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Pressure and temperature dependence of the OH radical reaction with acetylene
Volume
CHEhllCAL
93, numbcr 4
PHYSICS LEI-TXRS
PRESSURE AND TEMPERATURE DEPENDENCE OF THE OH RADICAL
REACTION
WITH ACETYLENE
R A PERRY
Recclvcd I3 August 1982. m final form 72 Scptcmbcr
Absolulc ol’20-403
KIIC constants
for the rcac11on ofOH
1982
WIII acctylcnc
Torr usmg a flash photolysa-rcsonancc
lluorcsccnre
wcrc dctcrmmcd tcchmquc
at 297 and 419 K for thu 101.d pru~rc\
The rate coclTic~cnt k was found to bc pwrurc
dcpcndcnt below 200 Torr at both 297 and 429 K, but \\a m the high-prcssurc hmellc rctxm abolc a tool prcww TOW. TIE best fit to the data over the prcssurc and tcmpcrnrurc r,mgc studred wasgwrn by lhc c\pressron k(T,~)b, + I). ~11crc /J IS the prcssurc anTorr x lo-” C\P[(-327 2 400)/fU~/(3O/p
suits, a stgmlicant zero-prcssurc mterccpt WJS observed in the e\trapolatlon of the low-prcssurc data, m dlsagreement with both hq$-pressure-room tempcraturc results [9) and carhcr low-pressure c\penmcnts [5,7.81.
1. Introduction The hydroxyl radical IS Important m combustion processes [ I,?], dswell as in the chenustry of the troposphere
and stratosphere
constant
deterrrunatlons
reactlon
[4--91
[3].
Whdc
numerous
have been carned
rate
out for the
OH + C,H, _ ” -+ products,
(1)
less effort has gone mto a systemattc study of the pres. sure dependence of this reactton at elevated temperatures [IO] As the modehng of O#etylenc flames becomes more sophlsticatcd, a need ehtsts for detallcd kmetlcs at these higher temperatures. Also, acetylene 1x1s
of X0 = I 18
In tlrc prcscnr study WC seek to resolve
thcsc dlszarcc-
of rmc11011 (I) at higher temperatures and by InvrsGgAting both the 111gl1-and low-prcssurc limlts of tile rcactlon to bcttcr understand the kmetlcs and possible nrcchanisms. Absolute rate constants arc determrncd, using the flash photolysls-rcsonancc fluorcsccncctcchotquc mcnts
[9],
by studying
the pressure
for the reactlon
surcs of 20-403
ofOH
Torr
depcndcncc
with C?Hl
dt total
m the tcmperaturc
prcs-
range 297-
429 K.
bee11 mlplrcated asI sootprecursor in hydrocarbon/
oxygen flames [I I] thus making tts oxidation chenustry of interest to those WIIO wish to understand soot formation. Recently the reaction of OH with acetylene IKIS been studied as a function of :emperature and pressure [lO].The results, using a FP-RF (flash photolynsresonance
fluorescence)
results 191, obtamed ed to account
techmque,
using a slrmlar
Imply that earhcr techmque,
for a strong temperarurc
the high-pressure linut.
0 009-2614/82/0000-0000/S
Also,
had fad-
dependence
in these more
recent
KI
re-
02.; 5 0 1982 North-Holland
2. Experimental
The apparatus scribed
previously
will be given
here
and teclmiqucs Hydrovyl
the pulsed vacuum-ultraviolet
lower-wavelength
used have been dc-
[I 1, hence. only a brlcf summary
hmlts
radicals
for the Hz0
were set by the USCof the following
>1050
were
photolysls
produced of Hz0
by The
photodlssoaal:on cutoff
windows.
W(LIF);>IXO~(C~F~).
331
93. nulniwr 4
Voluns
LODecenlbcr 1982
CHEMICAL PHYSICS EITERS
OH r3dlc31 conccntratlons were momtorcd as a functmn of tnne after the flash by resonance fluorescence using 3 cooled Ehll 9659QB photonultlpher fitled an nitcrfersncc filter lransnuttmg the 3064 A =O-+ X?ll,u” =O).Thc Inter-
wth
hand ofOH(A’S+,$
resonance rxhatlon from a discharge and the dctcction sysrenr dcfincd a fluorescence v~cwng 7onC wl~osc cross section WIS 2 cm In dlamcter TINS rcglon wx well scpsrdtcd from the reaction vessel walls. mmmnzmg wall losses of the OH radicals The rcxtlon vcsscl was enclosed In a furnace which could be held constant IO bcttcr than +5 K The gas temperastm~on of the
Iamp
1UCL WJS
muntcd
rl~.?3SUd
by
3
inside the rcacflon WSSC~.
The flash lamp wds typlcally operated at discharge cncrg~cs
of
I7 5-50
J per flash at rcpctitlon rates of
one flasl~ every 3 s. Signals wcrc obt,nncd
by photon counting in conJunction with multlchnrmcl scllling. Decay curves of OH radmls were accumulated from 10 lo 1GODflashes, depcndmg upon slgnal strengths. Hydrokyl radical hnlf-lwes ranged from 1.72 to I IO ms In order to avojd the accumulation of photolysis or rcdcllon products all eqcrmicnts were carried out under flow condltlons so Ihat Ihc gas IIIIYIUIC in the vessel H;~S rcplcnlshcd cvcry few flosl~rs. Tile partial prcssurc of Hl0 m rlre cell mnged from O,Oi to 0.16 Torr The gases used had the followq purlry levels accordmg IO 111~manufacturer. Ar> 9999S%, C,H, > 99 6% FurIhcr anslys~s of IIIC *I% C,H2 m argon rtukture, aitcr
passtng through Matlrcson model 454 gas purifier
10 rcniovr lhc acetone, gave the foilowing mass spcc-
trA analysts. argon. 98.99, acctylcne, 0 975; nitrogen, 0 0 15, and acetone, 0 017. No further effort MIS made lo purify rhe gas niixturc
4
2
0
8 I
K2H21 molecule cm-36
~~lrO~w~~~~ultle\tltI?rtwxOupk
Tlg I Plotsof the OH decay
rate
agn~nst
tion for the total prcssurcs studied
IO’J
acctylcnc conccnlrs-
at 429 K. Dnra pomls dls-
placed vcrt~cally for clarity (0 s-’ for 20 3 Torr,O,
20 s-’
for
I 4 Torr.o.35 s-’ lor 101 5 Torr. 0, 30 s-* for 201.3 Torr, v, 50 s-’ for 403.0Torr. q
5
spondmg resonance fluorescence intensrtles,liI, IS the first-order rate for removal of OH In the absence of added reactant (pnmanly attributed to diffusion out of the viewing zone and to reactlon wth impuntlcs), and k IS the rate constant for reaction (1). In all cuperimcnts, exponential decrys of the resonance fluorescence s~gnolwere obscrvcd over ;It lcast two half-hves, and the measured rates, defined as R
were found to depend linearly on the concentration of acetylene. Rate constants were measured over a pressure range of 20403 Torr. Fig. I shows typlcd plots of measured rates versus C,H, concentrations. A vanatlon of a factor of 3 in the flash energy produced no vanatlon, wthm experi-
= (f - co) - lo So/S,,
mental
uncertainty,
m the ntc
constants,
mdrcatmg
that secondary reactions were negligible under the ex3. Results and discussion All cxpermlenrs wcrc performed with the acetylene concentrations m great cxess over ~IIC mltlal OH radlcal concentrations The pseudo-first-order decays of the OH radical concmtrat~on, [OH], arc thus given by the inkgrated
rate cvpression
lW,WHll
= SO/s,
= exp {(k(j+ k [reacIanl])
OH mdmls with C2H2 proceeds wa the initial addIllon of OH radical to C,H,, followed by stabilizatm or decomposltron of the OH-C2H, (I - to)},
whcrc [OHIO and [OH Jr arc the concentrations of OH at tmes to and t, rcspcctlvcly.Sg and S, are the corre-
332
perimental condnlons used. Phololysls products orher than OH can be estimated to lead to errors In the measured rate constant of <5- IO% 191. The rate constant k given In table I and plotted qpnst total pressure in fig. 2 shows that reachon (I) is in the fall-off regmn beIow 200 Torr both at 297 and 429 K. This observation mdlcates that rhe reaction of
OH + C,H2 f HOC,H;,
HOC,H;
+ M -+ HOC,H,
+ M.
adduct,
Volume 93, number 4
Ttlblc
Rate
CHEMICAL
PHYSICS LEnERS
I
constantsR(+) for lfw rcxl~on orOH rddrCJk wth CzH2. The mdrcatcd error hmltsarc 111ccslmratcd overall error IIIIIIIS which mcludc the Icasl~u.rcs standard dcwrrmn (2-X%) as ucil as the esttmatcd accuracy limtts of 0111cr psr.mwtcn suclr
a+ prcssurc
IO Dsccmbcr 1982
and calculated Is ketcnc
heats of formatson
lhen estimates
The UI~II~I~~Cproducts
acctylcnc arc uwcrlairt, Prcssurc (Toir)
A-x 10” (cm” molecule-’ 5-l)
(IO
297
25 6 50 7 99 8 707.9 JO? 1
HO f C,H, I_ the
04~
to other
stud~cs of Perry et al. [9] and Michael
hlcrature
val-
and the
ct al [lO\,was
a
pressure dcpcndcnce observed in the remIt
iO90
hlrchael et 31 .I slightly
IIIglIer value fork
fddr
study or 31 thy’ l~gh-
repm was
514
5 07 2 0.5 1
in tk present nlcasurenlet~ts of tltc pressure dcprndtncc of thfs rcactlon at 429 K such a drain3tiL shffl m the hlgfkprcssure hmit was not observed In facf, II appears that the varfatlon m the pressure dcpcndcncc of rlus rcacrlon wrth ternpemturc is sir&r to the fc3cfion 0fOH Wfh
s
6 85 5 0 70
201 3
806+089
403 0
7.89i
to exclude
being present,
I IO
the possibday
of
(2) to zero pressure
lends
to
dercrmincd by M~chacl et al. [IO]. Also, the nalurc of the prcssurc dependence obscrvcd here mdtcntcs kat rcactlon (2) may 197 and 129 K arc below ~bc rnterccpt
nle~atlIet1~~
reaction,
and IIIC
dcpctldcot.
ethylale [I_‘].
I c.
+ H.
of the data
hmrr was found,
found to be hlgltly tcsi~~rature
mdlcatc that these channels are mmor al atmospherrc pressures. In particular. the low.presstrrc vntues at both
not be a simple
value IS Lomparcd
may
The prcsclil
pressure
--* C,H,O _..
e\trapolatlon
that a thrrd body
357~000
WI 11c it is difficult
_hannels
36 kcal, Indicates
cvcn at Hugh tcmpcraturcs
ues In table 2 Note that only rn &is study
5.67 z 0 57 661~066
691
[9,10],
bc involved h&pressure
0 31
488:
adduct
of the re~cttoi~ of OH with
but the stabthty of 111~HOC&
20 3 fOl
other
3.082
of
M~cltacl et al. [lOI for the hat of fortnatlon of frarw tton complex must bc made
and ~~~~tan~ c~n~tnzmtron~
Tcmpenturc
[ 101. If the product
sImIlar fo the calculatlon5
but rather
tts rate may be associated wtth an in~raInolccular arrangement with an appreciable energy barner
The actual tcmpcraturc dcpendcnce of rhc iqltpressure hnfit has niaJor r~~~pl~caIronsrcgxdlng the mlparlance of the terwolecular
renction 31 IuJlcr
Wm.
perrttures. For example, c~trJpolatIorI of the present data tn fig 3 to hrgfi tcnrpcr&urc >I 500 K. results in contribution Fran, this IcnnolCCular rowtioff, as compared to postulated altcmate I~WII~IUSI~~S 1131, SuCll JS
a signikxnt
that rcto
I ,3
hydrogen nagratIon. If the actual product IS the ~somcr HOC =CH. thw bnrrrer can bc esttmnted from known
Table 2 Compwcon of hiphaprcssurr room-lcmperxure X ulth irlcmlurc ~luss _---Total prescurc
10’3 XX
fTorr)
(art3 ,i~‘ll~cul~-~s-9
_-_--.-I (Ar or He)
unk.no\\ n
IO-20 (HC or H2/N20) 1.05-I f(k) ‘O-SOO(Hc) 200-400 (Ar) IN-600(Ar) ?03-J03(Ar)
IOh) 1.92 06
85 20+ 06 1.6.5+015 6 79 ?:0.70 7.76 f 0 73 6.75 ?I0.70
r31c ranslJnl
Teclmlqucaf
_Kcf
__-DI -LSR
IJI 151
FP-RA Dr-RA I‘P-RIr-P-RI-
161 I71
Dt--ESR
t-P-Rr
rp-Rr
198;
1101
nIlr\~orli
3) TOTALPRESSUREkvd rug. 2. Plols of bm~olccular rate conslanlsA w+nst tolid pres-
SW of argon drlucnl a 297 K, 0, and 429 I<. n-
DT-LSR, dtschargc l-lox wrrb ESR detection. DE‘-RA,dwch.trg~~flow WIIII rcson3n~ absorprton, TP-RA. fl.~sh pbotolysls-rcson.mcc absorpllon. TP-RI-, llasb photol)sw. rcsonancc fiuurcscunce b, rrl where PI IS slorcluomctry fxlor, ~lurh MS not rcporlcd.
333
CHEMICAL
Vohimc 9 3, number -I
PHYSICS
LETt-l-ERS
IO Drcrmbcr
cd tn Vandooren
10”.
1982
and vrm Tigpelen’s experimenr.
Work is under way to establtsh the rate of reaction (I)
at hlgbcr temperatures
mlportance
in
order
to further
assess the
of thts reaction at flame temperatures.
From tlte present work we conclude sure hmtt is not stgnificantly at Icast up to 430K.
that the hgh-pres-
temperature
dependent
Also the absence of a stgnificant
zero-pressure lntcrcept IS clgam confirmed.
Acknowledgement 10”
I
0
4
2
5
1000,TK;
t-1:. 3 ~r~hco~~~\ plot 0f log h egalnFt 1000/r(~) data(o), and Jonss to
to1 our
PCTF)CI al (91 (0). M~chxl ct al.1 IO] (x). rcnlmorc [ ‘51 (o),Vandoorcn and vanT~f@cn II-I] (- - -).
and BFO\~I? ~1 aI 1141 (-.
---)
TIIIS work was supported
by the U S Department
of Energy. The asststance of Jon Meek,
The sohd lone is the best fit
and Jim van de Vreugde
IS
greatly
ttonal thanks go to Charles Otto, spMtral
Dean Wdliams,
appreciated LLNL,
Addt-
for the mass
annlysis.
contbtncd datd of Pcrr! ct aI UIIII thr prchcnt datJ
OH + C,H,
By combmmg prcscnt
M,,
+ Hz0 + C2H.
the data of Perry ct al. [9] to descrtbc
e- -WRT
KS. An empmcal
I.lSX
=
IO-12
c\p[(-377+400
TIIIS expresston
Arrltcntus
Further
extrapolation
work IS required
IS
the
Ltndentann
of the data IS wartoJustify
using this
stmplc cmpwcal fit m modeltng combJstlon systems as fix eUrapolatton to htgher temperatures may be SubJ’ct
to
considerable
II should be noted
could reproduce van Ttggclcn
the Arrhcnms
[14] obtained
Torr) O,/acetylene postulated
error.
that usmg this expression
one
plot of Vandooren
from a low-pressure
and
(40
flame wltere tlte reactton (7) was
to explam
the formatton
measured by molecular
of C2H20,
as
beam sdmpltng and mass spec-
trometry analysts Recogmzing the dtfficulty m dtstingutshing between ketene and the isomer HOCCH m a molecular
beam mass spectrometer.
tsts that reactton
0,
+ HOHCCH
(I)
334
e\-
followed by
--c HO2 + HOCCH
may be responstble
the possibility
for the budd-up
References 111 R ht. rrlstrom nod AA Wcstcnbcrg, rlamc structure (McCroa-Hdl, New Yorh, 1965). 12 I A G Gabdon and H G. Wolfhmd. l-lames. thar structure, radtatlon snd tcmpcraturc, 3rd Ed. (Chapman and Hall. London, 1970). 131 R. Alhmson. K.R Darvall, A C. Lloyd, Abl Wmc and
J.N. Pnls Jr., Advan, Photochcm. II (1979) 375 I-I] 1V.C Wilson and A A. Wcstcnbcrg, 1Ilh Symp. (1111.) on
cnl)/RT]
I
best fit IO all t!ie data USIIQ 3 modtficd
ranted
kinet-
expression
30/F, +
ifnn
tile
k = I 55
luglt-pressure
tl~c
where p IS rhc prcssurc tn Torr form.
(3)
fit of the present data over the enttrc
pressure range gives the followng
k(T.P)b,
wtl~
the clpresston
data one can obtain
X IO-”
= 6 kcal
(4) mass 42 as measur-
Combust!on.Thc Combustion Inshtutc (1967) p. 1143 I.5 I JI. Brcun snd CP. Class. Intern J. Chcm. K~net. 3 (1971) I45 161 1.W hl. Smith and R. Zcllncr. J Chcm. Sot roradny Trans.1169 (1973) 1617 17 I A V. pastrclna nnd R.W. Carr Jr., Intern J. Chcm. Kmct. 6 (1974) 587. [“I D D. Davis. S. I-lschcr, R. Schrl-r, R.-l-. Watson and W
Bolhqcr, J. Chcm. Phys. 63 (1975) 1707. 19) R.A Pcny, R Athmson and J N. PII& Jr,
J. Chcm.
Phys
67 (1977) 5577. IO] J V. MIchxI, D r. Nova. R P. Borkowskt, WA. Payne and LJ Sncl, J Chcm. Phys. 73 (1980) 6108 I1 I C Porter. 4th Symp (Int ) on Combustron.Thc tlon Institute (1953) p. 248.
Combus-
121 R Atkmson, RA. Perry and J.N. Pltts Jr., J.Chcm. Phys 66 (1977) 1197. 131 \V.G. Brow, R P. Porter, J.D. Vcrlm and A W. CM, 12th Symp. (lnr.) on Combustion,Thc Combusuon
(1969) p 1035 . _ Inslttule _ . 1141 J. vandooren dttd P.J. vanTtg$len, 16th Symp. (Int.) on Combustlon,Thc Combustion lnstitutc (1976) p. 1133. 115 I C P rcmmore and C.W. Jones, J. Chcm. Phys. 41 (1964) 1887.
CHEhllCAL
93, numbcr 4
PHYSICS LEI-TXRS
PRESSURE AND TEMPERATURE DEPENDENCE OF THE OH RADICAL
REACTION
WITH ACETYLENE
R A PERRY
Recclvcd I3 August 1982. m final form 72 Scptcmbcr
Absolulc ol’20-403
KIIC constants
for the rcac11on ofOH
1982
WIII acctylcnc
Torr usmg a flash photolysa-rcsonancc
lluorcsccnre
wcrc dctcrmmcd tcchmquc
at 297 and 419 K for thu 101.d pru~rc\
The rate coclTic~cnt k was found to bc pwrurc
dcpcndcnt below 200 Torr at both 297 and 429 K, but \\a m the high-prcssurc hmellc rctxm abolc a tool prcww TOW. TIE best fit to the data over the prcssurc and tcmpcrnrurc r,mgc studred wasgwrn by lhc c\pressron k(T,~)b, + I). ~11crc /J IS the prcssurc anTorr x lo-” C\P[(-327 2 400)/fU~/(3O/p
suits, a stgmlicant zero-prcssurc mterccpt WJS observed in the e\trapolatlon of the low-prcssurc data, m dlsagreement with both hq$-pressure-room tempcraturc results [9) and carhcr low-pressure c\penmcnts [5,7.81.
1. Introduction The hydroxyl radical IS Important m combustion processes [ I,?], dswell as in the chenustry of the troposphere
and stratosphere
constant
deterrrunatlons
reactlon
[4--91
[3].
Whdc
numerous
have been carned
rate
out for the
OH + C,H, _ ” -+ products,
(1)
less effort has gone mto a systemattc study of the pres. sure dependence of this reactton at elevated temperatures [IO] As the modehng of O#etylenc flames becomes more sophlsticatcd, a need ehtsts for detallcd kmetlcs at these higher temperatures. Also, acetylene 1x1s
of X0 = I 18
In tlrc prcscnr study WC seek to resolve
thcsc dlszarcc-
of rmc11011 (I) at higher temperatures and by InvrsGgAting both the 111gl1-and low-prcssurc limlts of tile rcactlon to bcttcr understand the kmetlcs and possible nrcchanisms. Absolute rate constants arc determrncd, using the flash photolysls-rcsonancc fluorcsccncctcchotquc mcnts
[9],
by studying
the pressure
for the reactlon
surcs of 20-403
ofOH
Torr
depcndcncc
with C?Hl
dt total
m the tcmperaturc
prcs-
range 297-
429 K.
bee11 mlplrcated asI sootprecursor in hydrocarbon/
oxygen flames [I I] thus making tts oxidation chenustry of interest to those WIIO wish to understand soot formation. Recently the reaction of OH with acetylene IKIS been studied as a function of :emperature and pressure [lO].The results, using a FP-RF (flash photolynsresonance
fluorescence)
results 191, obtamed ed to account
techmque,
using a slrmlar
Imply that earhcr techmque,
for a strong temperarurc
the high-pressure linut.
0 009-2614/82/0000-0000/S
Also,
had fad-
dependence
in these more
recent
KI
re-
02.; 5 0 1982 North-Holland
2. Experimental
The apparatus scribed
previously
will be given
here
and teclmiqucs Hydrovyl
the pulsed vacuum-ultraviolet
lower-wavelength
used have been dc-
[I 1, hence. only a brlcf summary
hmlts
radicals
for the Hz0
were set by the USCof the following
>1050
were
photolysls
produced of Hz0
by The
photodlssoaal:on cutoff
windows.
W(LIF);>IXO~(C~F~).
331
93. nulniwr 4
Voluns
LODecenlbcr 1982
CHEMICAL PHYSICS EITERS
OH r3dlc31 conccntratlons were momtorcd as a functmn of tnne after the flash by resonance fluorescence using 3 cooled Ehll 9659QB photonultlpher fitled an nitcrfersncc filter lransnuttmg the 3064 A =O-+ X?ll,u” =O).Thc Inter-
wth
hand ofOH(A’S+,$
resonance rxhatlon from a discharge and the dctcction sysrenr dcfincd a fluorescence v~cwng 7onC wl~osc cross section WIS 2 cm In dlamcter TINS rcglon wx well scpsrdtcd from the reaction vessel walls. mmmnzmg wall losses of the OH radicals The rcxtlon vcsscl was enclosed In a furnace which could be held constant IO bcttcr than +5 K The gas temperastm~on of the
Iamp
1UCL WJS
muntcd
rl~.?3SUd
by
3
inside the rcacflon WSSC~.
The flash lamp wds typlcally operated at discharge cncrg~cs
of
I7 5-50
J per flash at rcpctitlon rates of
one flasl~ every 3 s. Signals wcrc obt,nncd
by photon counting in conJunction with multlchnrmcl scllling. Decay curves of OH radmls were accumulated from 10 lo 1GODflashes, depcndmg upon slgnal strengths. Hydrokyl radical hnlf-lwes ranged from 1.72 to I IO ms In order to avojd the accumulation of photolysis or rcdcllon products all eqcrmicnts were carried out under flow condltlons so Ihat Ihc gas IIIIYIUIC in the vessel H;~S rcplcnlshcd cvcry few flosl~rs. Tile partial prcssurc of Hl0 m rlre cell mnged from O,Oi to 0.16 Torr The gases used had the followq purlry levels accordmg IO 111~manufacturer. Ar> 9999S%, C,H, > 99 6% FurIhcr anslys~s of IIIC *I% C,H2 m argon rtukture, aitcr
passtng through Matlrcson model 454 gas purifier
10 rcniovr lhc acetone, gave the foilowing mass spcc-
trA analysts. argon. 98.99, acctylcne, 0 975; nitrogen, 0 0 15, and acetone, 0 017. No further effort MIS made lo purify rhe gas niixturc
4
2
0
8 I
K2H21 molecule cm-36
~~lrO~w~~~~ultle\tltI?rtwxOupk
Tlg I Plotsof the OH decay
rate
agn~nst
tion for the total prcssurcs studied
IO’J
acctylcnc conccnlrs-
at 429 K. Dnra pomls dls-
placed vcrt~cally for clarity (0 s-’ for 20 3 Torr,O,
20 s-’
for
I 4 Torr.o.35 s-’ lor 101 5 Torr. 0, 30 s-* for 201.3 Torr, v, 50 s-’ for 403.0Torr. q
5
spondmg resonance fluorescence intensrtles,liI, IS the first-order rate for removal of OH In the absence of added reactant (pnmanly attributed to diffusion out of the viewing zone and to reactlon wth impuntlcs), and k IS the rate constant for reaction (1). In all cuperimcnts, exponential decrys of the resonance fluorescence s~gnolwere obscrvcd over ;It lcast two half-hves, and the measured rates, defined as R
were found to depend linearly on the concentration of acetylene. Rate constants were measured over a pressure range of 20403 Torr. Fig. I shows typlcd plots of measured rates versus C,H, concentrations. A vanatlon of a factor of 3 in the flash energy produced no vanatlon, wthm experi-
= (f - co) - lo So/S,,
mental
uncertainty,
m the ntc
constants,
mdrcatmg
that secondary reactions were negligible under the ex3. Results and discussion All cxpermlenrs wcrc performed with the acetylene concentrations m great cxess over ~IIC mltlal OH radlcal concentrations The pseudo-first-order decays of the OH radical concmtrat~on, [OH], arc thus given by the inkgrated
rate cvpression
lW,WHll
= SO/s,
= exp {(k(j+ k [reacIanl])
OH mdmls with C2H2 proceeds wa the initial addIllon of OH radical to C,H,, followed by stabilizatm or decomposltron of the OH-C2H, (I - to)},
whcrc [OHIO and [OH Jr arc the concentrations of OH at tmes to and t, rcspcctlvcly.Sg and S, are the corre-
332
perimental condnlons used. Phololysls products orher than OH can be estimated to lead to errors In the measured rate constant of <5- IO% 191. The rate constant k given In table I and plotted qpnst total pressure in fig. 2 shows that reachon (I) is in the fall-off regmn beIow 200 Torr both at 297 and 429 K. This observation mdlcates that rhe reaction of
OH + C,H2 f HOC,H;,
HOC,H;
+ M -+ HOC,H,
+ M.
adduct,
Volume 93, number 4
Ttlblc
Rate
CHEMICAL
PHYSICS LEnERS
I
constantsR(+) for lfw rcxl~on orOH rddrCJk wth CzH2. The mdrcatcd error hmltsarc 111ccslmratcd overall error IIIIIIIS which mcludc the Icasl~u.rcs standard dcwrrmn (2-X%) as ucil as the esttmatcd accuracy limtts of 0111cr psr.mwtcn suclr
a+ prcssurc
IO Dsccmbcr 1982
and calculated Is ketcnc
heats of formatson
lhen estimates
The UI~II~I~~Cproducts
acctylcnc arc uwcrlairt, Prcssurc (Toir)
A-x 10” (cm” molecule-’ 5-l)
(IO
297
25 6 50 7 99 8 707.9 JO? 1
HO f C,H, I_ the
04~
to other
stud~cs of Perry et al. [9] and Michael
hlcrature
val-
and the
ct al [lO\,was
a
pressure dcpcndcnce observed in the remIt
iO90
hlrchael et 31 .I slightly
IIIglIer value fork
fddr
study or 31 thy’ l~gh-
repm was
514
5 07 2 0.5 1
in tk present nlcasurenlet~ts of tltc pressure dcprndtncc of thfs rcactlon at 429 K such a drain3tiL shffl m the hlgfkprcssure hmit was not observed In facf, II appears that the varfatlon m the pressure dcpcndcncc of rlus rcacrlon wrth ternpemturc is sir&r to the fc3cfion 0fOH Wfh
s
6 85 5 0 70
201 3
806+089
403 0
7.89i
to exclude
being present,
I IO
the possibday
of
(2) to zero pressure
lends
to
dercrmincd by M~chacl et al. [IO]. Also, the nalurc of the prcssurc dependence obscrvcd here mdtcntcs kat rcactlon (2) may 197 and 129 K arc below ~bc rnterccpt
nle~atlIet1~~
reaction,
and IIIC
dcpctldcot.
ethylale [I_‘].
I c.
+ H.
of the data
hmrr was found,
found to be hlgltly tcsi~~rature
mdlcatc that these channels are mmor al atmospherrc pressures. In particular. the low.presstrrc vntues at both
not be a simple
value IS Lomparcd
may
The prcsclil
pressure
--* C,H,O _..
e\trapolatlon
that a thrrd body
357~000
WI 11c it is difficult
_hannels
36 kcal, Indicates
cvcn at Hugh tcmpcraturcs
ues In table 2 Note that only rn &is study
5.67 z 0 57 661~066
691
[9,10],
bc involved h&pressure
0 31
488:
adduct
of the re~cttoi~ of OH with
but the stabthty of 111~HOC&
20 3 fOl
other
3.082
of
M~cltacl et al. [lOI for the hat of fortnatlon of frarw tton complex must bc made
and ~~~~tan~ c~n~tnzmtron~
Tcmpenturc
[ 101. If the product
sImIlar fo the calculatlon5
but rather
tts rate may be associated wtth an in~raInolccular arrangement with an appreciable energy barner
The actual tcmpcraturc dcpendcnce of rhc iqltpressure hnfit has niaJor r~~~pl~caIronsrcgxdlng the mlparlance of the terwolecular
renction 31 IuJlcr
Wm.
perrttures. For example, c~trJpolatIorI of the present data tn fig 3 to hrgfi tcnrpcr&urc >I 500 K. results in contribution Fran, this IcnnolCCular rowtioff, as compared to postulated altcmate I~WII~IUSI~~S 1131, SuCll JS
a signikxnt
that rcto
I ,3
hydrogen nagratIon. If the actual product IS the ~somcr HOC =CH. thw bnrrrer can bc esttmnted from known
Table 2 Compwcon of hiphaprcssurr room-lcmperxure X ulth irlcmlurc ~luss _---Total prescurc
10’3 XX
fTorr)
(art3 ,i~‘ll~cul~-~s-9
_-_--.-I (Ar or He)
unk.no\\ n
IO-20 (HC or H2/N20) 1.05-I f(k) ‘O-SOO(Hc) 200-400 (Ar) IN-600(Ar) ?03-J03(Ar)
IOh) 1.92 06
85 20+ 06 1.6.5+015 6 79 ?:0.70 7.76 f 0 73 6.75 ?I0.70
r31c ranslJnl
Teclmlqucaf
_Kcf
__-DI -LSR
IJI 151
FP-RA Dr-RA I‘P-RIr-P-RI-
161 I71
Dt--ESR
t-P-Rr
rp-Rr
198;
1101
nIlr\~orli
3) TOTALPRESSUREkvd rug. 2. Plols of bm~olccular rate conslanlsA w+nst tolid pres-
SW of argon drlucnl a 297 K, 0, and 429 I<. n-
DT-LSR, dtschargc l-lox wrrb ESR detection. DE‘-RA,dwch.trg~~flow WIIII rcson3n~ absorprton, TP-RA. fl.~sh pbotolysls-rcson.mcc absorpllon. TP-RI-, llasb photol)sw. rcsonancc fiuurcscunce b, rrl where PI IS slorcluomctry fxlor, ~lurh MS not rcporlcd.
333
CHEMICAL
Vohimc 9 3, number -I
PHYSICS
LETt-l-ERS
IO Drcrmbcr
cd tn Vandooren
10”.
1982
and vrm Tigpelen’s experimenr.
Work is under way to establtsh the rate of reaction (I)
at hlgbcr temperatures
mlportance
in
order
to further
assess the
of thts reaction at flame temperatures.
From tlte present work we conclude sure hmtt is not stgnificantly at Icast up to 430K.
that the hgh-pres-
temperature
dependent
Also the absence of a stgnificant
zero-pressure lntcrcept IS clgam confirmed.
Acknowledgement 10”
I
0
4
2
5
1000,TK;
t-1:. 3 ~r~hco~~~\ plot 0f log h egalnFt 1000/r(~) data(o), and Jonss to
to1 our
PCTF)CI al (91 (0). M~chxl ct al.1 IO] (x). rcnlmorc [ ‘51 (o),Vandoorcn and vanT~f@cn II-I] (- - -).
and BFO\~I? ~1 aI 1141 (-.
---)
TIIIS work was supported
by the U S Department
of Energy. The asststance of Jon Meek,
The sohd lone is the best fit
and Jim van de Vreugde
IS
greatly
ttonal thanks go to Charles Otto, spMtral
Dean Wdliams,
appreciated LLNL,
Addt-
for the mass
annlysis.
contbtncd datd of Pcrr! ct aI UIIII thr prchcnt datJ
OH + C,H,
By combmmg prcscnt
M,,
+ Hz0 + C2H.
the data of Perry ct al. [9] to descrtbc
e- -WRT
KS. An empmcal
I.lSX
=
IO-12
c\p[(-377+400
TIIIS expresston
Arrltcntus
Further
extrapolation
work IS required
IS
the
Ltndentann
of the data IS wartoJustify
using this
stmplc cmpwcal fit m modeltng combJstlon systems as fix eUrapolatton to htgher temperatures may be SubJ’ct
to
considerable
II should be noted
could reproduce van Ttggclcn
the Arrhcnms
[14] obtained
Torr) O,/acetylene postulated
error.
that usmg this expression
one
plot of Vandooren
from a low-pressure
and
(40
flame wltere tlte reactton (7) was
to explam
the formatton
measured by molecular
of C2H20,
as
beam sdmpltng and mass spec-
trometry analysts Recogmzing the dtfficulty m dtstingutshing between ketene and the isomer HOCCH m a molecular
beam mass spectrometer.
tsts that reactton
0,
+ HOHCCH
(I)
334
e\-
followed by
--c HO2 + HOCCH
may be responstble
the possibility
for the budd-up
References 111 R ht. rrlstrom nod AA Wcstcnbcrg, rlamc structure (McCroa-Hdl, New Yorh, 1965). 12 I A G Gabdon and H G. Wolfhmd. l-lames. thar structure, radtatlon snd tcmpcraturc, 3rd Ed. (Chapman and Hall. London, 1970). 131 R. Alhmson. K.R Darvall, A C. Lloyd, Abl Wmc and
J.N. Pnls Jr., Advan, Photochcm. II (1979) 375 I-I] 1V.C Wilson and A A. Wcstcnbcrg, 1Ilh Symp. (1111.) on
cnl)/RT]
I
best fit IO all t!ie data USIIQ 3 modtficd
ranted
kinet-
expression
30/F, +
ifnn
tile
k = I 55
luglt-pressure
tl~c
where p IS rhc prcssurc tn Torr form.
(3)
fit of the present data over the enttrc
pressure range gives the followng
k(T.P)b,
wtl~
the clpresston
data one can obtain
X IO-”
= 6 kcal
(4) mass 42 as measur-
Combust!on.Thc Combustion Inshtutc (1967) p. 1143 I.5 I JI. Brcun snd CP. Class. Intern J. Chcm. K~net. 3 (1971) I45 161 1.W hl. Smith and R. Zcllncr. J Chcm. Sot roradny Trans.1169 (1973) 1617 17 I A V. pastrclna nnd R.W. Carr Jr., Intern J. Chcm. Kmct. 6 (1974) 587. [“I D D. Davis. S. I-lschcr, R. Schrl-r, R.-l-. Watson and W
Bolhqcr, J. Chcm. Phys. 63 (1975) 1707. 19) R.A Pcny, R Athmson and J N. PII& Jr,
J. Chcm.
Phys
67 (1977) 5577. IO] J V. MIchxI, D r. Nova. R P. Borkowskt, WA. Payne and LJ Sncl, J Chcm. Phys. 73 (1980) 6108 I1 I C Porter. 4th Symp (Int ) on Combustron.Thc tlon Institute (1953) p. 248.
Combus-
121 R Atkmson, RA. Perry and J.N. Pltts Jr., J.Chcm. Phys 66 (1977) 1197. 131 \V.G. Brow, R P. Porter, J.D. Vcrlm and A W. CM, 12th Symp. (lnr.) on Combustion,Thc Combusuon
(1969) p 1035 . _ Inslttule _ . 1141 J. vandooren dttd P.J. vanTtg$len, 16th Symp. (Int.) on Combustlon,Thc Combustion lnstitutc (1976) p. 1133. 115 I C P rcmmore and C.W. Jones, J. Chcm. Phys. 41 (1964) 1887.