surfaces of the multiple excited states show a considerable lifetime anomaly for (SO2)-S-33 and (SO2)-S-36 for the low vibrational levels of the (A) over tilde (1)A(2) state. These results demonstrate that the isotope selectivity of accidental near-resonance interactions between states is of critical importance in understanding the origin of MIF in photochemical systems.
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