2019
DOI: 10.1021/acs.jpca.9b00327
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Multidimensional H Atom Tunneling Dynamics of Phenol: Interplay between Vibrations and Tunneling

Abstract: Multidimensional facets of the hydrogen tunneling dynamics of phenol excited in S1 (ππ*) have been unraveled to give particular S1 vibronic states strongly coupled or actively decoupled to the O–H tunneling coordinate. Strong mode-dependent variation of the tunneling rate measured with picosecond lasers indicates that tunneling probability is extremely sensitive to low-frequency vibrational modes seemingly orthogonal to the O–H elongation coordinate unless the rate of energy randomization exceeds that of tunne… Show more

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Cited by 23 publications
(52 citation statements)
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“…By measuring both the ps transients of parent and fragment and the total translational energy distribution of products as a function of the reaction time, it was evidenced that both the slow and fast components of the H fragment have the same tunneling origin and that the ground state is populated at the second ps*-S 0 crossing and not through a direct pp*-S 0 internal conversion process. 24,37 The H-loss dynamics have also been studied in the time domain. The ps time-evolution of the S 1 excited state of PhOH shows that the lifetime decreases from 2 ns at the band origin 0 0 0 down to 600 ps at the band located 3500 cm À1 above the origin.…”
Section: The Sddj Modelmentioning
confidence: 99%
See 1 more Smart Citation
“…By measuring both the ps transients of parent and fragment and the total translational energy distribution of products as a function of the reaction time, it was evidenced that both the slow and fast components of the H fragment have the same tunneling origin and that the ground state is populated at the second ps*-S 0 crossing and not through a direct pp*-S 0 internal conversion process. 24,37 The H-loss dynamics have also been studied in the time domain. The ps time-evolution of the S 1 excited state of PhOH shows that the lifetime decreases from 2 ns at the band origin 0 0 0 down to 600 ps at the band located 3500 cm À1 above the origin.…”
Section: The Sddj Modelmentioning
confidence: 99%
“…15 This model was ultimately dismissed following the demonstration of the correlation of the excited state lifetime of PhOH and its derivatives with the pp*/ps* gap. 24,34,37 It should be stressed that the cNH 4 (NH 3 ) n clusters can be seen as a very good messenger for characterizing the H loss on a ps* potential. Indeed, the H transfer requires a fairly direct process (the dynamics occur on a repulsive surface) since a process going through hot ground state molecules (H loss mediated by internal conversion to the ground state 33 ) would lead to a statistical process (Intramolecular Vibrational Redistribution: IVR) and the immediate evaporation of the whole cluster or some of the NH 3 molecules.…”
Section: The Sddj Modelmentioning
confidence: 99%
“…By measuring both the picosecond transients of parent and fragment and the total translational energy distribution of products as a function of the reaction time, it was evidenced that both the slow and fast components of the H fragment have the same tunneling origin and that the ground state is populated at the second *-S0 crossing and not through a direct *-S0 IC process. 54 Using picosecond laser, a complete survey of the evolution of the excited lifetime of phenol as a function of the excess energy has shown that the lifetime changes from 2 ns at the band origin 00 0 to 600 ps at 3500 cm -1 above. 54,55 These surveys show that the excitation of A" symmetry vibrational levels in the S1 state shortens the lifetime, mainly through S1-S2 vibronic coupling.…”
Section: Phenol Chromophorementioning
confidence: 99%
“…It is theorized that the photostability of tyrosine arises, in part, from the availability of an excited state relaxation channel in the phenol moiety wherein O-H bond extension facilitates non-radiative decay back to the ground state. [1][2][3][4] This bond extension and complete O-H bond fission in such molecules has thus been the subject of extensive study, both experimentally [5][6][7][8][9][10][11][12][13][14][15][16][17][18][19][20][21] and computationally. 1,[22][23][24][25][26][27][28][29][30][31][32][33] Experimental studies have shown that the photodissociation of phenol following excitation at wavelengths  ~270 nm proceeds via excitation from the ground electronic state, S0, to the first excited singlet state, S1, which has 1 ππ* character in the Franck-Condon (FC) region.…”
Section: Introductionmentioning
confidence: 99%