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ABSOLUTE RATE CONSTANT FOR THE
REACTION OF ATOMIC CHLORINE
WITH HYDROGEN PEROXIDE VAPOR
OVER THE TEMPERATURE
RANGE 265-400K
f
J. V. MICHAEL
D. A. W HYTOCK
J. H. LEE
W. A. PAYNE
L. J. STIFF
MAY 1977
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NASA STi
FACILITY
iir'; UT BRANCH
4
GODDARD SPACE FLIGHT CENTER
GREENBELT, MARYLAND
(NASA-TM
-
X-71340) ABSOLUTE RATE CONSTANT
N77-26248
FOR THE REACTION OF ATOMIC CHLORINE WITH
HYDROGEN PEROXIDE VAPOR OVER THE TEMPERATURE
RANGE 265-400 K (NASA) 20 p HC A02/MF A01
Unclas
CSCL 07D G3/25 37031
lk.
ABSOLUTE RATE CONSTANT FOR THE REACTION OF
ATOMIC CHLORINE WITH HYDROGEN PEROXIDE VAPOR
OVER THE TEMPERATURE RANGE 265 - 400 K
o..
J. V. Michael
*
, D. A. Whytock
t
, J. H. Leett^
W. A. Payne and L. J. Stief
Astrochemistry Branch
Laboratory for Extraterrestrial Physics
NASA/Goddard Space Flight Center
Greenbelt, Maryland 20771
*
NAS/NRC Senior Resident Research Associate
t
Department of Chemistry, University of Essex,
Colchester, Essex; on leave 1975-76 at Catholic
University of America, Washington, D. C. 20017
tt
NAS/NRC Resident Research Associate
+
Adjunct Professor of Chemistry, Catholic
University of America, Washington, D. C. 20017
ABSTRACT
Rate constants for the reaction of atomic chlorine with
hydrogen peroxide have been measured from 265-400 K using the
flash photolysis-resonance fluorescence technique. Analytical
techniques were developed to measure [H
2
O
2
3
under reaction
conditions. Due to ambiguity in the interpretation of the
analytical results, the data combine to give two equally
acceptable representations of the temperature dependence:
k
l
= (3.14 + 0.56) x 10
-13
cm molecule
-1
s
-1
independent
of temperature or k
l
= (1.24 + 0.74) x 10
-12
exp (-384 + 168,1T)
3
cm molecule
-1
s
-1
.
The results are compared to previous
work at 298 K and are theoretically discussed in terms of
the mechanism of the reaction. Additional experiments
on the H + H
2
O 2
reaction at 298 and 359 K are compared.
with earlier results from this laboratory and give a slightly
revised bimolecular rate constant of (4.89 + 0.70) x 10-12
exp (-2780 + 280/RT) cm molecule
-1
sec-1.
{
=_
-
INTRODUCTION
The rate constants for chlorine atom reactions with hydrogenous
molecules have become increasingly important due to the
current interest in the potential modification of strato-
spheric ozone concentration. Modelers have shown that
hydrogen abstraction reactions which produce HCt constitute
significant sinks for chlorine atoms, and the potential
depletion of ozone from the U - Ct0 chain is moderated over
that which is predicted if such reactions are not operative.
Due to the known abundance of CH in the stratosphere, one
such important reaction is Ct + CH -"HCt, + CH302
Watson, et al have reviewed other important abstraction
reactions
including
Ct + H
2
-+ HCt, + H
4
and have
explicitly
discussed the stratospheric implications. One possibly
important substrate is hydrogen peroxide which is presumably
formed from the self disproportionation of H0
2
0
These
authors have additionally studied
Ct, + H
2
0
2
-> products
(1)
and have supplied one of the two published room temperature
values to date, the other being by Leu and DeMore.
5
These
two studies show adequate agreement within claimed uncertainties.
On the basis of these determinations and a
presumed temperature
f
_,
-1
t