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Investigation of the interaction between molecules at medium distances
Chemical Physics 8 (1975) 192-200 Q North-Holland Publish@ Company
lNVESTIGATlON 1. SCF LCAO
OF THE INTERACTlON
h10 superuwlecule,
for two inters&q
BETWEEN MOLECULES AT MEDIUhf DkXN’JCES
perturbational
and mutually consistent chh~~fls
HF and CHzO molecules
I. Introduction T)I~ calcu)~tjon
of jntrractjorl
energies
brtrseen
molecuks
is ofgcner;ll
intcrcst.
NOst
calculations
performed distances 1 I 1. Thw jnvest@tlans have shown that at large intermolecular distances inttxsction energy csprcssions based on pert\& bational cspansions are sufficient to obtain 3 reasonable qproxtmation. whereas at small distance betwscn tk interacting molecules (I/< 2.5 AI the two molecules have to be treated a~ one common supermolecule [ 11. CInd\e other hand problems of real interest for the orsanic chemist or molecular biologist are interacttons of organic: mola cults at medium (3-4 A) distances. For tlw interaction oforynic molecules at medium distances until now only perturbsfional calculations have been performed using 3s unperturbed one-electron functions the MOs of (he single molecllks obtajncd fronl difkrcnl semiempiricd calculations [ 2) _(mw prrpers cited in II] give also t)~e usscl P.Yprrssions of Ihr different perrurharic& terms [4] *.) On the other hand. Lischka 131 performjng ab initio ~+alcu. lations with a large basis XI and taking Into sczoun~ a considaablc pxt of the correlation hs foufjd for t\,~ interacting He .*. HF. He ... H-&I H-, ... HF and Hz ... GO systems at intermolecular distances of 3-4 9, that the pcrtutbation inrerxtion ener$x calculared wvith the Ad of the wrrect perturbational expressicms including second order yield only about SO per cent of the inrermion energies provided by the supermolecule approach. 7% iw ‘WnlS to be not WfOUn&d that by interactions of organic molecules the error may became even larger at till’ s3rw disranccs. jn a I~igl~er
approsimaIion
refer,
howtwr.
to small mokcuks
at largc.or small intclrmohxu~ar
TO investigate this rathtzr inrricarr! problem WCstarted an investigation of the interactions between mokculc5 3t medium distances. AS CI first sfep we iwe taken two interacting I+F and Cl-l,0 molecules, respectively. Tfw inrzraction energies have be?n computed in three different uays: f 1) ive ~NC: takn
the two
interacting molecules as common superrnolecule
and an &
initio
SCF LCAI) ?I0
f! Ozro. J. LadiklJrzreracrrorz
calculation (2) The
bcrwwrz nzolccrrles az rrzcdrrznzdzsrazzccr
for the supermolecule and the constituent
has been performed
193
molecules.
inrernction energies hirve been compured takirlg Into xcounl
perturbational
the clectrosta~ic (in LIIC mOnopOle approximation), the polarization. the exchange and the charge transl’er wms [-I] siarting from (11~ah inilio SCF LCAO hlOs of the unperturbed single molecules. (3) A further model (see below) has been clpplred which takes into account auwmafica11y the rnulual pokwztion of the interacting molecules and so provides better starting wave funckns for the cddxiorr of the rctruining terms in the perturbational scheme. In the present starting stage of Ihe invcsligation WCh~vc noI included the dispersion rcrm in ~ltc inlerrrction energies because [he ab initio supcrmoksuk calculations have not [aken into account the corrclarion. The proposed model could. however, be modified IO include correlation and rhen if has 10 bc f&n into account also in Ihr two other methods. This will be discusssd in a subsequent paper. The ;I(
aim
of these
investigations
is CO work
results 2nd ~‘3” be mow easily hnndlcd
IO llle supcrrnolcculc the heavy have ab
been the
For
atoms
wd
contracted
orbilnl
For rhc crestmcnc
7/3
to 4,
I,
+ 4 and 7/j
2 s functions
1. I s funcrions
and conlracrlon
and 2,
brt\rccn
approtich,
Iargcr
but gives
mol~.ul~
nrorc KCW,~~C
cxprrssmns.
f 7 gausslan
for the hydrogen
I p functions
cocfiicicnrs
oiinrcrxtions
~IKIII tlw supermolcculo
thorn the pcrcurbarional
cslculstions 3, respectively
esponcnts
inirio calcuhions
out ;I model
distance whicll is Its: evpwsive
medwm mrermolecular
lobe
basis (7s
;lloms)
for the lwauy
rhc vrrlues given
and 3 pX. pY 3~d
p_ lunctions
havs been used. The primirive atoms
by tiuL[naga
and to 3. 151 have
IIWL’ been CSL’CU!C~oft 311 IBM 360/91 L’OII)~UIP~using rhc program
written
for
funclions
1 6 functions
for J-1.
been upplicd. by Meyer
TIIC and
Pulay [61. For
3 HF
molecule
have been takn
the bond
d P u= I. 13 ,a, o = I 16.5’) &&les energy
was taken
oTO.92
S 113s been
= $CH,O
the ald of Ihe 7/J
_ +H20 f 4 basis.
in li_c.
D = 0.48 A.
I. The goornctry of a single CH20 molcculc (dc-0 of the supcrrnoleculc,
i.e., niaxirniLing
11ilZ
inwraction
,
The two CH,O molecules
Fig. 1. ‘The relzGve position of rhc tRo nOer~ctrnc HF molecules; R = 3.704,
uSed (71.
lvhcreas the IWO intsracfing HF molecules = I .?I & from Takagi and Oka (81, The relative geomelry of IIVO interacting CH,O _ shun
WIS obtained by ntrntmrzing the 1~31 crwrg of the two CHzO molrculcs, dctkd as &.A’.
with
distance
in [he rclarivt’ position
(1) wrc’
rakw
in parallel
phnh
in 311 ~rr~ngcf~iei~l
35
FIN. 2. TIC ~CI~IIV~powion ai IIICtno mrcrdmg CH,O molcculcs. ,\losr %!ble conformalion: K = 3.?OA. D = -0.30A,13=0’.
shown in fig. 2. Varping the interplane distance R, the distance D idched we
Ca.11 Set
rrom
fig.
j,
jar
the
srsblc configurntion
most
in fig. 2) and the angle 13one gets, 3s .A. D = -0.30 3 ;~nclfl= 0’.
of 111~IH’O molecules R = 3.X
(The latter angle is defined 3s the roution
angle of one of the molecules around the axis perpendicular
planes of t[lc nlo\ecules ;rnd going
one
till:
in(crac(ion
pcrlbrm
th?
energ
I7
iS -3.
calculations
with
~11subsequent calculstions
thruu&
kCai/n~ole.
all
the
rhrce
of
7Iux@
the
carbon,
IO ckCk
rcspectivd)’ ti7~’ proposed
OXv!$n
mod4
methods for the whole inreraclion
atoms.)
it would It~c
curve. 3s first
resprlctivrly
IO 1112
COIlfi$mltiOn
been better 10
step wr: hsve cx~ured
by this peometq’.
To investigate the dependence of the total energy on the basis set besides the 713 SCTL(9s
thij
In
13 s and 5 respectiwly
the hydrogen atoms) was applied
ior
\l\e
7 pA, pY and p_ functions single CH$I
also
;I
9/5 and ;1 IX/7 basis
for the heavy 31oms and 1 s functions
molecule. The primitive
functions
ior
have been contrscrc~
IO
I. I, 1 respecrivzly 3, J, 3, 2 s functions nod 4, I respectively 4.3 p functions for rhe hcnv atoms and IO 3, 1 s functions for H. The corresponding computer times were 0.5, \ .5 Jnd 3.8 minutes, rcspecriwly, If as SCF
6.
criteria I&+‘)
- pr,rl (‘0 G 10-lowae
used for all &mentSp,, t”) (o btained in the jtrh itcrnrion
The supermolccule calculation of the two CHZO molecules usuq the 7/3 basis set 1135 t&en IBhf 36Op
the pzrturbation
berwcm
rheory wilh overlap of Murrcll
Slater A05 belotlging IO difierrnt
rncrgy 3s 3 power series expsnsion of i?S2
13 minutes
on the
I computer.
Following intqyds
step) simultaneously.
ct al. [4] (which
can be applied until
the owrlap
molecules are smaller than 0.1) one gets the intrracrion
in the intermolecular
potential
0 and the overlap integral S. Up lo th? order
the interaction cnrr&g terms 3re
&P.T.
=E
CLSi. * E pot
+ 4~
Hew the ternIs EeLLI,, KpoL 3rd Ed,, laP wrurbation tributionsoforder
hvY.
+ &ch.rr
+ E dq.
are of zzroth
The contribution
+ kwh.poL
.
order in overlap and havs the same form, as in the zero owr-
of order US2 leads to the e.u&nge
U-7Sz may bt! subdivided into the charge transfer
energy, EeYcll. and the cnsrgy an-
energy Ech,_. and into the exchange’polariz)
195
tion and dispersion terms due to the exchange. Since the latter have neglected
this term
7Te electrostnfic
term is much smaller
thsn tllc o~ltcr ants
WC
[4j.
in our calculations.
term EccLa is in the monopole
approximation
(3) where 2:
is the nuclear
molecule
A and B. respectively.
of the
charge
92
ath nucleus
is the total
in molecule
clcctronic
A. IV,
and hfB stand far the number of nuclei in
charge of the ath 3tom
in molecule
A. whrch
we have
hfulliken’s population analysis 191 of lhc ab inilio SCF results and finally rwl is the distance Ir, bctwcen the 0th ato111in mokcule 11 and the /31l1 0112 in mokcule U. Ofcoursc. in more sophisticated future
taken
from
calculations hutions
use inslcad
unc could
of the two ntoleculcs
the first-order
density
The polarization
of the
applyirrg
monopolr:
either
appro~imaricm
multipole
expansions,
(3) a more refined
analysis
or use 3 three-dimensional
-
r,,l
of the clrsrgc dtstri. mesh to dcscribc
rn~~tnces.
term E,,o,. has the exprcssiun
I’_c)
(5)
II:
and rrk xc
ener@s
the numba
of molecule
for the Coulomb In zschnnge
of filled
hlOs in molcculc
A and B, respectively.
and cxch~n~~ term Ec,ch
A73
inrcgrals.
L$. $‘.
A and B. rcsprctively. I$
and $
E,‘, E,!‘, E! and E: arc one-electron
zrc the corresponding
hlOs and .I,‘,. h’p,. etc.. stand
rrspectwly.
IUS tllc Form 1-I)
411’ terms
TheEclLu,= Ecll.t1.+ hrr.
can be drrivcd
from
lhc
cxprchons
given ifl 141 as
196
0)
(In eqs.(6)
and (7) I~IC convention
Iqk~i *) =(~,(1,~,(7)lr;~‘l~~(1)~~(7))
C~,~,l’ij
was used.)
one
compares perturbational interaction energlcs Finally the dispersion term Em, should not be included if wrirh those obtained in the supcrlnolecule approach in the Hxtree-Fock level. and thereiore we do not write down here its esplicit Expressing
espression
(given
terms of the AOs and LCAO
coefficients.
which have been used in the actual
Instead
or solving
p’“p;
of the free single molecules of the partner
To we
it is easy to derive
we do not write
down
the corresponding hew
these rather
cspressions lengthy
in
iormulae
equations
Z&B I I
one can modify
molecule.
form
spxz
calculations.
the Hartrec-Fock
P$=+$.
trntial
in ref. [IO] ).
all AlOs itt (1). (6) and (7) in al LCAO
(9) their
Fock operxors
This means if we introduce
F’ and FB making them dcpcndent on tlrl: ~3. again LCAO hlOs WL’ have to solve the matrix equa-
tions F”zP
I
=$&r\
I
I ’
FBzB
I
= &jBeR
I
where the elements of the matrices FA and FE. respectively. F$=r;;:, Hew
+(&VBI$).
(IO)
I ’
p;s = F$+@IrAI~;).
are now defined as Ill)
P. Otto, 1. Ladik/hrtcraction is
the
usual
Fock-matrix
element
with
electron
term crTs has to be calculated
solution
of the modified
4
pc = -3 c 1I.U
1.1,
Since
wlrh
n~olecrrles at nwdlum dnronccs
change that the charge-bond
order
157
matrix
the aid of the eigenvector-components
element
T,:, which
pz”,
of the two-
one obiains
from
the
problem,
&c
1=l
the only
bctwem
(C
I.”
A, B).
=
(13)
the potentials
e=(r) depend which
=Jfi
(C = A, B)
df’
on the charge distributions requires
mutually
YB, respectively,
pC(r’)
consistcnr
the simple
of the parrrrtp III tk
solutions.
monopolc
( I I) dcfinc a problem
cqs. (IO) wit11 clcmcnts
molecule.
present
we have used for the potentials
calculations
I’*
and
approsimarion
(15)
where HF
the total
problem
present
electronic
with
only
niuhipolr
the aid ofa
with
and +F
can ayin
population
ltle nrsr ~pprosnnarlons
with the aid ot’a pC(r’)
charges $$
the aid of hlullikcn’s
IO rhe potcntlals
espansion
large number
oi
be obtained
tinalysis.
from
It should
(14) which
rl~c charge distribtirions
the vector
be emphasized, be obtuincd
could
or SIIII bctrcr
of point chargss in a Ihrcc-dimensional
Z, * and Z,B of the modified
however,
rhnt eqs. (I 5) re-
in a belter
approxtmation
by approsimating
rhc functions
mesh and performing
the mtcgrs-
[ion (I 4) nunicrically. Returning IWO
to the calculations
molecules
relative position
consistent
(as it was the exe
solutions,
with
Ihe aid of rhe simple
in our calculations,
if we solve the SCF problem
iteration
step besides the newly
ab initio
program,
for
the HF
both
performed
A and B arc of the same type and they are from
calculated
&fv
basis set and SCF crireris moleculss
and the CHzO
for one of thz molecules
also rhc newly
as described
molecules,
(I 5), we can obscrvc
computed
?:I.
(The
into
For this procedure ?.I),
above (see section
rcspcctlvcly.
substituting
solution
15-20
iterations
of the problem
that if the
in a svmmetric
of view of interactions
the mutually
1 and 2), we can obtain immediately
see figs.
(IO)
cspressions
the point
F”
in each
using the same were needed of the free singe
molecules required rhc same numbers of irerations.) Having rlie total
obtained
the murually
consistent
solutions
of eqs. (I 0) with (I I),
(I 2) and ( 15) w hv~ IO compute
energies
(C = A, B) Taking pzV
the difference
of the original
of the total unmodified
energies EC and EC (calculated
problem)
and adding
with
(16)
the charge-bond-order
to it (3). we c3n write
for the imenction
matrix
clcmcnrs
enera
(17)
$ Of course this advnntngc CM be used also III the ca>cii WC apply for 111spotentials SKBIIS than (15).
1“(C
= A. 8) ntorc complicated chprcr
bcrwccrr nroledes
I? Otto. 1. Ladikjllrtcractron
198
electronic
where the Fjt, etc., are again the total Eq. (17) gives in addition
charges obtained
at medim
from
dimma
the mutudlY
Consistent
Solutions~S,
polarization contribution also- Thus we do not have to calculate the complicated expression (6) for this Intter quantity, which the proposed new method gives in a simpler (and more accurate) (kxch.~
&?CF
= ‘%I, is defined
been taken
into
+ ‘&h. by cq.
account.
JJSO the murua]
The
term the
in this way wz also get better
Further
in eq.(z).
where E,, 10 fleai
way.
IT*.)
-%h.tr:
to the electrostatic
IIUS
nl:e can write
+ ‘%h.tr. + %‘hirp. +
‘%,ch.poL
(17). In our calculations,
corr&tion
wave functiOnS
for
remaining scheme
the
energy in the proposed
terms
(19)
’
described
here. in (19) OdY Eint., Eekch. and &h.lr. have of the idea of the mutually consistent field
2nd the ehtznsion
of .I?+,,
~dcuh!ion
starting
for the interaction
of the electrons
in interactirlg
molecules
will be dtscussed in 3 subsequent
paper.
3. Results In table
I we give the tot31 energies of CH,O
(in kcal/moles)
+ -1 his
set (and in rhr
case of HF also wirh 3 7/3 + 2 basis set). Finally
lated with
a 7/j
individual
terms of LL!T~.~. and LU?~~~’ .o gel 3 better
Table I Tile lolal enerpc, ofCHIO
obminsd
energies basis sets. Table 7 gives the interaction in the relative position given above, calcll. resp cctivcly,
using different
of the two HF and twu CHZO molecules,
with dtilcrcnr
bzsls scls
insighht into
in table 3 WC give 111,~
the problem.
T’abk 2 TIIC lntcrxtwn
cncrgics (in kcd/molc)
oi t\\o Hl’~nd
~\to
CH,O molcculcs
(in alomic unirs)
_-----I___ Basis set
Compufcr
Totd
cncrg
Sglem
Llasis set
time (s) 7/3 + 4 3) 915 + 4 13/7+4 -_____-
64. ____
-30 90
-I 13.68889 -I 13.76855
228
- I 13.82730
--
d 7 E and 3 pSu.p! and pz iuncuons lor the hcdvy amnlr. and 4 s functions ior tltc hydrog,x aloms
&.hl. (1)) ___--
tip.‘.
&ICF
bi
_-____
ZHF
713 f 2
-2.44
-1.93
‘HI:
713 + 4
-2.57
7/3 + 4 _____.
-3.17
- 1.49 - 4.02
2x,0 __
a)
- I.91 -1.47 --3.86
3) The liujt four terms of rq. (3) with the .q3prok~m~tc e\. pression (3) for Ecl.st.b) Tltc lirst three terms of cq. (19) wh
tltc appro~m3rti
ehprcssion (I 7).
T1 In (I 7) I\< could UW. of course. ho
prorimst?d
better (SW cq. (14)j.
a barer approlimstion
than ths monopole one if the potrntuls
In tfut casscWC would obtain instcJd of (I 7)
I rC (C = A. BJ !\ew .ip-
199
Table 3 The different --
calculated constituents
of &‘*T.
and ,&‘CF
(in kcal/mole) _.
GP.T. System
Basis
;\EhKF
E cl.w3)
E pol. b,
931
Ec,ch.C)
%~t,.~)
@A
- EA)
%.s,.
+ Epot.“)
~e,ctI.‘~
‘%,.rr.@
-1.96 -1.46
0.00 0.00
0.00 -0.0’
-3.56
0.09
-0.68 __-___
_____-
ZHF ?HF ‘CH,O
713 + 2 713 + 4
-1.89 -1.43
0.0-l -0.04
0.00 0.00
7/3 + 4
-3.17
0.00 -0.02
-0.25
010
-0.70
3) Cabulatcd b) Calculated c, Calculated d) Calculacd
from rq. (3). from cq. (4). from cq. (6).
g) CalculJtcd
from eq. (7) with 11x mutually
to.05 +0.03 +0.19 -_____
irom q(7). c) The fifth term (the double sum) of cq. (I 7). 11 Calculakd from q. (6) uith IIIC mutually conslrtcnt solutions. conslstent solutions.
4. Discussion
hokill:: 31 txble 1 we c3n 2 3.S eV which is nbout t&k
same basis set has bwn
thorough
the atomization larger [ion
calculation
Judgrmcnt energy
well. Looking between
interaction
the intcrtiction
encrg
bctwccn
only
111~’quality
rnthcr
bxis
Further,
Fo&
linlt[
was to corn--Ï
calculations.
with
of 3 CH,O
molecuk
litc
one has 10
investigation
cspensivc
(SW
c~;actly
To
obtain
the aid of each one
the exact value. This we have not done, because we wanted
with
the perturbetional
and
tllc
MCF
smaller values. than the supermolecule one should
Ire not without
the intramolecular
IO
the basis set is much
with
observe
error.
enera
schemes give for the iotcrar-
results which
thet in IIIC case of the smaller
the somewhat
Sarnely
sybsystcm
cncrgy.
31 least for two interacting
each
7/3 + 3 basis SCI the
larger 713 + 4 basis showing thet using a limited
the basis functions
of the other
agree with
and the charge trans-
tllatin this case both the exchange
than with
gets too large an interaction
the ealculotions
mo]cculcs
if in a]] calcul~[ions
of IIIC basis sets used one had to calculate
into table 3 WC cm SW further
SCI one usually
to repeat
two CH20
expect)
au
encrgics.
HF molccul~s
calculations
is (3s one would
] j/7 basis set is -0.1-l
and
close 10 [llc Har[rsc-
the ahovc mentioned
11121tlte chsngc of the to131 cncrgy
small.
found
schemes can bz compared
the three schemes is better
partly used to improve future
about
encrgics
molecule
the 7/j
energics are basis set dependent. II should be pointed out. however.
the supermolecule limited
forntaldehydr:
with LI large basis set. Since IIKZ aim of the present
interaction
of the polar
fer terms are vnnishingly agreement
of a single
rhc inreractmn
cncr~
to tables ? and 3 we can SW that troth
energies
other very
than
and to compare
than the c~lculatcd
Turning
lnryer
interxtion
sclwmes. we have not pcrformcd
in table 1 only.
demonstrate
enorgy
the total
used and to obtan
3. supermolccule
pare the different ;I more
20 times
different
2). Ikrefwe
perform
SCClh3t
OII Ihe b3sts. The difference in total energy between
rather dcpendrnt
that also the basis SC~ SO
on one of the siibsystems
are
and vice versa. In this tray ustng a
To ovrtrcomr this difficulty
wc intend in tltc
HF molecules with a basis set large ettouglt to provide
total energies near the Hartree-Fock limit. In the ease of two interacting CH,O nml~culcs hlCF
model give larger
worthwhile
to point
out
interaction that
in both
cases the crude
WC Kind that both tllc perturbational sclicmc and the proposed than the supermolecul c v~~luctlw hlCF result bring closer to it. It I$
the charg c transficr
and in the MCF schemes. From aI] these we c3n conelude using
energies
that
tttonop&
term
is rarhzr
large (-
-0.7
kcnl/mola)
tlte proposed model works sontewl~at bcttcr tktn apptosilxttion.
In subscqucnt
publications
both
tk
in rhc perturbational
perturbational
one
WCshall report the resultsofa
200
P. Urro. 1. Ladik/lrilrracrrotl
berwen
n~olenrles
ar medrum
disrances
more sophisticated version of the method using a three-dimensional mesh of Point ChWFS instead of the monopolc approximation, and Slater’s local exchange potential of the partner molecules built into the one-electron part of the Fock operator of the molecule under consideration. If in this way the exchange term can be approximated well enough and the charge rransfer cuntribution is small. one can expect that in this way one can get rather near to the Supern&c&
result Ms.“‘.
ob:ained with a renscnably large basis set to avoid Ihe “superposition
The model would have the advantage [o avoid the espensivc c&ulation
occur both in the supermolecule and perturbational bational treatment,
3pproxh)
especially if the number of interacting
and
of the illtL?rrTlOkCUhr
could be still more mUrate, is larger than two-
integrrrh
error’..
(w!lich
than the pertur-
moloculcs
Acknowlegement We should like to express our gratitude to Professor G.L. Hofacker for this continuous interest and support whicll made It possible to perform tllis investigation. WC are further indebted to Professor W. hleycr for his help in putting his programs at our disposal and for useful discussions.
The financial support Finally.
of the DeuMle
Forschungsgemeinschafr
we should like lo thank the Rechenzcntrum
should gratefully be acknowledged. fur Plasmaphysik for giving us
des hlas-Planck-lnstituts
compurer time on their IDhI 360/91 computer.
References
1I ) See for mslancc. J 0. Ihrschicldrr. C.F Curtis And R 6. Bird, XIOIKULII lh~~ry ot &$IxS and llqulds (\vllcY. NW York. 1954) p. 9 16. H. hlargcnauand N.R. K;cstner. ThuorY 01 rnwrmolsculx ror~cs (Pcrgmon Prr>s. New York) p. 14s.
12) Seefor 3. P.
insldnce:
Clawnrt.
11.
Pukmln snd J. Caikr,
J. Theor.
Eliot. (19661 419.
b. R Ran and M. Poll~k. J. Chem. PhYc. 47 I19671 2039: c. R. Rein. P. ClJvcrk and PolL~k, Inrcrn. J. Quanl. Chcm. 2 d. P. Cllveric and R. Rein. tntsrn. J. Quanf. Chrm. 3 (1969) c. R. Rein. Advan. QuJnl. Chcm. 7 (1973) 131 tl. Lischka.Chsm. Phys. 10973) ISrl.
537;
335
[-II J.N. Xlurrcli. M. RJndlc and O.R. \Vilh.mis Proc. Rob. (51 S. f1uzin.g. J. Cbem. Phys. 42 (1963) 1293. 161 W. Meyer and P. Pulpy. unpublished. 171 G. Herrberg. Di_nornw molecules (Van Natrand,
181 K. T3gaki
f 1968) 129;
Sot. A354 (1965)
Princeton.
1950) p. 356.
3nd T. O~J. J. Phys. Sac. J3p3n 18 ( 1963) 1174.
191 R.S. hlullikrn.
J. Chem. Phys. 23 (1955)
I tOI h.F. Hau& and J.O. W~chfcldcr.
1833.
J. Chrm. Phys. 23 (I 955) I 778.
566.
lNVESTIGATlON 1. SCF LCAO
OF THE INTERACTlON
h10 superuwlecule,
for two inters&q
BETWEEN MOLECULES AT MEDIUhf DkXN’JCES
perturbational
and mutually consistent chh~~fls
HF and CHzO molecules
I. Introduction T)I~ calcu)~tjon
of jntrractjorl
energies
brtrseen
molecuks
is ofgcner;ll
intcrcst.
NOst
calculations
performed distances 1 I 1. Thw jnvest@tlans have shown that at large intermolecular distances inttxsction energy csprcssions based on pert\& bational cspansions are sufficient to obtain 3 reasonable qproxtmation. whereas at small distance betwscn tk interacting molecules (I/< 2.5 AI the two molecules have to be treated a~ one common supermolecule [ 11. CInd\e other hand problems of real interest for the orsanic chemist or molecular biologist are interacttons of organic: mola cults at medium (3-4 A) distances. For tlw interaction oforynic molecules at medium distances until now only perturbsfional calculations have been performed using 3s unperturbed one-electron functions the MOs of (he single molecllks obtajncd fronl difkrcnl semiempiricd calculations [ 2) _(mw prrpers cited in II] give also t)~e usscl P.Yprrssions of Ihr different perrurharic& terms [4] *.) On the other hand. Lischka 131 performjng ab initio ~+alcu. lations with a large basis XI and taking Into sczoun~ a considaablc pxt of the correlation hs foufjd for t\,~ interacting He .*. HF. He ... H-&I H-, ... HF and Hz ... GO systems at intermolecular distances of 3-4 9, that the pcrtutbation inrerxtion ener$x calculared wvith the Ad of the wrrect perturbational expressicms including second order yield only about SO per cent of the inrermion energies provided by the supermolecule approach. 7% iw ‘WnlS to be not WfOUn&d that by interactions of organic molecules the error may became even larger at till’ s3rw disranccs. jn a I~igl~er
approsimaIion
refer,
howtwr.
to small mokcuks
at largc.or small intclrmohxu~ar
TO investigate this rathtzr inrricarr! problem WCstarted an investigation of the interactions between mokculc5 3t medium distances. AS CI first sfep we iwe taken two interacting I+F and Cl-l,0 molecules, respectively. Tfw inrzraction energies have be?n computed in three different uays: f 1) ive ~NC: takn
the two
interacting molecules as common superrnolecule
and an &
initio
SCF LCAI) ?I0
f! Ozro. J. LadiklJrzreracrrorz
calculation (2) The
bcrwwrz nzolccrrles az rrzcdrrznzdzsrazzccr
for the supermolecule and the constituent
has been performed
193
molecules.
inrernction energies hirve been compured takirlg Into xcounl
perturbational
the clectrosta~ic (in LIIC mOnopOle approximation), the polarization. the exchange and the charge transl’er wms [-I] siarting from (11~ah inilio SCF LCAO hlOs of the unperturbed single molecules. (3) A further model (see below) has been clpplred which takes into account auwmafica11y the rnulual pokwztion of the interacting molecules and so provides better starting wave funckns for the cddxiorr of the rctruining terms in the perturbational scheme. In the present starting stage of Ihe invcsligation WCh~vc noI included the dispersion rcrm in ~ltc inlerrrction energies because [he ab initio supcrmoksuk calculations have not [aken into account the corrclarion. The proposed model could. however, be modified IO include correlation and rhen if has 10 bc f&n into account also in Ihr two other methods. This will be discusssd in a subsequent paper. The ;I(
aim
of these
investigations
is CO work
results 2nd ~‘3” be mow easily hnndlcd
IO llle supcrrnolcculc the heavy have ab
been the
For
atoms
wd
contracted
orbilnl
For rhc crestmcnc
7/3
to 4,
I,
+ 4 and 7/j
2 s functions
1. I s funcrions
and conlracrlon
and 2,
brt\rccn
approtich,
Iargcr
but gives
mol~.ul~
nrorc KCW,~~C
cxprrssmns.
f 7 gausslan
for the hydrogen
I p functions
cocfiicicnrs
oiinrcrxtions
~IKIII tlw supermolcculo
thorn the pcrcurbarional
cslculstions 3, respectively
esponcnts
inirio calcuhions
out ;I model
distance whicll is Its: evpwsive
medwm mrermolecular
lobe
basis (7s
;lloms)
for the lwauy
rhc vrrlues given
and 3 pX. pY 3~d
p_ lunctions
havs been used. The primirive atoms
by tiuL[naga
and to 3. 151 have
IIWL’ been CSL’CU!C~oft 311 IBM 360/91 L’OII)~UIP~using rhc program
written
for
funclions
1 6 functions
for J-1.
been upplicd. by Meyer
TIIC and
Pulay [61. For
3 HF
molecule
have been takn
the bond
d P u= I. 13 ,a, o = I 16.5’) &&les energy
was taken
oTO.92
S 113s been
= $CH,O
the ald of Ihe 7/J
_ +H20 f 4 basis.
in li_c.
D = 0.48 A.
I. The goornctry of a single CH20 molcculc (dc-0 of the supcrrnoleculc,
i.e., niaxirniLing
11ilZ
inwraction
,
The two CH,O molecules
Fig. 1. ‘The relzGve position of rhc tRo nOer~ctrnc HF molecules; R = 3.704,
uSed (71.
lvhcreas the IWO intsracfing HF molecules = I .?I & from Takagi and Oka (81, The relative geomelry of IIVO interacting CH,O _ shun
WIS obtained by ntrntmrzing the 1~31 crwrg of the two CHzO molrculcs, dctkd as &.A’.
with
distance
in [he rclarivt’ position
(1) wrc’
rakw
in parallel
phnh
in 311 ~rr~ngcf~iei~l
35
FIN. 2. TIC ~CI~IIV~powion ai IIICtno mrcrdmg CH,O molcculcs. ,\losr %!ble conformalion: K = 3.?OA. D = -0.30A,13=0’.
shown in fig. 2. Varping the interplane distance R, the distance D idched we
Ca.11 Set
rrom
fig.
j,
jar
the
srsblc configurntion
most
in fig. 2) and the angle 13one gets, 3s .A. D = -0.30 3 ;~nclfl= 0’.
of 111~IH’O molecules R = 3.X
(The latter angle is defined 3s the roution
angle of one of the molecules around the axis perpendicular
planes of t[lc nlo\ecules ;rnd going
one
till:
in(crac(ion
pcrlbrm
th?
energ
I7
iS -3.
calculations
with
~11subsequent calculstions
thruu&
kCai/n~ole.
all
the
rhrce
of
7Iux@
the
carbon,
IO ckCk
rcspectivd)’ ti7~’ proposed
OXv!$n
mod4
methods for the whole inreraclion
atoms.)
it would It~c
curve. 3s first
resprlctivrly
IO 1112
COIlfi$mltiOn
been better 10
step wr: hsve cx~ured
by this peometq’.
To investigate the dependence of the total energy on the basis set besides the 713 SCTL(9s
thij
In
13 s and 5 respectiwly
the hydrogen atoms) was applied
ior
\l\e
7 pA, pY and p_ functions single CH$I
also
;I
9/5 and ;1 IX/7 basis
for the heavy 31oms and 1 s functions
molecule. The primitive
functions
ior
have been contrscrc~
IO
I. I, 1 respecrivzly 3, J, 3, 2 s functions nod 4, I respectively 4.3 p functions for rhe hcnv atoms and IO 3, 1 s functions for H. The corresponding computer times were 0.5, \ .5 Jnd 3.8 minutes, rcspecriwly, If as SCF
6.
criteria I&+‘)
- pr,rl (‘0 G 10-lowae
used for all &mentSp,, t”) (o btained in the jtrh itcrnrion
The supermolccule calculation of the two CHZO molecules usuq the 7/3 basis set 1135 t&en IBhf 36Op
the pzrturbation
berwcm
rheory wilh overlap of Murrcll
Slater A05 belotlging IO difierrnt
rncrgy 3s 3 power series expsnsion of i?S2
13 minutes
on the
I computer.
Following intqyds
step) simultaneously.
ct al. [4] (which
can be applied until
the owrlap
molecules are smaller than 0.1) one gets the intrracrion
in the intermolecular
potential
0 and the overlap integral S. Up lo th? order
the interaction cnrr&g terms 3re
&P.T.
=E
CLSi. * E pot
+ 4~
Hew the ternIs EeLLI,, KpoL 3rd Ed,, laP wrurbation tributionsoforder
hvY.
+ &ch.rr
+ E dq.
are of zzroth
The contribution
+ kwh.poL
.
order in overlap and havs the same form, as in the zero owr-
of order US2 leads to the e.u&nge
U-7Sz may bt! subdivided into the charge transfer
energy, EeYcll. and the cnsrgy an-
energy Ech,_. and into the exchange’polariz)
195
tion and dispersion terms due to the exchange. Since the latter have neglected
this term
7Te electrostnfic
term is much smaller
thsn tllc o~ltcr ants
WC
[4j.
in our calculations.
term EccLa is in the monopole
approximation
(3) where 2:
is the nuclear
molecule
A and B. respectively.
of the
charge
92
ath nucleus
is the total
in molecule
clcctronic
A. IV,
and hfB stand far the number of nuclei in
charge of the ath 3tom
in molecule
A. whrch
we have
hfulliken’s population analysis 191 of lhc ab inilio SCF results and finally rwl is the distance Ir, bctwcen the 0th ato111in mokcule 11 and the /31l1 0112 in mokcule U. Ofcoursc. in more sophisticated future
taken
from
calculations hutions
use inslcad
unc could
of the two ntoleculcs
the first-order
density
The polarization
of the
applyirrg
monopolr:
either
appro~imaricm
multipole
expansions,
(3) a more refined
analysis
or use 3 three-dimensional
-
r,,l
of the clrsrgc dtstri. mesh to dcscribc
rn~~tnces.
term E,,o,. has the exprcssiun
I’_c)
(5)
II:
and rrk xc
ener@s
the numba
of molecule
for the Coulomb In zschnnge
of filled
hlOs in molcculc
A and B, respectively.
and cxch~n~~ term Ec,ch
A73
inrcgrals.
L$. $‘.
A and B. rcsprctively. I$
and $
E,‘, E,!‘, E! and E: arc one-electron
zrc the corresponding
hlOs and .I,‘,. h’p,. etc.. stand
rrspectwly.
IUS tllc Form 1-I)
411’ terms
TheEclLu,= Ecll.t1.+ hrr.
can be drrivcd
from
lhc
cxprchons
given ifl 141 as
196
0)
(In eqs.(6)
and (7) I~IC convention
Iqk~i *) =(~,(1,~,(7)lr;~‘l~~(1)~~(7))
C~,~,l’ij
was used.)
one
compares perturbational interaction energlcs Finally the dispersion term Em, should not be included if wrirh those obtained in the supcrlnolecule approach in the Hxtree-Fock level. and thereiore we do not write down here its esplicit Expressing
espression
(given
terms of the AOs and LCAO
coefficients.
which have been used in the actual
Instead
or solving
p’“p;
of the free single molecules of the partner
To we
it is easy to derive
we do not write
down
the corresponding hew
these rather
cspressions lengthy
in
iormulae
equations
Z&B I I
one can modify
molecule.
form
spxz
calculations.
the Hartrec-Fock
P$=+$.
trntial
in ref. [IO] ).
all AlOs itt (1). (6) and (7) in al LCAO
(9) their
Fock operxors
This means if we introduce
F’ and FB making them dcpcndent on tlrl: ~3. again LCAO hlOs WL’ have to solve the matrix equa-
tions F”zP
I
=$&r\
I
I ’
FBzB
I
= &jBeR
I
where the elements of the matrices FA and FE. respectively. F$=r;;:, Hew
+(&VBI$).
(IO)
I ’
p;s = F$+@IrAI~;).
are now defined as Ill)
P. Otto, 1. Ladik/hrtcraction is
the
usual
Fock-matrix
element
with
electron
term crTs has to be calculated
solution
of the modified
4
pc = -3 c 1I.U
1.1,
Since
wlrh
n~olecrrles at nwdlum dnronccs
change that the charge-bond
order
157
matrix
the aid of the eigenvector-components
element
T,:, which
pz”,
of the two-
one obiains
from
the
problem,
&c
1=l
the only
bctwem
(C
I.”
A, B).
=
(13)
the potentials
e=(r) depend which
=Jfi
(C = A, B)
df’
on the charge distributions requires
mutually
YB, respectively,
pC(r’)
consistcnr
the simple
of the parrrrtp III tk
solutions.
monopolc
( I I) dcfinc a problem
cqs. (IO) wit11 clcmcnts
molecule.
present
we have used for the potentials
calculations
I’*
and
approsimarion
(15)
where HF
the total
problem
present
electronic
with
only
niuhipolr
the aid ofa
with
and +F
can ayin
population
ltle nrsr ~pprosnnarlons
with the aid ot’a pC(r’)
charges $$
the aid of hlullikcn’s
IO rhe potcntlals
espansion
large number
oi
be obtained
tinalysis.
from
It should
(14) which
rl~c charge distribtirions
the vector
be emphasized, be obtuincd
could
or SIIII bctrcr
of point chargss in a Ihrcc-dimensional
Z, * and Z,B of the modified
however,
rhnt eqs. (I 5) re-
in a belter
approxtmation
by approsimating
rhc functions
mesh and performing
the mtcgrs-
[ion (I 4) nunicrically. Returning IWO
to the calculations
molecules
relative position
consistent
(as it was the exe
solutions,
with
Ihe aid of rhe simple
in our calculations,
if we solve the SCF problem
iteration
step besides the newly
ab initio
program,
for
the HF
both
performed
A and B arc of the same type and they are from
calculated
&fv
basis set and SCF crireris moleculss
and the CHzO
for one of thz molecules
also rhc newly
as described
molecules,
(I 5), we can obscrvc
computed
?:I.
(The
into
For this procedure ?.I),
above (see section
rcspcctlvcly.
substituting
solution
15-20
iterations
of the problem
that if the
in a svmmetric
of view of interactions
the mutually
1 and 2), we can obtain immediately
see figs.
(IO)
cspressions
the point
F”
in each
using the same were needed of the free singe
molecules required rhc same numbers of irerations.) Having rlie total
obtained
the murually
consistent
solutions
of eqs. (I 0) with (I I),
(I 2) and ( 15) w hv~ IO compute
energies
(C = A, B) Taking pzV
the difference
of the original
of the total unmodified
energies EC and EC (calculated
problem)
and adding
with
(16)
the charge-bond-order
to it (3). we c3n write
for the imenction
matrix
clcmcnrs
enera
(17)
$ Of course this advnntngc CM be used also III the ca>cii WC apply for 111spotentials SKBIIS than (15).
1“(C
= A. 8) ntorc complicated chprcr
bcrwccrr nroledes
I? Otto. 1. Ladikjllrtcractron
198
electronic
where the Fjt, etc., are again the total Eq. (17) gives in addition
charges obtained
at medim
from
dimma
the mutudlY
Consistent
Solutions~S,
polarization contribution also- Thus we do not have to calculate the complicated expression (6) for this Intter quantity, which the proposed new method gives in a simpler (and more accurate) (kxch.~
&?CF
= ‘%I, is defined
been taken
into
+ ‘&h. by cq.
account.
JJSO the murua]
The
term the
in this way wz also get better
Further
in eq.(z).
where E,, 10 fleai
way.
IT*.)
-%h.tr:
to the electrostatic
IIUS
nl:e can write
+ ‘%h.tr. + %‘hirp. +
‘%,ch.poL
(17). In our calculations,
corr&tion
wave functiOnS
for
remaining scheme
the
energy in the proposed
terms
(19)
’
described
here. in (19) OdY Eint., Eekch. and &h.lr. have of the idea of the mutually consistent field
2nd the ehtznsion
of .I?+,,
~dcuh!ion
starting
for the interaction
of the electrons
in interactirlg
molecules
will be dtscussed in 3 subsequent
paper.
3. Results In table
I we give the tot31 energies of CH,O
(in kcal/moles)
+ -1 his
set (and in rhr
case of HF also wirh 3 7/3 + 2 basis set). Finally
lated with
a 7/j
individual
terms of LL!T~.~. and LU?~~~’ .o gel 3 better
Table I Tile lolal enerpc, ofCHIO
obminsd
energies basis sets. Table 7 gives the interaction in the relative position given above, calcll. resp cctivcly,
using different
of the two HF and twu CHZO molecules,
with dtilcrcnr
bzsls scls
insighht into
in table 3 WC give 111,~
the problem.
T’abk 2 TIIC lntcrxtwn
cncrgics (in kcd/molc)
oi t\\o Hl’~nd
~\to
CH,O molcculcs
(in alomic unirs)
_-----I___ Basis set
Compufcr
Totd
cncrg
Sglem
Llasis set
time (s) 7/3 + 4 3) 915 + 4 13/7+4 -_____-
64. ____
-30 90
-I 13.68889 -I 13.76855
228
- I 13.82730
--
d 7 E and 3 pSu.p! and pz iuncuons lor the hcdvy amnlr. and 4 s functions ior tltc hydrog,x aloms
&.hl. (1)) ___--
tip.‘.
&ICF
bi
_-____
ZHF
713 f 2
-2.44
-1.93
‘HI:
713 + 4
-2.57
7/3 + 4 _____.
-3.17
- 1.49 - 4.02
2x,0 __
a)
- I.91 -1.47 --3.86
3) The liujt four terms of rq. (3) with the .q3prok~m~tc e\. pression (3) for Ecl.st.b) Tltc lirst three terms of cq. (19) wh
tltc appro~m3rti
ehprcssion (I 7).
T1 In (I 7) I\< could UW. of course. ho
prorimst?d
better (SW cq. (14)j.
a barer approlimstion
than ths monopole one if the potrntuls
In tfut casscWC would obtain instcJd of (I 7)
I rC (C = A. BJ !\ew .ip-
199
Table 3 The different --
calculated constituents
of &‘*T.
and ,&‘CF
(in kcal/mole) _.
GP.T. System
Basis
;\EhKF
E cl.w3)
E pol. b,
931
Ec,ch.C)
%~t,.~)
@A
- EA)
%.s,.
+ Epot.“)
~e,ctI.‘~
‘%,.rr.@
-1.96 -1.46
0.00 0.00
0.00 -0.0’
-3.56
0.09
-0.68 __-___
_____-
ZHF ?HF ‘CH,O
713 + 2 713 + 4
-1.89 -1.43
0.0-l -0.04
0.00 0.00
7/3 + 4
-3.17
0.00 -0.02
-0.25
010
-0.70
3) Cabulatcd b) Calculated c, Calculated d) Calculacd
from rq. (3). from cq. (4). from cq. (6).
g) CalculJtcd
from eq. (7) with 11x mutually
to.05 +0.03 +0.19 -_____
irom q(7). c) The fifth term (the double sum) of cq. (I 7). 11 Calculakd from q. (6) uith IIIC mutually conslrtcnt solutions. conslstent solutions.
4. Discussion
hokill:: 31 txble 1 we c3n 2 3.S eV which is nbout t&k
same basis set has bwn
thorough
the atomization larger [ion
calculation
Judgrmcnt energy
well. Looking between
interaction
the intcrtiction
encrg
bctwccn
only
111~’quality
rnthcr
bxis
Further,
Fo&
linlt[
was to corn--Ï
calculations.
with
of 3 CH,O
molecuk
litc
one has 10
investigation
cspensivc
(SW
c~;actly
To
obtain
the aid of each one
the exact value. This we have not done, because we wanted
with
the perturbetional
and
tllc
MCF
smaller values. than the supermolecule one should
Ire not without
the intramolecular
IO
the basis set is much
with
observe
error.
enera
schemes give for the iotcrar-
results which
thet in IIIC case of the smaller
the somewhat
Sarnely
sybsystcm
cncrgy.
31 least for two interacting
each
7/3 + 3 basis SCI the
larger 713 + 4 basis showing thet using a limited
the basis functions
of the other
agree with
and the charge trans-
tllatin this case both the exchange
than with
gets too large an interaction
the ealculotions
mo]cculcs
if in a]] calcul~[ions
of IIIC basis sets used one had to calculate
into table 3 WC cm SW further
SCI one usually
to repeat
two CH20
expect)
au
encrgics.
HF molccul~s
calculations
is (3s one would
] j/7 basis set is -0.1-l
and
close 10 [llc Har[rsc-
the ahovc mentioned
11121tlte chsngc of the to131 cncrgy
small.
found
schemes can bz compared
the three schemes is better
partly used to improve future
about
encrgics
molecule
the 7/j
energics are basis set dependent. II should be pointed out. however.
the supermolecule limited
forntaldehydr:
with LI large basis set. Since IIKZ aim of the present
interaction
of the polar
fer terms are vnnishingly agreement
of a single
rhc inreractmn
cncr~
to tables ? and 3 we can SW that troth
energies
other very
than
and to compare
than the c~lculatcd
Turning
lnryer
interxtion
sclwmes. we have not pcrformcd
in table 1 only.
demonstrate
enorgy
the total
used and to obtan
3. supermolccule
pare the different ;I more
20 times
different
2). Ikrefwe
perform
SCClh3t
OII Ihe b3sts. The difference in total energy between
rather dcpendrnt
that also the basis SC~ SO
on one of the siibsystems
are
and vice versa. In this tray ustng a
To ovrtrcomr this difficulty
wc intend in tltc
HF molecules with a basis set large ettouglt to provide
total energies near the Hartree-Fock limit. In the ease of two interacting CH,O nml~culcs hlCF
model give larger
worthwhile
to point
out
interaction that
in both
cases the crude
WC Kind that both tllc perturbational sclicmc and the proposed than the supermolecul c v~~luctlw hlCF result bring closer to it. It I$
the charg c transficr
and in the MCF schemes. From aI] these we c3n conelude using
energies
that
tttonop&
term
is rarhzr
large (-
-0.7
kcnl/mola)
tlte proposed model works sontewl~at bcttcr tktn apptosilxttion.
In subscqucnt
publications
both
tk
in rhc perturbational
perturbational
one
WCshall report the resultsofa
200
P. Urro. 1. Ladik/lrilrracrrotl
berwen
n~olenrles
ar medrum
disrances
more sophisticated version of the method using a three-dimensional mesh of Point ChWFS instead of the monopolc approximation, and Slater’s local exchange potential of the partner molecules built into the one-electron part of the Fock operator of the molecule under consideration. If in this way the exchange term can be approximated well enough and the charge rransfer cuntribution is small. one can expect that in this way one can get rather near to the Supern&c&
result Ms.“‘.
ob:ained with a renscnably large basis set to avoid Ihe “superposition
The model would have the advantage [o avoid the espensivc c&ulation
occur both in the supermolecule and perturbational bational treatment,
3pproxh)
especially if the number of interacting
and
of the illtL?rrTlOkCUhr
could be still more mUrate, is larger than two-
integrrrh
error’..
(w!lich
than the pertur-
moloculcs
Acknowlegement We should like to express our gratitude to Professor G.L. Hofacker for this continuous interest and support whicll made It possible to perform tllis investigation. WC are further indebted to Professor W. hleycr for his help in putting his programs at our disposal and for useful discussions.
The financial support Finally.
of the DeuMle
Forschungsgemeinschafr
we should like lo thank the Rechenzcntrum
should gratefully be acknowledged. fur Plasmaphysik for giving us
des hlas-Planck-lnstituts
compurer time on their IDhI 360/91 computer.
References
1I ) See for mslancc. J 0. Ihrschicldrr. C.F Curtis And R 6. Bird, XIOIKULII lh~~ry ot &$IxS and llqulds (\vllcY. NW York. 1954) p. 9 16. H. hlargcnauand N.R. K;cstner. ThuorY 01 rnwrmolsculx ror~cs (Pcrgmon Prr>s. New York) p. 14s.
12) Seefor 3. P.
insldnce:
Clawnrt.
11.
Pukmln snd J. Caikr,
J. Theor.
Eliot. (19661 419.
b. R Ran and M. Poll~k. J. Chem. PhYc. 47 I19671 2039: c. R. Rein. P. ClJvcrk and PolL~k, Inrcrn. J. Quanl. Chcm. 2 d. P. Cllveric and R. Rein. tntsrn. J. Quanf. Chrm. 3 (1969) c. R. Rein. Advan. QuJnl. Chcm. 7 (1973) 131 tl. Lischka.Chsm. Phys. 10973) ISrl.
537;
335
[-II J.N. Xlurrcli. M. RJndlc and O.R. \Vilh.mis Proc. Rob. (51 S. f1uzin.g. J. Cbem. Phys. 42 (1963) 1293. 161 W. Meyer and P. Pulpy. unpublished. 171 G. Herrberg. Di_nornw molecules (Van Natrand,
181 K. T3gaki
f 1968) 129;
Sot. A354 (1965)
Princeton.
1950) p. 356.
3nd T. O~J. J. Phys. Sac. J3p3n 18 ( 1963) 1174.
191 R.S. hlullikrn.
J. Chem. Phys. 23 (1955)
I tOI h.F. Hau& and J.O. W~chfcldcr.
1833.
J. Chrm. Phys. 23 (I 955) I 778.
566.