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Journal ArticleDOI

Absolute rate constant for the reaction of atomic chlorine with hydrogen peroxide vapor over the temperature range 265–400 K

J. V. Michael1, D. A. Whytock2, J. H. Lee1, Walter A. Payne1, Louis J. Stief1 
Goddard Space Flight Center1, University of Essex2
01 May 1977-Journal of Chemical Physics (American Institute of Physics)-Vol. 67, Iss: 8, pp 3533-3536
TL;DR: In this article, the rate constants for the reaction of atomic chlorine with hydrogen peroxide were measured from 265-400 K using the flash photolysis-resonance fluorescence technique.
Abstract: Rate constants for the reaction of atomic chlorine with hydrogen peroxide were measured from 265-400 K using the flash photolysis-resonance fluorescence technique. Analytical techniques were developed to measure H2O2 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. 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 + H2O2 reaction at 298 and 359 K are compared with earlier results from this laboratory and give a slightly revised bimolecular rate constant.

Summary (1 min read)

Jump to: [INTRODUCTION][2 EXPERIMENTAL] and [RESULTS]

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 stratospheric 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.

2 EXPERIMENTAL

  • Within five minutes after collection, a known volume of 1M H2 sO4 was introduced into the sample bulbs, and the bulbs were thoroughly shaken in order to extract the gaseous H2O Hydrogen peroxide (90% from FMC Corporation) was thoroughly outgassed and was pumped at 273 K for at least 30 minutes to remove H 2O.
  • The sample was then further pumped for 5-10 minutes at 298 K before making mixtures.

RESULTS

  • Ctl so that pseudo-first order kinetics are applicable, and the decay of chlorine atoms is given by EQUATION With the described apparatus, the inixturo inlet and exit ports to the cell assembly are not symmetric.
  • Thus, samples are always preheated or cooled before entering the cell.
  • Values of kbi are extracted from (a) the assumption that the arithmetic mean is valid and (b) the assumption that the "after the cell" measurement is appropriate.
  • The authors note that the experimental results, either (a) or (b), are more compatible with the latter approach and may suggest important contributions from reactions (5) and/or (6) .

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^/7^ X - 71,3 +^4
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
(^
4
f v
J
g4
V I
1,. 1,
7
i
L l
RECl
`
r ro
}
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
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Theoretical Investigations of Rate Coefficients of H + H2O2 → OH + H2O on a Full-Dimensional Potential Energy Surface

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Xiaoxiao Lu1, Xiaoxiao Lu2, Xingan Wang1, Bina Fu2, Dong-Hui Zhang2 
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16 Apr 2019-Journal of Physical Chemistry A
TL;DR: Considering that the old experimental values vary widely from different groups, it is expected that the theoretical investigations can motivate new experimental work, which facilitates a more reliable comparison between theory and experiment.
Abstract: The thermal rate coefficients of H + H2O2 → OH + H2O were obtained theoretically based on a recent fundamental invariant-neural network potential energy surface. The ring polymer molecular dynamics (RPMD) calculations were performed to get the rate coefficients with quantum effects, which are in good accord with some experimental values. The rate coefficients derived from extensive quasi-classical trajectory and canonical variational transition-state calculations also predict well the experimental results at high temperatures. The RPMD rate coefficients for H + H2O2 → OH + H2O are larger than H + H2O2 → H2 + HO2, but at very low temperatures below the room temperature, the H2 + HO2 channel becomes dominant due to significant quantum tunneling effects in the H atom transfer process. Considering that the old experimental values vary widely from different groups, we expect that our theoretical investigations can motivate new experimental work, which facilitates a more reliable comparison between theory and experiment.

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01 Jan 1979

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S. Marouani1, S. Marouani2, H. Koussa1, M. Bahri1, Majdi Hochlaf2, H. Batis 
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15 Jul 2009-Journal of Molecular Structure-theochem
TL;DR: In this article, the authors performed ab initio calculations followed by transition state theory treatment to investigate the gas phase elementary bimolecular reaction of hydrogen peroxide with chlorine atom H2O2+Cl.
Abstract: Ab initio calculations followed by transition state theory (TST) treatment are performed to investigate the gas phase elementary bimolecular reaction of hydrogen peroxide with chlorine atom H2O2 + Cl. The electronic structure calculations are done using the post Hartree–Fock MCQDPT2//CASSCF approach and the aug-cc-pVTZ basis set. Two reaction pathways are considered: the H-abstraction path (denoted as path1) and the OH-abstraction one (denoted as path2). For each path, the activated complex is located. The zero point vibrational energy corrected values of the classical barrier heights were predicted to be 3.2 and 10.4 kcal/mol for path1 and path2, respectively. Reaction rate constants are calculated for the temperature range 200–2500 K using the transition state theory (TST) incorporating a Zero-Curvature Tunneling correction. The results of theoretical rate constants for path1 are in good agreement with the available experimental data. The calculated branching ratios show that the H-abstraction path is the most probable process occurring for temperatures below 1500 K confirming hence the experimental findings. The contribution of path2 to the reaction dominates at higher temperatures.

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Princeton University1, East China University of Science and Technology2, University of Tennessee3
17 Nov 2021-Journal of Physical Chemistry A
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References
More filters
Book
Textbook of quantitative inorganic analysis

[...]

Izaak M. Kolthoff, E. B. Sandell
01 Jan 1948
TL;DR: Textbook of quantitative inorganic analysis as discussed by the authors, Textbook of qualitative and quantitative analysis of inorganic properties, textbook of quantitatively analytically-inorganic analysis, as discussed by the authors.
Abstract: Textbook of quantitative inorganic analysis , Textbook of quantitative inorganic analysis , مرکز فناوری اطلاعات و اطلاع رسانی کشاورزی

2,103 citations

Journal ArticleDOI
Chlorofluoromethanes in the Environment

[...]

F. S. Rowland1, Mario J. Molina1
University of California, Irvine1
01 Feb 1975-Reviews of Geophysics
TL;DR: In this article, the photoprocesses of atmospheric chlorofluoromethanes, including their ultimate sinks, are studied. Butt et al. present a detailed study of the photodissociation process of chlorofluromethane.
Abstract: A study is presented on the photoprocesses of atmospheric chlorofluoromethanes, including their ultimate sinks. Topics covered include: current inventories of atmospheric trichlorofluoromethane and dichlorodifluoromethane, absorption cross-sections for photodissociation of chlorofluoromethanes, mechanisms and quantum yields for photodissociation of CF/sub 2/Cl/sub 2/ and CFCl/sub 3/, solar irradiation flux versus wavelength and altitude, atmospheric diffusion models, chain reactions in the ozone layer, the chloroxyl chains for decomposition of O/sub 3/, abstraction reactions by thermal chlorine atoms, release of Cl atoms by hydroxyl radical attack on hydrogen chloride, methane concentrations at 50 km, rate constants for ClO/sub x/ reactions with O/sub 3/ and oxygen atoms, chain terminating reactions, the importance of symmetrical dioxychloride in the stratosphere, fluorine atom chains, possible removal of chlorofluoromethanes by electron capture and/or ionic reaction, possible chlorofluoromethane removal by reaction with singlet oxygen, hydrolysis of chlorofluoromethanes, possible reactions of chlorofluoromethanes with aerosol particles in the stratosphere, calculated O/sub 3/ depletion by chlorine-containing species, multi-dimensional calculations, feedback in the ozone depletion calculation, increased odd oxygen production with O/sub 3/ depletion, time delay effects in the appearance of O/sub 3/ depletion, time concentration patterns with a one year stepfunction injection of CF/sub 2/Cl/sub 2/ and for several hypothetical models of chlorofluoromethane releasemore » stratospheric concentrations from CF/sub 2/Cl/sub 2/ injected by 1975, estimates of consequences for two different manufacturing patterns for CF/sub 2/Cl/sub 2/ between 1975 and 1990, current stratospheric levels of chlorine-containing compounds, possible biological and climatological effects of stratospheric O/sub 3/ depletion, and observable trends in the average O/sub 3/ concentration of the atmosphere.« less

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