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Anionic tricarbonyl derivatives of molybdenum and tungsten and their reactions with allyl halides
427
Journa1ofOrganometa11icChemistry.156 (1978) 42'7-437 0 ElsevierSequoiaS.A.,Lausann e-FkintedinTheNetherlanck
ANIONIC
TRICARBONYL
OF MOLYBDENUM AND
THEIR
BRIAN
School
AND
REACTIONS
TUNGSTEN
WITH
J.BRISDON, and
DERIVATIVES
ALLYL
DENNIS
JAMES
H4LIDE.S
A-EDWARDS
W.WBITE
of Chemistry, University of Bath, Bath BA2 7AY (Great Britain) (Received
?Iay 17th,
1975)
Summary A series where
I = Mo
or W,
of carbonylmetallate X = Cl,
or 2,2 '-bipyridine(bipy) cis-M(C0) was
L 42
evident
have
the
formation
with
various
ally1
I and
been
No
complexes.
evidence
for-
from
of -fat-to in MeCN
the
solvolysis Reaction
halides
yields
resulted
in high The
the mechanism
of the
significance
ally1
corresponding
mer-isomerisation
of fat-M(CO)2L2(MeCN).
[MX(CO)2(~3-RC3H,)L2].
servations
fat-[MX(COl2L,]-,
L2 = l,lO-phenanthroline(phen)
prepared
although
on dissolution,
with
complexes
Br or
anions
of
occurred the
anions
of q3-ally1 of
these
oh-
oxidative-addition
reaction are discussed.
Introduction The synthesis
use
reactive
of organometallics
well-established which
of higbly
these
procedure
nucleophiles
carbonylmetallate
of the [1,2].
react
with
early Because ally1
transition of
anions metals
the mild
halides,
many
for
the
is now
conditions new
a under
T13-ally1
428 complexes
of these
including
some
elements
chromium
have
analogues
CMX
materials
the
anions
been
for
of the
where the
facile
first
ceq.1).
anions
(eq.2).
not
given
subsequently
found
this
of
[3-71,
X = halide
this
prepared
A more but
route
VI series
or W and
synthesis
[MX
by
Group
I = MO
frown M(C0)3
prepared
series by
The
of allyl-complexes
Behrens
convenient
full
LS].
et al.
[9)
routetothese
experimental
details
were
173.
M(C013cht
+ bidentate
M
paper
molybdenum
and
preparation
+ X-
f X-
reports
tungsten
-
the
[YX(CO)3bidentate]-
LMx
anionic
of several
-
ally1
and
derivatives
and of
(1)
+ CG
ssctroscopic
complexes.
+ cht
(2) properties
filustrates
these
their
of
use
the
in the
elements.
Experimental Al2
solvents
in an atmosphere where
M = MO
prepared Ph4PC1 Ph4PX
by
were
of dry
or W;
purified nitrogen
and
dried,
gas.
The
L2 = 2,2'-bipyridine
literature
methods
by a stoichiometric (X = Cl or Br)
and
Et4NX
was
XI, while
(X = Cl,
were
materials
carried
Br or
precipitated commercial
I) were
were from
samples
warmed
out
&-M(CO)4L2,
l,lO-phenanthroline,
Ph4PI of
reactions
starting
or
[lo].
quantity
and
aqueous of
in vacua --
before
use. %I NMR
spectra
tetramethylsilane on a Hilger
as
and
Far
interferometer
Preparation
of
These with
Ph4PX
[MX(CO),L,]-
or Et4NX
mulls
studies
samples
complexes
Infrascan
Nujol
infrared
with
reference.
H 1200
using
on a JEOL
recorded
internal
Watts
spectrophotometer
or CH2Cl2.
were
were
dispersed
100
Infrared and
and
PS
spectrometer
using
spectra
were
on a Perkin-Elmer
237
solutions carried
of complexes
out
in pressed
recorded
in MeCN
on a Beckmann
polythene
FS 720
discs.
salts
were
prepared
by
the
direct
in MeCN
/toluene
or MeCN/xylene
reaction mixtures.
of cis-M
429
procedures
are
significant
given
for
variations
one
molybdenum
in experimental
Ph4P[MoC1(CO)_phen]. Mo(CO)4phen in refluxing product dried
4:l
was
Yield
in vacua.
by similar
time
For
of 4 h. was
the
(5 mmol)
product
was
in refluxing
filtered
analogous reaction 1:l.S
time
for
and
the
Preparation
of
The
washed
for
was
heated
with
Complexes complexes ratio
of 1:3
R4Z[MX(CO)3L2]
(10 mmol)
(1 mmol)
(0.2
h for
MO and
the
solid
product
was
filtered
off,
washed
with
Ph
known
of
gc
2) crystallised
to stand
L2
in over
Preparation
XIII
a
divided for
water, were
the
8 h.
then
The
methanol
prepared
1 required
at 0°C
complexes = bipy 80%
for
(10 cm3)
added
complete
(Table
in methanol
was
was
isolated
and
prepared
in an
a 16 h.
and
iodo-complex
chloro-analogues.
reaction
X = Cl or Br;
and
were
finely
(40 cm3)
for
the
The
with
in Table
When
allcwed
XII
ma~ol)
the
methanol
V (Tablel)
XIV-XVI
halide
was
(1.5
[Mx(c~)~(T~-Rc~H~)L~]
complex
XXIV
cold
ice-cold
of ally1
Complex
Ph4PCl
On cooling,
1 h.
IV and
and
below.
with
of complexes
rapidly
remaining
and
reacted
xylene/acetonitrile
a M(CO)4L2:R4ZX
bromo-
noted
a little
II,
(1 mmol)
Yield 93%. The
manner.
with
synthesis
8:l
off,
end dried in vacua.
was
complex,
necessary.
Et4N[WI(CO)3bipy-j.W(CO)4bipy Et4NI
rapidly
tungsten are
(40 cm3)
Complexes
97%.
procedures.
reaction
(1 mmol)
washed
off,
one
details
toluene/acetonitrile
filtered
and
only
slowly
72 h prior
yields
by
at ambient 1.0
and
the
where
M = W, X = Cl or
this
temperatures.
h for W compounds),
methanol and
solution
dried
reaction
in vacua. --
mixture
to filtration.
[MX(CO)2
to a stirred
Li'j~ bipy,
I [11,12]
were
M = MO,
all
procedure.
[MoBr(CO)2(r13-cyclohexenyl)bipy]
MoBr
3-bromocyclohexene
CO.5
(5 mmol)
(complex
XXII,
Table
vacua.
Yield
42%.
2) was The
mmol)
was
added
in CHC13
(5 cm3)
filtered
off,
corresponding
to a deoxygenated
at -15@c.
washed
with
phenanthroline
The CH2C12 anion
solution
product and
dried
reacted
3
in an
of
431 analogous
manner
oxidised
and
but
could
the
not
h3 -cyclohexenyl
be obtained
derivative
so
formed
in an analytically
pure
easily
was
state.
and discussion
Results
Tricarbonyl anions [MX(CO)3L2]The anionic yields
as deep
to reform were
most
and
of
purple
the
as
Sparingly
were
which
the
1 were
which
all
slowly
decomposition
data
were
in high
decomposed
on standing The
solvents
by coordinating
confined
obtained
products.
in non-coordinating
solvolysed
spectroscopic
of stoichiometry may
ligand.
should
stretching
give
exist
rise
Such
state
complexes
as
solvents,
to solid
the mer-isomer
case
three
strong
bands
are
expected
show
three
strong
CHCl 3 and
consequently
measurements
this
L
2
was
these
complexes
the
no evidence
on dissolution
NMe4[MoI
and
constant
Cotton-Rraihanzel
are
and
of
as
for
the carbonyl
as modified
by
anionic
state
forlner
and
two
and
in solution assigned
temperature
the
with
carbonyl
species
of any where
halide stretching
were
discernable.
the anion previously
a
the anions
solutions
saturated
strong
discussion
[M(COj3(MeCNjL2],
of
reported
in any
of
for
[9].
anions
Dalton
under
and
mer-isomerisation in MeCN,
weak
of MeCN
In MeCN
the
in the
consequently
spectra
of
be distinguished
one
at room
be retarded
both
carbonyl
since
solid
[Ni
data
method
and
[14].
solvolysed
of -fat-to
31,
solvents
could
may
anions
characteristic
or phen
reaction
in the
forms,
terminal
whereas The
infrared
features
= bipy
of both
There
Thus
showed
solvolytic
frequencies
[13].
is a bidentate
isomeric
measurements,
absorptions
solvents
L2
fat-isomer
predicted
latter
carbonyl
solvolysed.
or W and
are
In coordinating
the complexes
I = MO
the
two
the
intensity
absorptions for
of
where
infrared-active
In general
fat-configuration. quickly
in either
by band
in non-coordinating
[MX
to three
vibrations.
from
ion,
solids
of
soluble
in Table
3).
chelating
of
one
immediately
Complexes
were
listed
crystalline
cis-M
at most
CH2C12
complexes
were
et al.
calculated [15].
by
the
In previous (Continued
on p.434j
(XXIV)
all
38.0 (39.5)
78
txxrrr)
b
Known complexes
on Nojol
44.8 (43.4)
89
(XXII)
LMoBr(CO),(TJ-C,H,)bipy]
a Recorded
47.1 (46.1)
42
(XXI)
[MoBr(CO)2(q-l-MeC3H4)bipy]
[WCl(CO),+2-.MeC,H,)bipy]
42.2 (43.4)
82
(XX)b
46.7
mulls,
83
bands
(48,2)
[MoBr(CO)2(q-l-MeC3H4)phen]
90
(XIX)
86
C
[MoCl(CO),(U-2-MeC,H,)bipy]
)b
(%)
(XVIII
Yield
[MoC1(CO)2(‘I)-2-MeC3H4)phen]
Complex
are
strong
G)
unless
N
otherwise
Elemental analysis found (calcd.) (%) H
ANALYTICAL AND SELECTED INFEARED DATA FOR THE COMPLEXES [MX(CO),(q-allyl)L,]
TABLE 2
noted
1918
1928
1920
1920
1925
1925
1923
*1
Infrared v(c-o)a
1841
1840
1838
1831
1838
1636
1847
B1
data
(cm-l)
268
164
166
164
168
267
266
v(M-X)
433
TABLE
3
SELECTED
INFRARED
Complex
V(h+X)
AND
FORCE
(G-1)
CONSTANT
-1
v
FOR
A"
1765
1742
1880
II
146
1886
ANIONS
Carbonyl constants
A'
227
CARBONYL
1
Ai
I
III
DATA
K
1751br
force (mdyne
b 2-l)
Kc'
KI
K2
0.59
0.60
12.9
13.4
0.50
0.70
12.9
13.4
c
1884
1764
1742
0.60
0.63
12.9
13.5
IV
227
1887
1769
1748
0.59
0.62
12.9
13.5
V
153
1886
1772
1751
0.57
0.60
13.0
13.5
1884
1763
1740
0.61
0.63
12.8
13.5
VI VII
234
1874 1880
1764 1760
1743 1743=
0.55 0.56
0.57 0.62
12.8 12.8
13.4 13.4
VIII
147
1874 1880
1766
1743br 1745c
0.48 0.57
0.68 0.59
12.8 12.9
13.2 13.4
1746br
o.i7
0.67
12.8
13.3
1875
IX X
230
1877
1763
1743
0.56
0.59
12.8
13.4
XI
158
1867 1879
1753 1758
1736 1742c
0.54 0.56
0.60 0.63
12.7 12.8
13.3 13..4
XII
229
1879
1763
1719
0.53
0.75
13.0
13.5
XIII
222
1884
1766
1737
0.45
0.64
13.2
13.7
XIV
129
1900 1892
0.59
177?
xv
129
1899
XVI
127
1870 1881
XVII
125
1877
Recorded Calculated Solution
data
0.60
0.63 0.64
13.0 12.6
13.6 13.2
1756br
0.51
0.72
12.7
13.2
0.64 0.51
0.62 0.62
12.8 12.9
13.5 13.4
0.74
0.60
12.7
13.4
1747 1762
1726 1752= 1737br
on Nujol by
1778br 1751c
the
mulls
unless
procedure
in CH2C12
otherwise
given
indicated
in ref.15
434
studies Lewis
of cis-L -2 base
used
and
in such
K2 greater expected
M = go
derivatives,
3
from
where
or W [14,15],
calculations,
than
complexes
YM(CO)
the
resulting
the
equatorial
simple
n-bonding
cis-MnX(-CO)3L2
L = bipy
assignment
in axial
CO stretching
A'
>
force
A**
force
constants
However,
an electronegative
Y = monodentate
A' >
CO stretching
considerations_
containing
or phen,
as
some
halide
been
constants
$,
for
has
manganese
ligand
X *'i
becomes
larger
intermediate under of
than
frequency
consideration
this
band
order
force
but
Kz'$'
that
A' >
and
hence
the
calculated
magnitude
interaction
possible
VII
based
on
the
alternative
stretching
seems
3 with
Kc =-, Kc
constants<6
assignment
and
in Table
given
at
derivatives
possible
yielded
to those
band
VI complexes
Group
considered
calculations
to the
Group
neutral
were
also
divergent
assigned
the anionic with
These
second
nor
'i
tungsten found
to
these
complexes,
of
these
Group
charge
on the
significant
for
less
as
likely
low
as
than
varies Thus
probably
central
atom
Lewis
and
complexes
was
found
M-X
stretches
complexity
of
of the
Y = monodentate
On ally1
The
for
far-infrared each
of
of the
oxidation, in their
difficultto
base
throughout
effect
pentacarbonyl of
effect
the molybdenum
where
halides the
into
halogen [18]
increased
not
the
where
extend
increased
compared or phen
cis
radii
results
constants
fac-MX
does
of
or W. L2 = bipy
and
on the
covalent
C 2~? orbitals
force
M = MO
~ld,lS,lS]
of the
of back-donation
the anions
in a with
and
M = Mn
or Re
[16]. region
the anions corresponding
the M(I1) far-infrared
assign
marked
CO stretching
fat-MY(C0)3L2,
In the
the
as a result
VI elements.
X = halide,
significantly
2
the manganese
decrease
neutral
K
series.
Co group
more
were
A'.
widely this
Since
been
tabulated.. Neither
many
constants )
has
assignments
of a similar
with
mode
isoelectronic both
A"
constants
0.331,
are
force
the A"
Cl+17-J.
stoichiometry,
consequently
or
K2 and
with
only (Table
a single 3),
strong
at even
halopentacarbonyl
derivatives
so
spectra
and
confidence.
The
lower
wavenumbers
anions
formed M-X
halogen-sensitive
showed
stretching
most
halogen
[MX(CO)5)an
band than
the
c20].
increased
frequencies sensitive
were bands
435 the
in
entire
Table
2 and
are
tentatively
agreement
with
the
v
ratio
spectra
infrared
data
the
: v(M-Br)
frequencies
Ally1
at
derivatives The
halides
at
room
are
139
-1
cm
anions
given
in
are
in good
derivatives
with
thatof
were
show
are
also
strong
the
[Zl]
parent
examined
and anions,
to
stretching
W-I
respectively.
listed
temperature 'Ihis route
complexes
in Table
or below
1 reacted
to give
is particularly
to prepare
difficult
molybdenum
phosphine
closely
I and
XXIV
[?d~(~O)2(~~~-allyl)1.2]
carbonyl
derivatives. which
and
ditertiary
Br and
-
These values
[WI(CO)2
X = Cl,
137
XVIII
as v(M-x).
correlates
and
series
complexes
assigned
on analogous
[WI(CO),(?i-C3H~)bipy] c complete
of
by
[11.12]
due
the
high
useful
slow
yields for
procedure
to the
readily
ally1
of M
the
tungsten
normally
kinetics
with
analogues
adopted
for
and
competing
and
XIX
the. reactions
_ of the
tungsten
sufficiently showed due
intermediates.
soluble
singlets
to the
8.25(d). ally1
for NMR
at
6 1.01,
n3-ally1
group,
8.06(t)
methyl
and
group
Only
measurements.
1.40
and
and
7.61(t)
ppm
The
caused
by
is even
greater
(6 0.70
related
complex
[Mo(NCS)(CO)2(?l-2-MeC3Hq)phen]
shown
to lay
solubilities precluded' CkC
of the their
stretch
this
members
the
and
plane
of
the
complexes
solid-state
with
mechanisms halides
of
complex
this
methyl
in Table
2 in suitable.
XVIII
structures
and
and
XIX
shift
closely
group
[22].
The
has
low
NhlR solvents
of an uncoordinated their
and
[22,23]
the
the
In the
ligand
oectra
of
effects
ally1
the absence
3:2:2
6 8.79(d),
shift
aromatic
infrared
known
at
group). the
latter
ratios
up-field
shielding
were the
intensity
absorptions
methyl
but
to complexes
at -57OC
phenanthroline
the ally1
characterisation.
q3-ally1
related
for
remaining
stoichiometry of
the
similarity
Various ally1
full
in their
spectroscopic of
over
corresponding
the
ring,
ppm
with
pronounced
aromatic
been
in the
2.39
ppm.
XVIII
In SO2
2,2'-bipyridine
is no doubt
and
complexes
to
general other
indicated
complexes
they
were
also
series. have
been
proposed
to low-valent
for
transition
the
oxidative
metal
addition
complexes,
of
including
436
nucleophilic [241p
attack
a concerted
and
initial
step
[27].
ally1
of
the metal
insertion
coordination Strong
mechanism
of
the
a-C
atom
thp
anion
subsequent
of
the
evidence
that
or direct halide
of halide
carbon
[25], to the
atom
bearing
a radical metal
chain
as
the
the.balogen process
rate
last
mechanism
is operative
has
been
presented
recently
(B), in
would
attack
in the A
[28].
metal
atom
on
explain why the halogen in
the P(II)-ally1
occurs
of the
[ZS]
determining
this
nucleophilic
retained
is initially exchange
e:C
systems
ally1
the
reaction
halide-IrX
similar
at
in some
products,
instances
although
in solution
on
standing.
A
+
[Mx(co)3L21-
CH2=CH-CH2Y
-
[(YcH2cH=CE2MX(co)2L2]-
I cMX(co)3L2]-
+
c!B2=CR-CB2Y
-
'co
fast
mwo)2L21 + y-
[ (R-C3H5
B
+
~~cH~=C~-CB~)MX(C~~~L~I
+
Y-
fast I [&C3"5MX
Attempts have
proved
to identify
unsuccessful
positively
so
either
of
these
+
reactive
CO
intermediates
far.
Acknowledgement We
thank
the
S.R.C.
for
the award
of a Research
Studentship
References
1.
J-Ellis.
2.
R.B.Mng.
3.
G.Doyle.
4.
J-Ellis
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86
3 (1970)
.J.Organometal.Ghem., and
R.A.Faltynek.
132
(1975)
1
417 (1977)
243
J.Organometal.Chem..
93
(1975)
205
(to J.W.W.).
437 5.
M.Schneider
6.
F.Hohmann,
7.
B.J.Brisdon
and
G-F-Griffin.
J.Chem.Soc.Dalton
8.
B.J.Brisdon
and
G.F.Griffin.
J.Organometal.Chem.,
9.
H.Behrens.
and
E-Weiss.
J.Organometal.Chem..
J.Organometal.Chem..
E.Lindner
and
137
(1977)
G.Lehnert,
(1974)
C7
315 (1975) 76
1999 (1974)
J.Organometal.Chem.,
M.B.H.Stiddard,
11.
C.G.Hull
12.
H.
13.
L.E.Orgel,
14.
L.W.Houk
15.
J-Dalton.
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L.F.Wuyts
and
17.
R.J.Angelici,
18.
M.B.Hall
and
R.F.Fenske,
Inorg.Chem..
19.
L.W.Houk
and
G.R.Dobson.
J.Chem.Soc.A,
20.
R-J-H-Clark
21.
B.J.Brisdon
22.
A.J.Graham
and
R.H.Fenn,
J.Organometal.Chem..
25
(1970)
173
23.
A-J-Graham
and
R.H.Fenn.
J.Organometal.Chem..
17
(1969)
405
24.
P.K.Wong,
25.
R.G.Fearson.
26.
J.A.Labinger,
27.
J.A.Osborn.
tom
Plenum 28.
M.B.H.Stiddard,
Dieck
and
G.R.Dobson,
der
F.Easolo
and and
and
J.Chem.Soc.A.
Inorg.Chim.Acta
A.J.Poe,
23
19
85
(1963)
J.Amer.Chem.Soc., 11
(1972)
(1966)
J.Organometal
Chem.,
149
in Y.Ishii
and and
Corp.,
A.T.Poulos
and
J.A.Osborn,
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New
J.Amer.Chem.Soc., 41
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J.A.Ibers,
(1973)
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113
(1974)
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76
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K.E.Paddick,
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Inorg.Chem.,
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Journa1ofOrganometa11icChemistry.156 (1978) 42'7-437 0 ElsevierSequoiaS.A.,Lausann e-FkintedinTheNetherlanck
ANIONIC
TRICARBONYL
OF MOLYBDENUM AND
THEIR
BRIAN
School
AND
REACTIONS
TUNGSTEN
WITH
J.BRISDON, and
DERIVATIVES
ALLYL
DENNIS
JAMES
H4LIDE.S
A-EDWARDS
W.WBITE
of Chemistry, University of Bath, Bath BA2 7AY (Great Britain) (Received
?Iay 17th,
1975)
Summary A series where
I = Mo
or W,
of carbonylmetallate X = Cl,
or 2,2 '-bipyridine(bipy) cis-M(C0) was
L 42
evident
have
the
formation
with
various
ally1
I and
been
No
complexes.
evidence
for-
from
of -fat-to in MeCN
the
solvolysis Reaction
halides
yields
resulted
in high The
the mechanism
of the
significance
ally1
corresponding
mer-isomerisation
of fat-M(CO)2L2(MeCN).
[MX(CO)2(~3-RC3H,)L2].
servations
fat-[MX(COl2L,]-,
L2 = l,lO-phenanthroline(phen)
prepared
although
on dissolution,
with
complexes
Br or
anions
of
occurred the
anions
of q3-ally1 of
these
oh-
oxidative-addition
reaction are discussed.
Introduction The synthesis
use
reactive
of organometallics
well-established which
of higbly
these
procedure
nucleophiles
carbonylmetallate
of the [1,2].
react
with
early Because ally1
transition of
anions metals
the mild
halides,
many
for
the
is now
conditions new
a under
T13-ally1
428 complexes
of these
including
some
elements
chromium
have
analogues
CMX
materials
the
anions
been
for
of the
where the
facile
first
ceq.1).
anions
(eq.2).
not
given
subsequently
found
this
of
[3-71,
X = halide
this
prepared
A more but
route
VI series
or W and
synthesis
[MX
by
Group
I = MO
frown M(C0)3
prepared
series by
The
of allyl-complexes
Behrens
convenient
full
LS].
et al.
[9)
routetothese
experimental
details
were
173.
M(C013cht
+ bidentate
M
paper
molybdenum
and
preparation
+ X-
f X-
reports
tungsten
-
the
[YX(CO)3bidentate]-
LMx
anionic
of several
-
ally1
and
derivatives
and of
(1)
+ CG
ssctroscopic
complexes.
+ cht
(2) properties
filustrates
these
their
of
use
the
in the
elements.
Experimental Al2
solvents
in an atmosphere where
M = MO
prepared Ph4PC1 Ph4PX
by
were
of dry
or W;
purified nitrogen
and
dried,
gas.
The
L2 = 2,2'-bipyridine
literature
methods
by a stoichiometric (X = Cl or Br)
and
Et4NX
was
XI, while
(X = Cl,
were
materials
carried
Br or
precipitated commercial
I) were
were from
samples
warmed
out
&-M(CO)4L2,
l,lO-phenanthroline,
Ph4PI of
reactions
starting
or
[lo].
quantity
and
aqueous of
in vacua --
before
use. %I NMR
spectra
tetramethylsilane on a Hilger
as
and
Far
interferometer
Preparation
of
These with
Ph4PX
[MX(CO),L,]-
or Et4NX
mulls
studies
samples
complexes
Infrascan
Nujol
infrared
with
reference.
H 1200
using
on a JEOL
recorded
internal
Watts
spectrophotometer
or CH2Cl2.
were
were
dispersed
100
Infrared and
and
PS
spectrometer
using
spectra
were
on a Perkin-Elmer
237
solutions carried
of complexes
out
in pressed
recorded
in MeCN
on a Beckmann
polythene
FS 720
discs.
salts
were
prepared
by
the
direct
in MeCN
/toluene
or MeCN/xylene
reaction mixtures.
of cis-M
429
procedures
are
significant
given
for
variations
one
molybdenum
in experimental
Ph4P[MoC1(CO)_phen]. Mo(CO)4phen in refluxing product dried
4:l
was
Yield
in vacua.
by similar
time
For
of 4 h. was
the
(5 mmol)
product
was
in refluxing
filtered
analogous reaction 1:l.S
time
for
and
the
Preparation
of
The
washed
for
was
heated
with
Complexes complexes ratio
of 1:3
R4Z[MX(CO)3L2]
(10 mmol)
(1 mmol)
(0.2
h for
MO and
the
solid
product
was
filtered
off,
washed
with
Ph
known
of
gc
2) crystallised
to stand
L2
in over
Preparation
XIII
a
divided for
water, were
the
8 h.
then
The
methanol
prepared
1 required
at 0°C
complexes = bipy 80%
for
(10 cm3)
added
complete
(Table
in methanol
was
was
isolated
and
prepared
in an
a 16 h.
and
iodo-complex
chloro-analogues.
reaction
X = Cl or Br;
and
were
finely
(40 cm3)
for
the
The
with
in Table
When
allcwed
XII
ma~ol)
the
methanol
V (Tablel)
XIV-XVI
halide
was
(1.5
[Mx(c~)~(T~-Rc~H~)L~]
complex
XXIV
cold
ice-cold
of ally1
Complex
Ph4PCl
On cooling,
1 h.
IV and
and
below.
with
of complexes
rapidly
remaining
and
reacted
xylene/acetonitrile
a M(CO)4L2:R4ZX
bromo-
noted
a little
II,
(1 mmol)
Yield 93%. The
manner.
with
synthesis
8:l
off,
end dried in vacua.
was
complex,
necessary.
Et4N[WI(CO)3bipy-j.W(CO)4bipy Et4NI
rapidly
tungsten are
(40 cm3)
Complexes
97%.
procedures.
reaction
(1 mmol)
washed
off,
one
details
toluene/acetonitrile
filtered
and
only
slowly
72 h prior
yields
by
at ambient 1.0
and
the
where
M = W, X = Cl or
this
temperatures.
h for W compounds),
methanol and
solution
dried
reaction
in vacua. --
mixture
to filtration.
[MX(CO)2
to a stirred
Li'j~ bipy,
I [11,12]
were
M = MO,
all
procedure.
[MoBr(CO)2(r13-cyclohexenyl)bipy]
MoBr
3-bromocyclohexene
CO.5
(5 mmol)
(complex
XXII,
Table
vacua.
Yield
42%.
2) was The
mmol)
was
added
in CHC13
(5 cm3)
filtered
off,
corresponding
to a deoxygenated
at -15@c.
washed
with
phenanthroline
The CH2C12 anion
solution
product and
dried
reacted
3
in an
of
431 analogous
manner
oxidised
and
but
could
the
not
h3 -cyclohexenyl
be obtained
derivative
so
formed
in an analytically
pure
easily
was
state.
and discussion
Results
Tricarbonyl anions [MX(CO)3L2]The anionic yields
as deep
to reform were
most
and
of
purple
the
as
Sparingly
were
which
the
1 were
which
all
slowly
decomposition
data
were
in high
decomposed
on standing The
solvents
by coordinating
confined
obtained
products.
in non-coordinating
solvolysed
spectroscopic
of stoichiometry may
ligand.
should
stretching
give
exist
rise
Such
state
complexes
as
solvents,
to solid
the mer-isomer
case
three
strong
bands
are
expected
show
three
strong
CHCl 3 and
consequently
measurements
this
L
2
was
these
complexes
the
no evidence
on dissolution
NMe4[MoI
and
constant
Cotton-Rraihanzel
are
and
of
as
for
the carbonyl
as modified
by
anionic
state
forlner
and
two
and
in solution assigned
temperature
the
with
carbonyl
species
of any where
halide stretching
were
discernable.
the anion previously
a
the anions
solutions
saturated
strong
discussion
[M(COj3(MeCNjL2],
of
reported
in any
of
for
[9].
anions
Dalton
under
and
mer-isomerisation in MeCN,
weak
of MeCN
In MeCN
the
in the
consequently
spectra
of
be distinguished
one
at room
be retarded
both
carbonyl
since
solid
[Ni
data
method
and
[14].
solvolysed
of -fat-to
31,
solvents
could
may
anions
characteristic
or phen
reaction
in the
forms,
terminal
whereas The
infrared
features
= bipy
of both
There
Thus
showed
solvolytic
frequencies
[13].
is a bidentate
isomeric
measurements,
absorptions
solvents
L2
fat-isomer
predicted
latter
carbonyl
solvolysed.
or W and
are
In coordinating
the complexes
I = MO
the
two
the
intensity
absorptions for
of
where
infrared-active
In general
fat-configuration. quickly
in either
by band
in non-coordinating
[MX
to three
vibrations.
from
ion,
solids
of
soluble
in Table
3).
chelating
of
one
immediately
Complexes
were
listed
crystalline
cis-M
at most
CH2C12
complexes
were
et al.
calculated [15].
by
the
In previous (Continued
on p.434j
(XXIV)
all
38.0 (39.5)
78
txxrrr)
b
Known complexes
on Nojol
44.8 (43.4)
89
(XXII)
LMoBr(CO),(TJ-C,H,)bipy]
a Recorded
47.1 (46.1)
42
(XXI)
[MoBr(CO)2(q-l-MeC3H4)bipy]
[WCl(CO),+2-.MeC,H,)bipy]
42.2 (43.4)
82
(XX)b
46.7
mulls,
83
bands
(48,2)
[MoBr(CO)2(q-l-MeC3H4)phen]
90
(XIX)
86
C
[MoCl(CO),(U-2-MeC,H,)bipy]
)b
(%)
(XVIII
Yield
[MoC1(CO)2(‘I)-2-MeC3H4)phen]
Complex
are
strong
G)
unless
N
otherwise
Elemental analysis found (calcd.) (%) H
ANALYTICAL AND SELECTED INFEARED DATA FOR THE COMPLEXES [MX(CO),(q-allyl)L,]
TABLE 2
noted
1918
1928
1920
1920
1925
1925
1923
*1
Infrared v(c-o)a
1841
1840
1838
1831
1838
1636
1847
B1
data
(cm-l)
268
164
166
164
168
267
266
v(M-X)
433
TABLE
3
SELECTED
INFRARED
Complex
V(h+X)
AND
FORCE
(G-1)
CONSTANT
-1
v
FOR
A"
1765
1742
1880
II
146
1886
ANIONS
Carbonyl constants
A'
227
CARBONYL
1
Ai
I
III
DATA
K
1751br
force (mdyne
b 2-l)
Kc'
KI
K2
0.59
0.60
12.9
13.4
0.50
0.70
12.9
13.4
c
1884
1764
1742
0.60
0.63
12.9
13.5
IV
227
1887
1769
1748
0.59
0.62
12.9
13.5
V
153
1886
1772
1751
0.57
0.60
13.0
13.5
1884
1763
1740
0.61
0.63
12.8
13.5
VI VII
234
1874 1880
1764 1760
1743 1743=
0.55 0.56
0.57 0.62
12.8 12.8
13.4 13.4
VIII
147
1874 1880
1766
1743br 1745c
0.48 0.57
0.68 0.59
12.8 12.9
13.2 13.4
1746br
o.i7
0.67
12.8
13.3
1875
IX X
230
1877
1763
1743
0.56
0.59
12.8
13.4
XI
158
1867 1879
1753 1758
1736 1742c
0.54 0.56
0.60 0.63
12.7 12.8
13.3 13..4
XII
229
1879
1763
1719
0.53
0.75
13.0
13.5
XIII
222
1884
1766
1737
0.45
0.64
13.2
13.7
XIV
129
1900 1892
0.59
177?
xv
129
1899
XVI
127
1870 1881
XVII
125
1877
Recorded Calculated Solution
data
0.60
0.63 0.64
13.0 12.6
13.6 13.2
1756br
0.51
0.72
12.7
13.2
0.64 0.51
0.62 0.62
12.8 12.9
13.5 13.4
0.74
0.60
12.7
13.4
1747 1762
1726 1752= 1737br
on Nujol by
1778br 1751c
the
mulls
unless
procedure
in CH2C12
otherwise
given
indicated
in ref.15
434
studies Lewis
of cis-L -2 base
used
and
in such
K2 greater expected
M = go
derivatives,
3
from
where
or W [14,15],
calculations,
than
complexes
YM(CO)
the
resulting
the
equatorial
simple
n-bonding
cis-MnX(-CO)3L2
L = bipy
assignment
in axial
CO stretching
A'
>
force
A**
force
constants
However,
an electronegative
Y = monodentate
A' >
CO stretching
considerations_
containing
or phen,
as
some
halide
been
constants
$,
for
has
manganese
ligand
X *'i
becomes
larger
intermediate under of
than
frequency
consideration
this
band
order
force
but
Kz'$'
that
A' >
and
hence
the
calculated
magnitude
interaction
possible
VII
based
on
the
alternative
stretching
seems
3 with
Kc =-, Kc
constants<6
assignment
and
in Table
given
at
derivatives
possible
yielded
to those
band
VI complexes
Group
considered
calculations
to the
Group
neutral
were
also
divergent
assigned
the anionic with
These
second
nor
'i
tungsten found
to
these
complexes,
of
these
Group
charge
on the
significant
for
less
as
likely
low
as
than
varies Thus
probably
central
atom
Lewis
and
complexes
was
found
M-X
stretches
complexity
of
of the
Y = monodentate
On ally1
The
for
far-infrared each
of
of the
oxidation, in their
difficultto
base
throughout
effect
pentacarbonyl of
effect
the molybdenum
where
halides the
into
halogen [18]
increased
not
the
where
extend
increased
compared or phen
cis
radii
results
constants
fac-MX
does
of
or W. L2 = bipy
and
on the
covalent
C 2~? orbitals
force
M = MO
~ld,lS,lS]
of the
of back-donation
the anions
in a with
and
M = Mn
or Re
[16]. region
the anions corresponding
the M(I1) far-infrared
assign
marked
CO stretching
fat-MY(C0)3L2,
In the
the
as a result
VI elements.
X = halide,
significantly
2
the manganese
decrease
neutral
K
series.
Co group
more
were
A'.
widely this
Since
been
tabulated.. Neither
many
constants )
has
assignments
of a similar
with
mode
isoelectronic both
A"
constants
0.331,
are
force
the A"
Cl+17-J.
stoichiometry,
consequently
or
K2 and
with
only (Table
a single 3),
strong
at even
halopentacarbonyl
derivatives
so
spectra
and
confidence.
The
lower
wavenumbers
anions
formed M-X
halogen-sensitive
showed
stretching
most
halogen
[MX(CO)5)an
band than
the
c20].
increased
frequencies sensitive
were bands
435 the
in
entire
Table
2 and
are
tentatively
agreement
with
the
v
ratio
spectra
infrared
data
the
: v(M-Br)
frequencies
Ally1
at
derivatives The
halides
at
room
are
139
-1
cm
anions
given
in
are
in good
derivatives
with
thatof
were
show
are
also
strong
the
[Zl]
parent
examined
and anions,
to
stretching
W-I
respectively.
listed
temperature 'Ihis route
complexes
in Table
or below
1 reacted
to give
is particularly
to prepare
difficult
molybdenum
phosphine
closely
I and
XXIV
[?d~(~O)2(~~~-allyl)1.2]
carbonyl
derivatives. which
and
ditertiary
Br and
-
These values
[WI(CO)2
X = Cl,
137
XVIII
as v(M-x).
correlates
and
series
complexes
assigned
on analogous
[WI(CO),(?i-C3H~)bipy] c complete
of
by
[11.12]
due
the
high
useful
slow
yields for
procedure
to the
readily
ally1
of M
the
tungsten
normally
kinetics
with
analogues
adopted
for
and
competing
and
XIX
the. reactions
_ of the
tungsten
sufficiently showed due
intermediates.
soluble
singlets
to the
8.25(d). ally1
for NMR
at
6 1.01,
n3-ally1
group,
8.06(t)
methyl
and
group
Only
measurements.
1.40
and
and
7.61(t)
ppm
The
caused
by
is even
greater
(6 0.70
related
complex
[Mo(NCS)(CO)2(?l-2-MeC3Hq)phen]
shown
to lay
solubilities precluded' CkC
of the their
stretch
this
members
the
and
plane
of
the
complexes
solid-state
with
mechanisms halides
of
complex
this
methyl
in Table
2 in suitable.
XVIII
structures
and
and
XIX
shift
closely
group
[22].
The
has
low
NhlR solvents
of an uncoordinated their
and
[22,23]
the
the
In the
ligand
oectra
of
effects
ally1
the absence
3:2:2
6 8.79(d),
shift
aromatic
infrared
known
at
group). the
latter
ratios
up-field
shielding
were the
intensity
absorptions
methyl
but
to complexes
at -57OC
phenanthroline
the ally1
characterisation.
q3-ally1
related
for
remaining
stoichiometry of
the
similarity
Various ally1
full
in their
spectroscopic of
over
corresponding
the
ring,
ppm
with
pronounced
aromatic
been
in the
2.39
ppm.
XVIII
In SO2
2,2'-bipyridine
is no doubt
and
complexes
to
general other
indicated
complexes
they
were
also
series. have
been
proposed
to low-valent
for
transition
the
oxidative
metal
addition
complexes,
of
including
436
nucleophilic [241p
attack
a concerted
and
initial
step
[27].
ally1
of
the metal
insertion
coordination Strong
mechanism
of
the
a-C
atom
thp
anion
subsequent
of
the
evidence
that
or direct halide
of halide
carbon
[25], to the
atom
bearing
a radical metal
chain
as
the
the.balogen process
rate
last
mechanism
is operative
has
been
presented
recently
(B), in
would
attack
in the A
[28].
metal
atom
on
explain why the halogen in
the P(II)-ally1
occurs
of the
[ZS]
determining
this
nucleophilic
retained
is initially exchange
e:C
systems
ally1
the
reaction
halide-IrX
similar
at
in some
products,
instances
although
in solution
on
standing.
A
+
[Mx(co)3L21-
CH2=CH-CH2Y
-
[(YcH2cH=CE2MX(co)2L2]-
I cMX(co)3L2]-
+
c!B2=CR-CB2Y
-
'co
fast
mwo)2L21 + y-
[ (R-C3H5
B
+
~~cH~=C~-CB~)MX(C~~~L~I
+
Y-
fast I [&C3"5MX
Attempts have
proved
to identify
unsuccessful
positively
so
either
of
these
+
reactive
CO
intermediates
far.
Acknowledgement We
thank
the
S.R.C.
for
the award
of a Research
Studentship
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