TY - JOUR
T1 - The non-ergodic nature of internal conversion
AU - Sølling, Theis Ivan
AU - Kuhlman, Thomas Scheby
AU - Stephansen, Anne Boutrup
AU - Klein, Liv Bærenholdt
AU - Møller, Klaus Braagaard
PY - 2014
Y1 - 2014
N2 - The absorption of light by molecules can induce ultrafast dynamics and coupling of electronic and nuclear vibrational motion. The ultrafast nature in many cases rests on the importance of several potential energy surfaces in guiding the nuclear motion - a concept of central importance in many aspects of chemical reaction dynamics. This Minireview focuses on the non-ergodic nature of internal conversion, that is, on the concept that the nuclear dynamics only sample a reduced phase space, potentially resulting in localization of the dynamics in real space. A series of results that highlight the nonstatistical nature of the excited-state deactivation process is presented. The examples are categorized into four groups. 1) Localization of the energy in one degree of freedom in S2→S1 transitions, in which the transition is either determined by the time spent in the S2→S1 coupling region or by the time it takes to reach it. 2) Localization of energy into a single reactive mode, which is dictated by the internal conversion process. 3) Initiation of the internal conversion by activation of a single complex motion, which then specifically couples to a reactive mode. 4) Nonstatistical internal conversion as a tool to accomplish biomolecular stability. Herein, the discussion on nonstatistical internal conversion in DNA as a mechanism to eliminate electronic excitation energy is extended to include molecules with an SS bond as a model of the disulfide bridge in peptides. All of these examples are summed up in Kasha's rule. For systems with multiple degrees of freedom it will be possible to locate an appropriate motion somewhere in phase space that will take the wavepacket to the coupling region and facilitate an ultrafast transition to S1. Once at S1, the momentum of the wavepacket is lost and the only options left are the statistical processes of reaction or light emission. Spotlight on energy localization: Coupling of electronic states by specific vibrational degrees of freedom leads to ultrafast internal conversion in a range of different molecular systems. The electronic structure defines the potential energy surfaces, but it is the nuclear dynamics that restricts and determines what parts of the surfaces will be visited during the transition processes (see picture).
AB - The absorption of light by molecules can induce ultrafast dynamics and coupling of electronic and nuclear vibrational motion. The ultrafast nature in many cases rests on the importance of several potential energy surfaces in guiding the nuclear motion - a concept of central importance in many aspects of chemical reaction dynamics. This Minireview focuses on the non-ergodic nature of internal conversion, that is, on the concept that the nuclear dynamics only sample a reduced phase space, potentially resulting in localization of the dynamics in real space. A series of results that highlight the nonstatistical nature of the excited-state deactivation process is presented. The examples are categorized into four groups. 1) Localization of the energy in one degree of freedom in S2→S1 transitions, in which the transition is either determined by the time spent in the S2→S1 coupling region or by the time it takes to reach it. 2) Localization of energy into a single reactive mode, which is dictated by the internal conversion process. 3) Initiation of the internal conversion by activation of a single complex motion, which then specifically couples to a reactive mode. 4) Nonstatistical internal conversion as a tool to accomplish biomolecular stability. Herein, the discussion on nonstatistical internal conversion in DNA as a mechanism to eliminate electronic excitation energy is extended to include molecules with an SS bond as a model of the disulfide bridge in peptides. All of these examples are summed up in Kasha's rule. For systems with multiple degrees of freedom it will be possible to locate an appropriate motion somewhere in phase space that will take the wavepacket to the coupling region and facilitate an ultrafast transition to S1. Once at S1, the momentum of the wavepacket is lost and the only options left are the statistical processes of reaction or light emission. Spotlight on energy localization: Coupling of electronic states by specific vibrational degrees of freedom leads to ultrafast internal conversion in a range of different molecular systems. The electronic structure defines the potential energy surfaces, but it is the nuclear dynamics that restricts and determines what parts of the surfaces will be visited during the transition processes (see picture).
KW - electronic structure
KW - energy localization
KW - internal conversion
KW - molecular dynamics
KW - potential energy surfaces
U2 - 10.1002/cphc.201300926
DO - 10.1002/cphc.201300926
M3 - Journal article
C2 - 24375886
AN - SCOPUS:84894105287
SN - 1439-4235
VL - 15
SP - 249
EP - 259
JO - ChemPhysChem
JF - ChemPhysChem
IS - 2
ER -