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Query: KEGG:D00907 (
CET
)
159
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Collisional energy transfer,
CET
, is of major importance in chemical, photochemical, and photophysical processes in the gas phase. In Paper I of this series (J. Phys. Chem. B 2005, 109, 8310) we have reported on the mechanism and quantities of
CET
between an excited benzene and cold benzene and Ar bath. In the present work, we report on
CET
between excited toluene,
p-xylene
, and azulene with cold benzene and Ar and on
CET
of excited benzene with cold toluene,
p-xylene
, and azulene. We compare our results with those of Paper I and report average vibrational, rotational, and translational energy quantities, <DeltaE>, transferred in a single collision. We discuss the effect of internal rotation on
CET
and the identity of the gateway modes in
CET
and the relative role of vibrational, rotational, and translational energies in the
CET
process, all that as a function of temperature and excitation energy. Energy transfer probability density functions, P(E,E'), for the various systems are reported and the shape of the curves for various systems and initial conditions is discussed. The major findings for polyatomic-polyatomic collisions are:
CET
takes place mainly via vibration-to-vibration energy transfer assisted by overall rotations. Internal free rotors in the excited molecule hinder energy exchange while in the bath molecule they do not. Energy transfer at low temperatures and high temperatures is more efficient than that at intermediate temperatures. Low-frequency modes are the gateway modes for energy transfer. Vibrational temperatures affect energy transfer. The
CET
probability density function, P(E,E'), is convex at low temperatures and can be concave at high temperatures. A mechanism that explains the high values of <DeltaE(a)> and the convex shape of P(E,E') is that in addition to short impulsive collisions there are chattering collisions where energy is transferred in a sequence of short encounters during the lifetime of the collision complex. This also leads to the observed supercollision tail at the down wing of P(E,E'). Polyatomic-Ar collisions show mechanistic similarities to polyatomic-polyatomic collisions, but there are also many dissimilarities: internal rotations do not inhibit energy transfer, P(E,E') is concave at all temperatures, and there is no contribution of chattering collisions.
...
PMID:Energy transfer between polyatomic molecules II: Energy transfer quantities and probability density functions in benzene, toluene, p-xylene, and azulene collisions. 1643 15
This paper is the third and last in a series of papers that deal with collisional energy transfer,
CET
, between aromatic polyatomic molecules. Paper 1 of this series (J. Phys. Chem. B 2005, 109, 8310) reports on the mechanism and quantities of
CET
between an excited benzene and cold benzene and Ar bath. Paper 2 in the series (J. Phys. Chem., in press) discusses
CET
between excited toluene,
p-xylene
and azulene with cold benzene and Ar and
CET
between excited benzene colliding with cold toluene,
p-xylene
and azulene. The present work reports on
CET
in self-collisions of benzene, toluene,
p-xylene
and azulene. Two modes of excitation are considered, identical excitation energies and identical vibrational temperatures for all four molecules. It compares the present results with those of papers 1 and 2 and reports new findings on average vibrational, rotational, and translational energy, <DeltaE>, transferred in a single collision.
CET
takes place mainly via vibration to vibration energy transfer. The effect of internal rotors on
CET
is discussed and
CET
quantities are reported as a function of temperature and excitation energy. It is found that the temperature dependence of
CET
quantities is unexpected, resembling a parabolic function. The density of vibrational states is reported and its effect on
CET
is discussed. Energy transfer probability density functions, P(E,E'), for various collision pairs are reported and it is shown that the shape of the curves is convex at low temperatures and can be concave at high temperatures. There is a large supercollision tail at the down wing of P(E,E'). The mechanisms of
CET
are short, impulsive collisions and long-lived chattering collisions where energy is transferred in a sequence of short internal encounters during the lifetime of the collision complex. The collision complex lifetimes as a function of temperature are reported. It is shown that dynamical effects control
CET
. A comparison is made with experimental results and it is shown that good agreement is obtained.
...
PMID:Energy transfer between polyatomic molecules. 3. Energy transfer quantities and probability density functions in self-collisions of benzene, toluene, p-xylene and azulene. 1682 31
