- Email: [email protected]
Charge separation study in bisbenzene complexes of metals by theoretical analysis of infrared intensities
255
JournalofMolecularStructure,218 (1990)255-260 ElsevierSciencePublishersB.V.,Amsterdam-PPrintedinTheNetherlands
CHARGS
SEPARATION
STUDY
IN BISBENZENE
BY THEORETICAL
ANALYSIS
OF INFRARED
I.I.GREENWALD,
B.V.LOKSHIN
COMPLEXES
OF METALS
INTENSITIES
A.N.Nesmeyanov Institute of organoelement sciences, Vavilova Str.28, 117813 I%SCOW
compounds, (USSR)
Academy
of
SUMMARY Using the first approximation of the effective charges model from the experimental IR integrated intensities the effective charges on atoms in bisbenzene complexes of V, Cr and MO have been calculated. The charges on the metal atoms in the complexes studied are somehigher than in corresponding metallocenes and have the values about 0.5-0.9 electron charge units.
INTRODUCTION Considerably in molecules IR bands
intensities
effective
charges
systematic plexes ults
study
Cp2M
have
Therefore
model
(refs.l,2).
showed
have been made
that metallocenes
and calculations
compounds-
bisbenzene
the cyclopentadienyl
opinion, duse
complexes
are unstable
data
on stated
the picture
small
of charge
effective
distribution
atomic
class
Bz=q6-C6H6
make
The res-
chemical
pro-
charges.
of sandwich and M=V,Cr,
the majority
temperature.
compounds
a
com-
out a new seriebof
important
Bz2M, where
at room
three
(ref.2)
this model.
different
to carry
complexes
work
of
of the
in cyclopentadienyl
using
for a very
MO. Unlike
approximation
with
it interesting
charges
on the analysis
In our earlier
charges
and relatively
of effective
based
of first-order
of the effective
similar
ne compounds
to the study
by the method,
in terms
we considered
experiments
approach
(Cp=$-C5H5)
obtained
perties
correct
is represented
of bisbenze-
Nevertheless, it possible
in bisbenzene
in our
to repro-
complexes.
EXPERIMENTAL IR measurements
were
in tne reegion 4000-50 tions.
Sample
atmosphere
made
on IR spectrometer
"Perkin-Elmer"-180
cm -1 in octane , cy=lonex;.ne and benzei:e solu-
preparation
or in vacuum
and cell using
filling
special
was performed
procedure
in inert
(ref.3).The
for the intensity
measurements
did not exceed6-8%.
0022-2860/90/$03.50
0 1990ElsevierSciencePublishersB.V.
error
256
RESULTS
AND DISCUSSION
Measurement
of absolute
Measurements
were
IR band
made
le 1). The intensities because
these
values
and for comparison that the tendency
CP2Fe
lower
than
not influence
values
are summarized
It schould
be noticed
zene modes
3, and
bands were
(ref.Z):the
intensities
of skeletal
that the forbidden
of charges
l.These
in Bz2M
(Tab-
not studied
intensities
in Table
intensities
the intensities
modes
the accuracy
of integrated
of vibrational
fers from metallocenes much
from ten IR active
of two CH stretching should
The obtained
calculation.
intensities
for eight
for Bz2M data
show
complexes
of ligand
modes
metal-ligand
by symmetry
difare
modes.
for "free"ben-
the bisbenzene
9 have a very low intensities. In this respect 10 complexes are closer to "ionic" Cp-compounds (Cp2Mn,
CP2Yg)
as to "covalent"
TABLE
as well
ferrocene.
1
Frequencies (S,cm-') and integrated intensities (A,l.mole of bands in IR spectra of Bz2M (M=V,Cr,Mo) and Cp2Fe.
Bz2V NO
-lcm-2
Bz2Mo
Bz2Cr
)
Cp2Fe
Assignment $
A.104
A.104
$
3
A.104
$
A.104
. $26
, sLML
E.
$25 $23 311
48 *c
Normal
coordinate
There
analysis
are several
benzene
complexes
lations
are available
scheme
Bz2Cr
force
81 frequencies available. diagonal
Data force
coordinate
analysis
of bis-
However
complete
calcu-
0.21 0.02 0.05 0.02 0.14
1005 1431
normal
of force
Norma1
field was
elements
of force matrix
The prosedure
for deuterated from refs.6,8 field
(ref.2).
derivatives
0.18
were
analysis
In this work
for Bz2Cr
varied
is resonable,
were
constants.
coordinate
field was made
force
0.06
complexes
(refs.4-7).
for Bz2Cr.
Diagonal
field.
0.31 0.55 0.11 0.12 0.32 0.22_
to that of Cp2iY complexes
variation
-derivative. d10 but nondiagonal
0.05 172 1.21 481 0.65 498 0.06 815 0.12 845 0.03 1108 0.17 1000 0.02 1423
1.84
820 970
where
140 380 435 785 812 970 1045 1420
2.08
of bisbenzene
works,
only
0.08
159 462 492 795
are described
is similar
the complete
0.06 2.20 0.69 0.55 0.06 0.26 0.11 0.08
150 430 473 745 775 960 992 1440
for Bz2V
transferred since
of Bz2V
and its and Bz2Mo, from the
the experimen-
and Bz2Mo
used as zero order
are not
approach
of
257
TABLE
2
Frequencies and normalized modes Bz2M complexes, M=V,Cr and MO.
Compound
$,cm -1
Assignment
Cal
Bz_Cr L
)ML
Bz2Cr-d10
456
Qcc
459
0.05 -0.04 0.27 -0.09
f CH -0.04 1.06 0.26 -0.03
2252
0.04 0.01 0.25 -0.13
0 0 0.06 0.76
-0.28 -0.25 0.24 -0.09
-0.19 0.80 0.10 -0.05
SML .9cD
422 627
420 637
-kD
2283
920
A2u 0
LML -0.34 -0.18 0.23 -0.06
970 3058
xc
'CH
0 0.03 1.04
3074
928
of
Mode
Exp
795 SCH
of A2u and Elu vibrations
BCH
SLML
Bz2V
&l L 430 $H 742 -kc 963 SCH 3093
430 745 960 3100
0.04 -0.02 0.27 -0.08
0 -0.34 0 -0.17 0.03 0.22 1.04 -0.06
-0.05 1.06 0.20 -0.03
Bz,Plo
$ PL 374 814 QCH see 970 $CH 3083
380 812 970 3100
0.03 -0.07 0.25 -0.09
-0.37 0 -0.18 0.03 0.19 1.04 -0.06
0.02 1.02 0.36 -0.03
0 0 0 -0.32 0 0.07 0.04 0.15 0.03 -0.09 1.04 -0.06
0.01 -0.05 1.07 0.14 -0.05 -0.03
0 0.15 0.03 0.05 -0.03 -0.04 0.70 0.07 1.46 0.04 -0.04 0.03
L
0
Elu Bz2Cr
z LML 163 SML 493 QCH 817 P CH 1003 kc 1437 SCH 3071
Bz2Cr-d10
sLE 8
159 490 820 1005 1431 3058
4'::
SCD 630 CD 795 CC 1278 CD 2272
802 1282 2252
0 0.04 0 0.13 -0.30 -0.12
SLML 149 +IL 472 3CH 779 PCH 995 3cc 1441 ?CH 3080
150 473 775 992 1440 3100
0003 -0.11 0.22 -0.27 -0.07
: 0 0.05 0.02 1.03
-0032 -0.06 0.14 -0.09 -0.06
0 -0.04 1.07 0.13 -0.05 -0.03
0 0.15 0.04 0.05 -0.03 -0.04 0.83 -0.06 1.39 0.05 -0.02 0.03
SLML 138 SML 436 9CH 787 @CH 1037 kc 1418 3CH 3080
140 435 785 1045 1420 3100
: 0 0.04 0.05 1.04
0.01 -0.33 -0.06 0.15 -0.05 -0.06
0.01
0003 -0.02 0.29 -0.19 -0.07
-0.04 1.07 0.13 -0.04 -0.03
0.15 0% 0.06 -0.01 -0.05 0.38 -0.07 1.57 0.03 -0.05 0.03
480
Bz2V
Bz2Mo
0 0.03 -0.02 0.24 -0.24 -0.07
0 0 0 0.05 -0.03 0.76
0.01 -0.29 -0.12 0.13 -0.11 -0.09
0.02 -0.16 0.80 0.06 -0.05 -0.05
0 0.14 0.07 0.07 0 -0.06 0.76 -0.05 0.94 0.05 0.04 0.04
Results the close plexes.
of normal
coordinate
similarity
of the normal
It is important
(SLML) is highly intensity in Bz2M
of this mode
depends
as in Cp2M
data of A2u
ted eigenvectors
and hydrogen
It is well
known
is aggravated ves matrix
that
There
from each
for Bz2M
maining
MO
that
com326
the IR
distribution
intensities were
the method
and calculafor detennina-
charges
described
of dipole
hence
on metal,
in refs.l,2. problem
moment
derivati-
the 2n solutions
correspond
of the
order)each
satisfy-
to 2n possible
for Eiu species,but
in sign.
represented
used
of the electrooptical
(where n- matrix
which
are close
atomic
charges
Practical
sign com-
16 of them
calculations
can be reduced
in their
effective
in Table
3.
(in units
of electron
Variant
Atomic 1
to four. charge
showed The re-
values
charge)
to
in Bz2M
ofsolution
2
3
,4
QC.10
-1.03
-0.91
-1.16
-0.91
QB.10
0.54
0.23
0.36
-0.02
Q,, Cr
exist
only
charge
V
to conclude
mode
3
Effective
M __
using
all the 16 solutions
four,
frequency
and effective
are 32 solutions other
of Cp2M and Bz2M
on charge
coordinates
the solution
values,
indicate
problem
are not known.
12 solutions
one of those
TABLE
atoms
equation
ing the intensity
differ
practically
by the fact that the signs
elements
electrooptical
binations.
permits
parameters
that
vibrations
that the lowest
and Elu bands
in Cartesian
tion of elrctrooptical
and eigenvectors
compounds.
of the electrooptical
Experimental
carbon
to note
characteristic.It
as well
Solution
analysis
0.49
0.68
0.80
0.92
Qc-10
-1.20
-1.34
-1.41
-0.65
QR-10
0.40
0.63
0.30
-0.12
QCr
0.80
0.71
0.91
0.77
QC'10
-0.99
-1.04
-1.07
-0.36
QB.10
0.16
0.27
0.26
-0.42
0.77
0.81
0.78
the calculations
do not give
QMo
0.83
As it has been value
noted
of the charges.
Nevertheless
for all solutions
the absolute the calcula-
259 tion proves are opposite.
that the signs of the metal and carbon atomic charges The data of table 3 permit the following conclusions:
the absolute
values
no defenite series found
of the carbon
e. The charges
exceedO.15
tendency
sponding
in effective
For different
of metals.
to lie between
0.49
Cp-complexes.
se the formal
valence
zero and in Cp2M-
and hydrogen
of the metal
charge
atomic
changes
that
The result
these
and
in the
charges
than
is rather
never
values
is observed
is higher
obtained
charges
are closein
sets of solutions
and 0.92e,
state
atoms
are
for corre-
strange
of the metal
atoms
in Bz2M
to 2+ and the opposite
order
of charges
becau-
is equal was
to
expe-
cted. It is interesting tive
charges
refs.9,10
with
to compare
the quantum
the average
values
the results
chemical
ween
Di value
energy
dissosiation
cyclopentadienyl
to suppose
that
TACLE
are presented
energy
to the valence
E(M-L)
in the series
in Table
is
s-tate.The
from spectroscopic
and benzene
close
In
bet-
data
the energies
are not avaiSable.Nevertheless
as ber~zei,c cui.lpounds they have
for Ei(M-L)
molecule.Thedifference
taken
radical
state
data.
energies
of the metal-ligand boMand L remain in the
dissosiation
atom were
to the valence
is reasonable well
average
from the standard
for the metal
(ref.ll).For transition
as in the initial
and the usual
the excitation last vaiues
state
for the effec-
and thermodinamic
of "inner"
??i(N-L) were proposed as the characteristic nd. It is supposed that after dissosiation same electronic
obtained
of it
of cyclopentadienyl
values.
The obtained
as data
4.
4
Average (rd) and "inner" average (5.) dissosiation energies of M-L bond, metal excita tion energies toithe valence state (&)(~cal/mcle) and Wiberg indexes for Cp2M and Bz2M complexes. Ligand
!"I l5(X-L)
.&
E$Y-L)
SC
‘72i5.
97
V
38+1
58
Co ___ Ni -x--I--_I~ " ;; 68+1 40+1 101 :;
.__~-f-C6H5
W4S,4#PL
W3d_L
1.20
1.5
117 119 116 120
1.4 1.4 1.4 1.4 1. 5 1.5
0.5 0.6 0.6 0.6 O"6 0.6 0.6
ii
0.9 0.8
,g;l -.
.-
_ I-___
2 .O 2.0 2.0 2.0 2.0 2 . ;. 2.1 ------_0.8 1.6 _
~-____-_.-_-__I
wPl-L
117
260
In the series llY_t3
stant
of Cp-complexes
Kcal/mole.
these values
For Bz2X
are approximately the values
complexes
con-
are 94+3;;cal/ -
mole . In the Table presented between
3 the calculated
(ref.12).
The W3d_i_ value
3d A0 and W4s
4h_L-
ligands.
The Wiberg
13) with
parametrization
ain approximately the average
bonds
ato:ns. Taking valent both
covalent, charges
is in agreement
is rather to some
and to a decrease
1
atoms. larger
increase
with
as
ind.:xes of cyc-
charges
(1,"
on met& the co-
that in the
are predominantly
the relatively
small
complexes
fbr cyclopsntadienyl
in the effective
(ref. rem-
as well
characterizes
bonds
charge
or ci((M-L) val:kcs for this
W(M-L)
"ini1e.r'energies
it may be supposed
For bisbenzene than
Wiberg
effective
t'nat W(M-L)
MO of
IXDO method
of complexes
to nigher
the metal-ligand
with
The values
?Yi((M-L). higher
to M-L bond
on the metal
tribution responds
what
series
and to the smaller
of complexes
the interaction
using
(ref.14).
correspond
into consideration
contribution
series
W(P!m.L)z-e also
characterizes
calculated
in both
energies
complexes
metal-iigand
were
of Clack
constant
indexes
4s and 4p A0 of the metal
i;dexes
"inner"
lopentadienyl
Wiberg
class
atomic
the ionic
con-
ones
cor-
on metal
that
atoms
of c0mpOunds.
S.Kh.Samvelyan, V.T.Alexanyan, P.V.Lokshin, J.Mol.S~cctrcsc., 48(1973)47,566. 2 V::'.Alexacyan, l.i.GreenwalJrJ. ?oi.StrL:c-t.,3ij(lT;c%2) 35. .I .G.reenwald,A.S. ir'.'T.A~.exinyan,T'.I.Arser~ieva r X.N. J>~rshinsk~y,I 3 Smirnov Izv.Acad.Sci.USS" rY,ser.kchim.,(1981)299 (in Russian). 4 L:Schafdr,J.i Soutern S .ci.~~~~in,Spc?ctrochj.,7!.Acta,27~(1972)13i~3. 3 3 .;!.Cyi:ir?:a.i:.C;'~i3, ?.ca:l Moleci?ia~- Orbital Theory, ?41:*i:r;-:w HFll,N.Y.,i970. 14 D.C.Lack ,nol..i'!;ys.,27(j.974)ljl3.
JournalofMolecularStructure,218 (1990)255-260 ElsevierSciencePublishersB.V.,Amsterdam-PPrintedinTheNetherlands
CHARGS
SEPARATION
STUDY
IN BISBENZENE
BY THEORETICAL
ANALYSIS
OF INFRARED
I.I.GREENWALD,
B.V.LOKSHIN
COMPLEXES
OF METALS
INTENSITIES
A.N.Nesmeyanov Institute of organoelement sciences, Vavilova Str.28, 117813 I%SCOW
compounds, (USSR)
Academy
of
SUMMARY Using the first approximation of the effective charges model from the experimental IR integrated intensities the effective charges on atoms in bisbenzene complexes of V, Cr and MO have been calculated. The charges on the metal atoms in the complexes studied are somehigher than in corresponding metallocenes and have the values about 0.5-0.9 electron charge units.
INTRODUCTION Considerably in molecules IR bands
intensities
effective
charges
systematic plexes ults
study
Cp2M
have
Therefore
model
(refs.l,2).
showed
have been made
that metallocenes
and calculations
compounds-
bisbenzene
the cyclopentadienyl
opinion, duse
complexes
are unstable
data
on stated
the picture
small
of charge
effective
distribution
atomic
class
Bz=q6-C6H6
make
The res-
chemical
pro-
charges.
of sandwich and M=V,Cr,
the majority
temperature.
compounds
a
com-
out a new seriebof
important
Bz2M, where
at room
three
(ref.2)
this model.
different
to carry
complexes
work
of
of the
in cyclopentadienyl
using
for a very
MO. Unlike
approximation
with
it interesting
charges
on the analysis
In our earlier
charges
and relatively
of effective
based
of first-order
of the effective
similar
ne compounds
to the study
by the method,
in terms
we considered
experiments
approach
(Cp=$-C5H5)
obtained
perties
correct
is represented
of bisbenze-
Nevertheless, it possible
in bisbenzene
in our
to repro-
complexes.
EXPERIMENTAL IR measurements
were
in tne reegion 4000-50 tions.
Sample
atmosphere
made
on IR spectrometer
"Perkin-Elmer"-180
cm -1 in octane , cy=lonex;.ne and benzei:e solu-
preparation
or in vacuum
and cell using
filling
special
was performed
procedure
in inert
(ref.3).The
for the intensity
measurements
did not exceed6-8%.
0022-2860/90/$03.50
0 1990ElsevierSciencePublishersB.V.
error
256
RESULTS
AND DISCUSSION
Measurement
of absolute
Measurements
were
IR band
made
le 1). The intensities because
these
values
and for comparison that the tendency
CP2Fe
lower
than
not influence
values
are summarized
It schould
be noticed
zene modes
3, and
bands were
(ref.Z):the
intensities
of skeletal
that the forbidden
of charges
l.These
in Bz2M
(Tab-
not studied
intensities
in Table
intensities
the intensities
modes
the accuracy
of integrated
of vibrational
fers from metallocenes much
from ten IR active
of two CH stretching should
The obtained
calculation.
intensities
for eight
for Bz2M data
show
complexes
of ligand
modes
metal-ligand
by symmetry
difare
modes.
for "free"ben-
the bisbenzene
9 have a very low intensities. In this respect 10 complexes are closer to "ionic" Cp-compounds (Cp2Mn,
CP2Yg)
as to "covalent"
TABLE
as well
ferrocene.
1
Frequencies (S,cm-') and integrated intensities (A,l.mole of bands in IR spectra of Bz2M (M=V,Cr,Mo) and Cp2Fe.
Bz2V NO
-lcm-2
Bz2Mo
Bz2Cr
)
Cp2Fe
Assignment $
A.104
A.104
$
3
A.104
$
A.104
. $26
, sLML
E.
$25 $23 311
48 *c
Normal
coordinate
There
analysis
are several
benzene
complexes
lations
are available
scheme
Bz2Cr
force
81 frequencies available. diagonal
Data force
coordinate
analysis
of bis-
However
complete
calcu-
0.21 0.02 0.05 0.02 0.14
1005 1431
normal
of force
Norma1
field was
elements
of force matrix
The prosedure
for deuterated from refs.6,8 field
(ref.2).
derivatives
0.18
were
analysis
In this work
for Bz2Cr
varied
is resonable,
were
constants.
coordinate
field was made
force
0.06
complexes
(refs.4-7).
for Bz2Cr.
Diagonal
field.
0.31 0.55 0.11 0.12 0.32 0.22_
to that of Cp2iY complexes
variation
-derivative. d10 but nondiagonal
0.05 172 1.21 481 0.65 498 0.06 815 0.12 845 0.03 1108 0.17 1000 0.02 1423
1.84
820 970
where
140 380 435 785 812 970 1045 1420
2.08
of bisbenzene
works,
only
0.08
159 462 492 795
are described
is similar
the complete
0.06 2.20 0.69 0.55 0.06 0.26 0.11 0.08
150 430 473 745 775 960 992 1440
for Bz2V
transferred since
of Bz2V
and its and Bz2Mo, from the
the experimen-
and Bz2Mo
used as zero order
are not
approach
of
257
TABLE
2
Frequencies and normalized modes Bz2M complexes, M=V,Cr and MO.
Compound
$,cm -1
Assignment
Cal
Bz_Cr L
)ML
Bz2Cr-d10
456
Qcc
459
0.05 -0.04 0.27 -0.09
f CH -0.04 1.06 0.26 -0.03
2252
0.04 0.01 0.25 -0.13
0 0 0.06 0.76
-0.28 -0.25 0.24 -0.09
-0.19 0.80 0.10 -0.05
SML .9cD
422 627
420 637
-kD
2283
920
A2u 0
LML -0.34 -0.18 0.23 -0.06
970 3058
xc
'CH
0 0.03 1.04
3074
928
of
Mode
Exp
795 SCH
of A2u and Elu vibrations
BCH
SLML
Bz2V
&l L 430 $H 742 -kc 963 SCH 3093
430 745 960 3100
0.04 -0.02 0.27 -0.08
0 -0.34 0 -0.17 0.03 0.22 1.04 -0.06
-0.05 1.06 0.20 -0.03
Bz,Plo
$ PL 374 814 QCH see 970 $CH 3083
380 812 970 3100
0.03 -0.07 0.25 -0.09
-0.37 0 -0.18 0.03 0.19 1.04 -0.06
0.02 1.02 0.36 -0.03
0 0 0 -0.32 0 0.07 0.04 0.15 0.03 -0.09 1.04 -0.06
0.01 -0.05 1.07 0.14 -0.05 -0.03
0 0.15 0.03 0.05 -0.03 -0.04 0.70 0.07 1.46 0.04 -0.04 0.03
L
0
Elu Bz2Cr
z LML 163 SML 493 QCH 817 P CH 1003 kc 1437 SCH 3071
Bz2Cr-d10
sLE 8
159 490 820 1005 1431 3058
4'::
SCD 630 CD 795 CC 1278 CD 2272
802 1282 2252
0 0.04 0 0.13 -0.30 -0.12
SLML 149 +IL 472 3CH 779 PCH 995 3cc 1441 ?CH 3080
150 473 775 992 1440 3100
0003 -0.11 0.22 -0.27 -0.07
: 0 0.05 0.02 1.03
-0032 -0.06 0.14 -0.09 -0.06
0 -0.04 1.07 0.13 -0.05 -0.03
0 0.15 0.04 0.05 -0.03 -0.04 0.83 -0.06 1.39 0.05 -0.02 0.03
SLML 138 SML 436 9CH 787 @CH 1037 kc 1418 3CH 3080
140 435 785 1045 1420 3100
: 0 0.04 0.05 1.04
0.01 -0.33 -0.06 0.15 -0.05 -0.06
0.01
0003 -0.02 0.29 -0.19 -0.07
-0.04 1.07 0.13 -0.04 -0.03
0.15 0% 0.06 -0.01 -0.05 0.38 -0.07 1.57 0.03 -0.05 0.03
480
Bz2V
Bz2Mo
0 0.03 -0.02 0.24 -0.24 -0.07
0 0 0 0.05 -0.03 0.76
0.01 -0.29 -0.12 0.13 -0.11 -0.09
0.02 -0.16 0.80 0.06 -0.05 -0.05
0 0.14 0.07 0.07 0 -0.06 0.76 -0.05 0.94 0.05 0.04 0.04
Results the close plexes.
of normal
coordinate
similarity
of the normal
It is important
(SLML) is highly intensity in Bz2M
of this mode
depends
as in Cp2M
data of A2u
ted eigenvectors
and hydrogen
It is well
known
is aggravated ves matrix
that
There
from each
for Bz2M
maining
MO
that
com326
the IR
distribution
intensities were
the method
and calculafor detennina-
charges
described
of dipole
hence
on metal,
in refs.l,2. problem
moment
derivati-
the 2n solutions
correspond
of the
order)each
satisfy-
to 2n possible
for Eiu species,but
in sign.
represented
used
of the electrooptical
(where n- matrix
which
are close
atomic
charges
Practical
sign com-
16 of them
calculations
can be reduced
in their
effective
in Table
3.
(in units
of electron
Variant
Atomic 1
to four. charge
showed The re-
values
charge)
to
in Bz2M
ofsolution
2
3
,4
QC.10
-1.03
-0.91
-1.16
-0.91
QB.10
0.54
0.23
0.36
-0.02
Q,, Cr
exist
only
charge
V
to conclude
mode
3
Effective
M __
using
all the 16 solutions
four,
frequency
and effective
are 32 solutions other
of Cp2M and Bz2M
on charge
coordinates
the solution
values,
indicate
problem
are not known.
12 solutions
one of those
TABLE
atoms
equation
ing the intensity
differ
practically
by the fact that the signs
elements
electrooptical
binations.
permits
parameters
that
vibrations
that the lowest
and Elu bands
in Cartesian
tion of elrctrooptical
and eigenvectors
compounds.
of the electrooptical
Experimental
carbon
to note
characteristic.It
as well
Solution
analysis
0.49
0.68
0.80
0.92
Qc-10
-1.20
-1.34
-1.41
-0.65
QR-10
0.40
0.63
0.30
-0.12
QCr
0.80
0.71
0.91
0.77
QC'10
-0.99
-1.04
-1.07
-0.36
QB.10
0.16
0.27
0.26
-0.42
0.77
0.81
0.78
the calculations
do not give
QMo
0.83
As it has been value
noted
of the charges.
Nevertheless
for all solutions
the absolute the calcula-
259 tion proves are opposite.
that the signs of the metal and carbon atomic charges The data of table 3 permit the following conclusions:
the absolute
values
no defenite series found
of the carbon
e. The charges
exceedO.15
tendency
sponding
in effective
For different
of metals.
to lie between
0.49
Cp-complexes.
se the formal
valence
zero and in Cp2M-
and hydrogen
of the metal
charge
atomic
changes
that
The result
these
and
in the
charges
than
is rather
never
values
is observed
is higher
obtained
charges
are closein
sets of solutions
and 0.92e,
state
atoms
are
for corre-
strange
of the metal
atoms
in Bz2M
to 2+ and the opposite
order
of charges
becau-
is equal was
to
expe-
cted. It is interesting tive
charges
refs.9,10
with
to compare
the quantum
the average
values
the results
chemical
ween
Di value
energy
dissosiation
cyclopentadienyl
to suppose
that
TACLE
are presented
energy
to the valence
E(M-L)
in the series
in Table
is
s-tate.The
from spectroscopic
and benzene
close
In
bet-
data
the energies
are not avaiSable.Nevertheless
as ber~zei,c cui.lpounds they have
for Ei(M-L)
molecule.Thedifference
taken
radical
state
data.
energies
of the metal-ligand boMand L remain in the
dissosiation
atom were
to the valence
is reasonable well
average
from the standard
for the metal
(ref.ll).For transition
as in the initial
and the usual
the excitation last vaiues
state
for the effec-
and thermodinamic
of "inner"
??i(N-L) were proposed as the characteristic nd. It is supposed that after dissosiation same electronic
obtained
of it
of cyclopentadienyl
values.
The obtained
as data
4.
4
Average (rd) and "inner" average (5.) dissosiation energies of M-L bond, metal excita tion energies toithe valence state (&)(~cal/mcle) and Wiberg indexes for Cp2M and Bz2M complexes. Ligand
!"I l5(X-L)
.&
E$Y-L)
SC
‘72i5.
97
V
38+1
58
Co ___ Ni -x--I--_I~ " ;; 68+1 40+1 101 :;
.__~-f-C6H5
W4S,4#PL
W3d_L
1.20
1.5
117 119 116 120
1.4 1.4 1.4 1.4 1. 5 1.5
0.5 0.6 0.6 0.6 O"6 0.6 0.6
ii
0.9 0.8
,g;l -.
.-
_ I-___
2 .O 2.0 2.0 2.0 2.0 2 . ;. 2.1 ------_0.8 1.6 _
~-____-_.-_-__I
wPl-L
117
260
In the series llY_t3
stant
of Cp-complexes
Kcal/mole.
these values
For Bz2X
are approximately the values
complexes
con-
are 94+3;;cal/ -
mole . In the Table presented between
3 the calculated
(ref.12).
The W3d_i_ value
3d A0 and W4s
4h_L-
ligands.
The Wiberg
13) with
parametrization
ain approximately the average
bonds
ato:ns. Taking valent both
covalent, charges
is in agreement
is rather to some
and to a decrease
1
atoms. larger
increase
with
as
ind.:xes of cyc-
charges
(1,"
on met& the co-
that in the
are predominantly
the relatively
small
complexes
fbr cyclopsntadienyl
in the effective
(ref. rem-
as well
characterizes
bonds
charge
or ci((M-L) val:kcs for this
W(M-L)
"ini1e.r'energies
it may be supposed
For bisbenzene than
Wiberg
effective
t'nat W(M-L)
MO of
IXDO method
of complexes
to nigher
the metal-ligand
with
The values
?Yi((M-L). higher
to M-L bond
on the metal
tribution responds
what
series
and to the smaller
of complexes
the interaction
using
(ref.14).
correspond
into consideration
contribution
series
W(P!m.L)z-e also
characterizes
calculated
in both
energies
complexes
metal-iigand
were
of Clack
constant
indexes
4s and 4p A0 of the metal
i;dexes
"inner"
lopentadienyl
Wiberg
class
atomic
the ionic
con-
ones
cor-
on metal
that
atoms
of c0mpOunds.
S.Kh.Samvelyan, V.T.Alexanyan, P.V.Lokshin, J.Mol.S~cctrcsc., 48(1973)47,566. 2 V::'.Alexacyan, l.i.GreenwalJrJ. ?oi.StrL:c-t.,3ij(lT;c%2) 35. .I .G.reenwald,A.S. ir'.'T.A~.exinyan,T'.I.Arser~ieva r X.N. J>~rshinsk~y,I 3 Smirnov Izv.Acad.Sci.USS" rY,ser.kchim.,(1981)299 (in Russian). 4 L:Schafdr,J.i Soutern S .ci.~~~~in,Spc?ctrochj.,7!.Acta,27~(1972)13i~3. 3 3 .;!.Cyi:ir?:a.i:.C;'~i3, ?.ca:l