Open AccessUltrafast Dissociation Dynamics of 2-Ethylpyrrole
Author(s) -
Neil C. Cole-Filipiak,
Michael Staniforth,
Natércia d. N. Rodrigues,
Yoann Peperstraete,
Vasilios G. Stavros
Publication year - 2017
Publication title -
the journal of physical chemistry a
Language(s) - Uncategorized
Resource type - Journals
SCImago Journal Rank - 0.756
H-Index - 235
eISSN - 1520-5215
pISSN - 1089-5639
DOI - 10.1021/acs.jpca.6b12228
Subject(s) - photoexcitation , kinetic energy , dissociation (chemistry) , chemistry , kinetic isotope effect , bond cleavage , atomic physics , ion , photodissociation , ultrashort pulse , excitation , atom (system on chip) , population , photochemistry , potential energy , excited state , deuterium , physics , laser , optics , catalysis , biochemistry , demography , organic chemistry , quantum mechanics , sociology , computer science , embedded system
To explore the effects of ring substitution on dissociation dynamics, the primary photochemistry of 2-ethylpyrrole was explored using ultrafast ion imaging techniques. Photoexcitation to the S 1 state, a πσ* state, in the range from 238 to 265 nm results in cleavage of the N-H bond with an H atom appearance lifetime of ca. 70 fs. The insensitivity of this lifetime to photon energy, combined with a small kinetic isotope effect, suggests that tunneling does not play a major role in N-H bond cleavage. Total kinetic energy release spectra reveal modest vibrational excitation in the radical counter-fragment, increasing with photon energy. At wavelengths less than or equal to 248 nm, an additional low kinetic energy H atom loss mechanism becomes available with an appearance lifetime of ∼1.5 ps, possibly due to the population of higher-lying 1 ππ* states.
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