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Dimethylplatinum(IV) compounds. V. Preparation and reations of bis(salicylaldehydato) complexes
121
Joumol of OrganometalIic Cizemistry, 161 (19’78) 121-138 0 Elsevier Sequoia S.A., Lausanne - Printed inThe Netherlands
DIMETHYLPLATINUM(IV)
COMPOUNDS. V. PREPARATION AND
REACTIONS OF BIS(SALICYLALDEHYDAT0)
J.R. HALL
and
COMPLEXES
G.A. SWILE
Department of Chemistry, University of Queensland, Brisbane, Australia 4067. (Received
July
17th,
1978)
summa ry
Two geometrical
isomers of Pt(CHa)2(Sal)2 have been prepared and Some reactions of isomer A (phenolic
identified by 'H NMR spectra. and
oxygen atoms traj?s to CH3)
isomer
6
(aldehydic oxygen atoms t?%??s
Isomer B reacts with CgDaN to produce species
to CH3) are reported.
containing unidentate Sal in
while
solution,
Primary amines react with isomer
with formation of hydroxo species. B to form salicylaldimine
isomer A tends to lose Sal
complexes.
isomer A reacts with en to form
Pt(CHa)zen(DH)z.
Introduction Although a large range of f3-dicarbonyl complexes of both trimethylplatinum(lV) far
less
was
prepared
dimeric [g,lO]
[i-6]
and dimethylplatinum(lV)
work on salicylaldehydato
with
by
reaction
bridging
of phenolic
[7-81
complexes.
[Pt(CH3)31], oxygen
with atoms
are kno.,:n,there has been
A compound of formula R(CH;)3Sa' TiSal
both
in
is]
and k/as
the
solid
found
to
state
and in solution [ll], but no reactions of the compound were
reported.
In the dimethylplatinum(lV)
system only the compound
Bur+N[Pt(CH3)2Br2Sal] which is monomeric with Sal tzw?s to CHa groups has been reported 1121. geometrical
In this
paper
we report
the
preparation
of
isomers of formula Pt(CHa)2(Sal)2 and a number of reactions
be
122 these
of
have
compounds with
been
Results
reported
pyridine-dg
amines _
Preliminary
results
[8].
and Discussion
E'nzparatioz
and
identijYca-t;icn -L
Pt(CH3)2(0H)2-2H20 from
and
such
solutions
isolated.
The
is
in
soluble
decomposed
dissolves
a compound
product
is
organic
of the
in boiling
of
formula
by 95% ethanol
or
such
as
aqueous
salicylaldehyde
Pt(CH3)2(Salj2
an orange-yellow
solvents
Pt(CH313(SaZ)7
compozmds
may be
crystalline chloroform
acetone
and
to
and
reform
solid
which
benzene
but
the
hydroxo
cdmpound. Assuming three
bidentate
geometrical
salicylaldehyde
isomers
are
and &s-methyl
possible
for
Pt(CH;)2(Salj2
Fig. 1. Isomers of ci.s-dimethyl-bis(saJicylaldehydato),olatinum(IV),
The
‘H
NMR spectrum
presence
of
only
resonance
(with
and
(I
ruled
lg5Pt out
one sate1
= %,
since
of
for
the
isomer li tes
compound since due
34% abundance)) this
isomer
in
only
CDC13
is twc
(Fig.
a single
to coupling
groups
non-equivalent
(see
present,
Fig.
Pt(CH3)2(SaI)l_
2a:
indicates
the
methyl-platinum
between
observsd.
are
the methyl
Isaner
protons
C may be
methyl-platinum
-* The compound Pt(CHsj2 (OHj2;2H20 has been reported f rem the reaction df [Pt(CH3)2Br2] with NaOH ES]. Subsequent preparations indicate that freshly pre;ared samples approach this formulation, but there is loss of weight with ageing and the compound is probably better described as Pt(CH3)2(OH),nH,O(n=l-2).
lj
_
123
I
,
I
I
Fig. 2. ‘H n.m.r. spectra of Pt(CH,)Z(Sal)2
resonances to
the
influence
positions
of
Hz,
Table
atoms
trall.s
trmzs
to
to
phenol
CH3 tim?s
1)
in CDCI,;
(a), isomer A and (b), isomer B. *ThIS.
to
to
salicylaldehydato This
value
8 of
Fig.
is
phenolic
of the
(74.1
the
to
be
compared Hz)
be
expected
atoms
in
the
coup1 ing
wi th
appears
when
donor
would
presence more
with
and
constant
aldehydic
trays
observed
of
oxygen
consistent
the
due
donor
with
CH3
obtained
valties
Hz)
(78.6
in
[12]. Table ligands
substantially
1 (where
of tent
and
i c oxygens
BubN[Pt(CH3)2Br2Sal] Reference
consis
CH3 [13]
constants
types
magnitude
is
I
8
r
coupling
different
The
1131.
(72.4
for
different
with
’
I
6
1
4
2
0
the
1 shows
that
the
to
lg5Pt
couple higher coup1 ing
than
would
aldehydic with that
protons
of
the
a magnitude
of
121 .O Hz.
expected
be expected
to
for
either
be of
the
isomer same
124 TABLE ‘ii
1
NMR SPECTRA OF ISOMERS CF Pt(CH3)2(Sal)2
AND THEIR
Pt-CH3
P t-O=CH
Compowd r
T
J
REACTION
PRODUCTS
P t-N=CH *
J
Pt-N-CHs
J
T
J
In Ifi-dichlorobeozene Pt(CH3)2(Sal)2
In
A
a.13
72.5
B
8.12
77.5
C
8.07
77.2
a.23
72.7
A
8.23
72.4
1.83
B
a. 13
16.3 15.9
CDCl?
Pt(CH3)2(Sa1)2
Pt(CH3)+al
(Sal=N-CH;)
77.5
0.62
8.31
79-I
0.67
121.0
1.89
22.0
6.61
8.7a
1.95
22.5
6.67
9.1 6
I.83
19.6
6.58
y-1'
8.55
67.1
Pt(CH3)2(Ss1=N-CH3),
8-66
68.4
Pt(CH3)2(Sal)
a. 14
78.7
8.44
68.5
8.49
68.4
2.04
22.2
a.55
70.4
1.90
19.2
(Sal=N-C6Hs)
(Sal=N-CH?)
Pt(CH3)2(Sal=N-C6H5)
Pt(CH3)2(Sal)2,S
+ en:
Ini tiai Products:
8.32
78.8
a.52
66.6
a.&0 a.52
66.6
Major
8.64
68.6
Minor
8.65
69.0
Major
Minor
Final
In
Products:
79.1
0.68
15.4
1.83
Igd
0.61
15.2
1.93
20'7
1.92
21.2
c
CDCI~-CSD~N
Pt(CH3)2(Sal)2C+$~
Pt(CH3)2(Sal)z(C~DSN)~ Pt(CH3)2(Sal)
(CSDSN)OH
Pt(CH3)2(CSD,N),(OH), In
16.0
0.78
a.025
77-
a.57’i
71.6
-0.62'~
-
8.07
71.4
-0.48
-I
1
17.2
0.62’
8.3+
73.2
1.46
8.49:
72.0
O.Oy'i
8.63
71.8
8.87
70.7
76.2 -
D,O
Pt(CH;)zen(DH)z
(L d 5
3J (CHj-N=CH)
1.2
Error
’
~1
Slight
50% by
Hz.
Hz. Region
downfield
shift
g
Slight
volume. 50%
increased
to
increased
to 50%
’
by volume. by
volume.
1.4 Hz.
3J(CH3-N=CH) complex,
(3-4
Hz)
upfield IL
only as
peaks
(2
move5
Hz)
as
1.3 Hz.
identified.
CSDsN concentration
shift Peak
major
3J(CH3-N=CH)
=
increased
to
CsDSN concentration
to T -0.73
as CSDSN
concentration
125 order
as
[14]
since
Fig.
1
when
allowance
with
that
found
the
is
methyl
can
for
with
only
isomer,
be
[16].
found
it
for
assigned
to
heating
not
the
and
and
reactions
metallic
reported
this
below
for
more
orientation been
compounds
to
a particular
with
the
found
consistent
results
that
Hz
those
compound
can
be
1. is
indefinitely
stable
boiling
according
are
Hz
assignment
these
the
121
I)
of
of 40
in alken$lplatinum(l
unequivocal
compared
15 and
a favourable
al though
of
are
have
solvents
dicyclopentadiene
is
of
0
coup1 ings
couplings
evi dence, an
Fig.
terms
of
isanerA
of
the
CH3NH2
Hz)
be expected
influence
value
large
comparison
high
new species
the
to
usually
results
lH
dependent
such
in
the
by
state,
tetrachloroethylene,
in
the
formation rate
The
temperature
accompanied
solid
as
NMR spectra.
on
the
of
of
of formation
reaction,
some
decomposition
m-dichiorobenzene
solutions
to
platinum.
Accord (Table
i ng
l),
three Two of
Hz)
at
remain from is
in
than
was made The increased
NMR spectra
these
equal
species
isolate
third in
to
one-third
with
be
of
(T
8.07,
throughout
the
the
appear
J 77.2
C of
total
Fig.
species
during
Hz;
reaction
non-equivalent
isomer
T 8.23, and
methyl
1 in
but
the
so
J 72.7 probably This
groups.
was
never
solution
and
present no
attempt
it.
methyl-platinum intensity
resonances
resonances
intensity
postulated
to
of
new methyl-platinum
a single
species more
‘H
to
reaction.
arise
by
in
new species
these
Similar
compound
m-dichlorobenzene
of
in
above
A of
isomer
high
or
might
, where
CH3 and
(22-27
CH$
Hz)
tiqar?s 3+
to
to
( 0, 60
abnormally
isomer
solutions
several
tia7z.s
smaller
trans
allow
only
other
Al though
value
rationalized
The
is
the
is
case
H couplings
A.does
and
each
the
H groups.
Hz)
isomer
for
The
Pt*=C-
(120-148
[pt(CH,),Br,Sal=N-RI-
higher
protons
Pt-O=C-
trails
complexes
*[Pt(CH3)2(CH,NH2)4]-
[ 151)).
coupling the
made
(cf.,
respectively
of
in
a somewhat
[13]
methylamine
the
coupling
(where
CH3
in
as
resonance the
reaction
(T
8.12,
proceeded
J 77.5 and
was
Hz)
gradually
ultimately
126
the only such resonance present. species
a yellow
solid
analysing
From solutions containing this for Pt(CHx)z(Sal)z was isolated.
This
solid is soluble in chloroform and benzene and, in contrast to the previous
isomer, dissolves in ethanol and acetone without decomposition.
The IH NMR spectrum of this isomer in CDC13 is shown in Fig. 2b. The NMR data (Table 1) are consistent with this compound being isomer B of Fig. 1.
A single methyl-platinum
resonance is observed
with a coupling constant of 77.5 Hz consistent with CH3 trazs to oxygen donors [13] while the salicylaldehyde with lg%t
aldehydic protons couple
with a magnitude of 16.3 Hz, comparable with the coupling
of the aldimine proton in
[Pt(CH3)2Br2Sal=N-R]-
[lb].
It
may be
noted
that for this isomer there is no enhanced coupling of the aidehydic proton to lgsPt. Since the magnitude of the coupling constant gives an indication of tend strength
[13] it would be predicted that the coupling
constant of a methyl group i=rans to an aldehyde group as in isomer B would
be greater
than
that traisz to a phenolic oxygen as in isomer A.
The couplings observed for the two isomers (77.5
Hz for isomer B;
72.4 Hz for the initial isomer) tend to confirm that the initial isomer is isomer A.
Reactions of the compounds Pt(CH?)T(Sai)q
When CsDsN is added dropwise to a CDC13 solution of isomer B, two new methyl-platinum (Table
1).
resonances appear in the NMR spectrum
These resonances are of equal intensity and are presumably
due to a single species with non-equivalent methyl groups.
The
coupling constants, 71.6 and 77.1 Hz are consistent with methyl groups t~ans to CgDgN and an aldehydic oxygen respectively, so that
:‘:
CsDsN rather than CsHsN resonances to be observed.
was used to enable the aldehydic proton
127 the
species
and
one
is
unidentate
The
ligand.
presumed
to
be Pt(CH3)2(Sai)2(CSDsN)
the
(via
aldehydic
phenol
proton
ic
region
oxygen
atom)
supports
with one bidentate
sal
the
icylaldehyde
presence
of
such
a species since two separate resonances are observed, one at T 0.62 (J 17.2 Hz) which is attributable
to CHs and a second at ~0.62
group zkans
fi rst
to bidentate Sal with the aldehydic
and shows
no evidence
for
which
is broader than the
coup1 ing with lg 5Pt.
There
is
apparently an equilibrium between isomer B and this species
since
there
addition
is
still
an
appreciable
amount
of
isomer
B. present
on
of more than two moles of CsDsN per mole of Pt(CHs),(Sal),.
There
is no further change in the spectrum on allcwing the solution to stand.
On the other hand,the relative amounts of each species are
altered
by Further
changing
the
addition
concentration
of
Pt(CH,),(Sal)2(CsDSN),
CsDsN
of
results
slight changes
CDC13. in
in
increased the
formation
chemical
shifts
of of
the
methyl and coordinated aldehydic protonsand a more marked downfield shift of the free aldehyde proton which also tends to sharpen. Continued addition of CsDsN results in the formation of a new species with only a single methyl-platinum
resonance (T 8.07, J 71.4 Hz)
which is postulated to be Pt(CHs)2(Sal)2(CsDsN)2 trcvzs to CH3 and two unidentate salicylaldehyde
with CsDsN
(via the phenolic oxygen atom)
ligands. A single.sharp
resonance (T - 0.48) appears
in the aldehydic proton region with no evidence for coupling with 19Spt.
Further addition of CsDsN increases the amount of this species
at the expense of Pt(CH,)2(Sal),(CsDSN) species is present.
until only the bis pyridine
On allowing such solutions to stand for several
days decomposition apparently occurs,since
the colour of the solution
becomes deep red and the NMR spectrum shows a large number of new peaks in the methyl-platinum
region.
When a solution of isomer A is treated dropwise with C5D5N, two new methyl-platinum
resonances appear in the NMR spectrum.
The
resonances are of equal intensity and presumably arise from a single
128 species
with
constants tiazs to
observed
to
CsDsK
stand
in
platinum, isomer One
second
Two
position
cis
is
present
at
~0.09
chemical
(T
the
methyl
than
which
is
probably
shift
is
almost
the
more
species
yields
large
The due
0.06).
The
likely
from
121.0
with
the
Hz
in
in each
in isomer
arising
a change of
this
further
with
resonance Furthermore,
the
pattern
found
in
ligands
have
probably
of
aromatic
its
salicylaldehyde solution
could
with
CsDsN or
formulation containing
this
infrared
the
coordinated
species
is
orientation
spectrum. aldehyde
also of
effect
a second 8.63,
consistent the
would
region
to
of
the
sat icylaldehyde. and
the
solution
OH and CsDsN as
to
J 71.8
aldehyde
not
the
(Table
1)
aldehyde
proton
increases
in
spectrum
resembles
the
This
indicates
methyl-platinum for
give
a solid by
Hz)
exhibiting
T 0.06)
Support
confirmed
species
CSDSN while
(shifted
displaced
the
singlet
the
influence
(+
I%ZV_S to
Pt(CH3)2(CsDsN),(OH),_
by evaporation coordinated
been
a trazs
be
in a
a sharp
in
latter
this
can
salicylaldehyde
(CsDsN)OH
of
a particular
resonance
previously
free
in
and
platinum
for
solutions
constant
species.
since
present
of of
second
bidentate
in
mole
expense
Hz)
is
solution
magnitude.
CH3 groups
observed
of
Hz
the
the
per
the
to
found
The
CsDSN produces
methyl-platinum
consistent
76.2
from since
of
atom.
coupling
A to
that
OH vibrations
with
the
one
Pt(CHs),Sal
evaporation
compound,
Addition a single
since
a product
coupling
in
oxygen
for
bonded
species
or
at
salicylaldehyde
with
CH3 groups
CsDsN
resonance
free
to
lq5Pt(76.2
that
second
to
of
present
with
so
identical
(T
moles
group
groups,
aldehydic
decrease
are
coup 1 i ng
On allowing
increases
coupling
[Pt(CH3)zSal(CsDsN),If to
two
gradually
compound.
The
respectively.
more
shows
the
appears
result
of
groups.
may be assigned
on an aldehydic
solutions
OH ~&ES
group
i c oxygen
in
be either
Hz)
resonances
1.46)
to
73.2
species
a proton
similar
The
and
aldehydic
resonance to
(72.0
presence
this A.
methyl-platinum
and phenol
the
assigned
in
non-equivalent
IR.
this
that
The
both
species
is
formulation
containing compound
intensity.
Sal
most is
obtained
both is
however
129
unstable
and
When
loses
a one
Pt(CHS)2(Sal)2 a
new
species
CsDsN
to
form
Pt(CH3),(DH)2nH20
mole ratio of methylamine (isomer 6) in
CDCl3
there
on
standing.
is added to a solution of is
an
immediate
formation
of
two noll-equivalent methyl-platinum groups as
with
evidenced by the presence of two methyl-platinum equal intensity in the NMR
spectrum
(Fig.
resonances of
3a).
The
spectrum
can
be
i i Fig. 3. Pt(CH,)2(Sal)2
(isomer
(b) 2 mol of CHxNHI.
*TMS.
l
I
I 4
I
2
6
interpreted
in terms
of
!
B) plus (a) 1 mol of CHlNH2;
the
I
-r
structure
in Fig.
4A
(R=CH3),
platinum which
resonances are
consistent
Thus
have coupling constants of with
CH3
trajzs
to
an
79.1
aldehydic
the
where
and
iigands
two 67.1
oxygen
methylHZ (cf.,
I
10
8
methylamine has condensed with one of the salicylaldehyde to form an N-methyl salicylaldimine complex.
,
I
I
6
(Table 77.5
11, Hz
130
B Fig. 4. Structures CH,NHz (B)
in
of the reaction
isomer B) and txizs
products
to
of isomer B with one mol of CH,NH?
group
an aldimine
Ph,As[Pt(CH,),Bt-,Sal=N-CHs][l41).
(cf., 67.1
with lq5Pt (Fig. 3a).
together with sate11 ites
The
in
The N-methyl resonance consists of
a central doublet due to coupling between the CH3 proton (3J(HC=NCH3)1.2Hz)
(A) and two mol of
magnitude
of
this
latter
group due
and to
the
imine
coupling
coupling
(8.7 Hz)
is somewhat less than those found in M[Pt(CH3)2Br2Sal=N_CH31 (13.0-13.2 Hz)[14] and [Pt(CHs)sSal=N-CH3L)
(14-16 Hz) [17] indicating
a weaker Pt-N bond in Pt(CH3)2(Sal)(Sal=N-CH3).
This is supported also
by the magnitude of the coupling of the aldimine proton with lg5Pt (22.0 Hz) which
[141.
is less than that in Bu4N[Pt(CH3)zBr2Sal=N-CH3](26.4
Hz)
The aldehydic proton couples with lg5Pt with a magnitude of
15.9 Hz, which is of the same order as that found in isomer B (16.3 Addition of a two mole ratio of methylamine to a CM13 of Pt(CH3)2(Sal)2
Hz).
solution
(isc;nerB) immediately produces Pt(CHS)2Sal(Sal=N-CH3)
as for a one mole ratio.
However, on allowing the solution to stand,
formation of a new species, whose spectrum is shown in Fig. 3b, occurs over a period of about 30 minutes.
The spectrum indicates that the
compound is the bis (N-methylsalicylaldimine) is shcwn in Fig. 46 (R=RI=cH,).
compound whose structure
Thus a single methyl-platinum
resonance is observed with a coupling constant of 68.4 Hz, coupling
of
lg5Pt
proton
(22.5
in
compound
the
Hz)
with are
both of
the
Pt(CH3)zSal
the same
N-methyl order
(Sal=N-CHs).
group as
is
(9.1 found
Hz) for
while
and these
the
aldimine
couplings
131
Although a second mole of CHsNH, reacted quite readily with Pt(CHs)$al(Sal=N-CHs)
as shown above, an attempt to react the latter
species with a-methylbenzylamine
was unsuccessful since no apparent
reaction occurred after heating for 10 hours at 55'C. Reaction of isomer B with a two mole ratio of aniline was extremely slow at room temperature but at 55'C reaction occurred over a period of 3 hours to produce a species whose NMR spectrum was consistent with Pt(CHs)2Sal(Sal=N-CsHS)
(Fig. 4A, R=C6HS).
Thus two non-equivalent
resonances are observed with coupling
methyl-platinum
constants
of
78.7 Hz (tram
to aldehyde group)
Roth aldehydic
6.0 Hz) and aldimine (T 1.83, J 13.6 Hz) (T 0.78, J 1'
protons were observed
and
e 1). (Tab 1'
6815 Hz (trans to aldimine group).
The larger value of 2J(1g5Pt-CH,) t?mls
to N and the smaller value of 3J(1g5Pt-N=CH) compared with the values in Pt(CHs)zSal (Sal=N-CHs) consistent
compound, of
the No
aryl
group
attempt
with
i ndicate a weaker Pt-N bond in the former the
greater
electron
such
a
(Sal=N-CsHs)
reaction. with
was
made
to extend
the
5:
However
CH,NH,
, reaction
reaction
to the
formation
of
extreme
in
view
of
a solution
the
of
of
the
sladness
Pt(CH3)zSal
proceeded at a reasonable rate with the reaction
being complete after 6 hours at 55'C. Pt(CH3)2(Sal=N-C6HS)(Sal=N-CH3) 'H NMR.
properties
[lb].
bis (N-phenylsalicylaldiminato) compound of
- withdrawing
Two methyl-platinum
The product of the reaction was
(Fig. 48, R=CH3;R1=C6HS) according to
resonances are observed with coupling
constants of 70.4 Hz (CHj trans to N-CsHS) and 68.4 Hz (CH3 trarrs to N-CHs) and two aldimine proton resonances at T 1.30, J 19.2 Hz (EC-N-CsHS) and T 2.04, J 22.2 Hz (H_C-N-CHs). Reaction of Pt(CH3)2(Sal)2
(isomer 8) with ethylenediamine
complex than the above reactions and the results more equivocal.
is more Dropwise
addition of en to a CDC13 solution of isomer B produces three new methylplatinum resonances in the lH NMR spectrum.
The intensities of these
7: Species of the type Pt(CHs)2(Sal=N-R)2 would probably be best prepared as has been done with by reaction of Pt(CH 3 2(OH) 2- nH20 with HSal=N-R H acac=N-R ligands [6].
132 resonances indicate that two species, each with two non-equivalent methyl groups are present in so ution in
the
approximate
ratio
of
2:1 with one
resonance from each spec es be ?g accidentally degenerate (Table 1). The magnitudes of the coupling constants indicate that for
each species
one CHS group is trcwzs to an a dehyde oxygen (78.8 and 79.1 Hz respectively) and one trczzs to an aldimine group (66.6 Hz for each). Each species exhibits one aidehyde aldimine (T 1.83 and i possible
structures
resonances
but
it
1.93
which is
(7 0.68 and;
respectively)
would
impossible
give to
0.61 respectively) and one Fig.
resonance. non-equivalent
assign
5 shows
two
methyl-platinum
structures
from
the
NHR spectra.
-NH2
B Fig. 5. Possible products of the reaction of isomer 'B with en.
Further addition of ethylenediamine produces two new species each with equivalent methyl groups truzs to aldimine ligands (Table I).
A
large number of monomeric, dimeric and even polymeric structures could be postulated with equivalent methyl groups so that the species cannot be identified by 'H NMR spectra.
The formation of insoluble material
probably indicates that polymeric species
have
form&d
in the reaction.
Reaction of Pt(CHs)2(Sal),( isomer A) with ethylenediamine immediate precipitation of a white microcrystalline analyses
for
Pt(CHs)2en(OH)2".
solid
results in which
The 'H NMR spectrum of this compound
in D20 exhibits a single methylplatinum constant of 70.7 Hz, consistent wth
resonance with a coupling
CHs group trms
to nitrogen donor
The same species may be prepared by reaction of Pt(CHS)3(0H)3-nH20 with en.
133 atoms
[131.
coordinated From
the
The
infrared
OH at
3591
filtrate
of
(u(OH)),
the
above
coordinated presence even
the
and
acetone.
(phenolic)
[Is],
1 i gands .
On the
appear
be
bonds
trms
this
other
the
reactions
(cSD~N)
formation
of
in
by
remain
the
intact
due
I3 the
and
such
in
the
and to
their
high
tzw:s
the
salicylaldehyde
groups the
involved
in
either
-
The
do not
Pt-0
suggests
formation
the
tend
of
(amines)
the
A)
groups
only
systems
by IR spectra.
OH groups
phenolic is
it are
during
of bis-
(isomer
to
that
of
to
(w(Pt-0))
ethylenediamine
methyl
due
cm-l
confirmed
by
CSDSN,
reactions
in
species
as
displacement
which
condensation
hydroxo
as
558
crystals
displaced
isomer
groups
and
peaks
Pt(CH3)2(Sal)2
positions
OH groups
methyl
in
complete
in
contains
(6(OH))
yellow
Since
trcrrzs
hand,
or
bonds
in
results
displaced to
(phenolic)
such
ethanol Pt-0
969
that
readily
ligands
compound
be obtained
are
of
influence
to
groups
and
can
indicate
a variety
aqueous
weaken
reactions
the
reaction,
imine
aldehyde of
989
above
(salicylaldehyde)cethylenedi The
of
spectrum
the
(aldehydic)
displacement lack
of
the
Pt-0
Schiff
base
complexes. Experimental Analytical
,
Z%epaz-atioiz
results of
for
Ptr (Cfiq)
9 (Sa ZI 7
Pt(CH,),(OH),*nH,O
and
the
several
heated
minutes
heating
was
required
evaporated
orange-yellow
solution to
plates
sample
solutions
the
sol
id
1ization. off,
compound
appears
remaining the
on
solid
addition
of
water
to The
washed to
unchanged
compound
in
The
was
are
bath
product,
after treated
Table
2.
sal icylaldehyde
the
with
solution The
the
and n-hexane form
and
of
air
indefinitely 4 months.
was
air.
chloroform,
volume
z-hexane
ml)
of
When
95% ethanol
added
orange-yellow
dried. in
ml)
after
orange
a stream in
in
(0.5
resultant
in
(5
dissolved
ethanol
The
a small
stable
in
usually
dissolved
with
be
listed
/.I
dissolution.
concentrated
filtered
of
1ine
are
suspended
boi ling.
ready
dryness
crystal
crystal
was The
one
to
was
although
for
fi ltered,
induce
to
compounds
(isonisr
(0.69)
mixture
sometrmes
the
the
Yield solid
chloroform or
aqueous
952.
state,
_
134 TABLE
ANALYTICAL
2
DATA
Empirica? formula
Compound
Analysis
(calcd, (found)) (%) H
C C1sHxeOri”t
B
Cl6H16gL;Pt
Pt(CHs),fSa!)(Sal=N-CH3)
Cl7HlsNu3Pt
ClaH2zN20zPt
PtfCH3)2(Sal=N-CsHs) (Sal=N-CH3)
Czd%.$WW’~
C4H16N202Pr
41.1
3.5
(41.2)
(3.5)
41.1
3.5
(41.2)
(3.51
N
4.0
2.9
(42.3)
(4-O)
(3-o)
43.8
4.5
5.7
(43.9)
(k-61
(5.6)
49.7
4.4
5-o
(49.7)
(4.5)
(5.0)
15.0
5.;
8.8
(14.8)
(5.51
(8.4)
42.5
acetane the solution becomes cloudy and the odour of salicylaldehyde becomes noticeable,
Evaporation of the solution and extraction with
chloroform leaves a pale yellow residue which has an identical infrared spectrum to that of Pt(CHs)2(0H)2*nHz0.
Pt(CH3)g(Sal)2
(isomer A) (0.5s) was dissolved in m-dichlorobenzene
(8 ml) and the solution heated to boiling.
Metallic platinum began to
precipitate from solution after 30 seconds but heating was continued for 8 minutes at which time the IiiNMR spectrum confirmed that only a single species was present in solution,. The solvent was then evaporated by heating on a water bath in a stream of air.
The residue was
extracted with chloroform, charcoal added to adsorb the colloidal platinum, and
135 the
solution
and
the
yellow
remove
all
stable
indefinitely
of
Several
both
of
NMR spectra
boiling.
Initial
amount
of
occurred
difficult
as
intractable
was
with
C.
Both
than
30-402,
increased
at
rise
to
no evidence
amount
the
expense it
On the
reaction.
dicyclopentadiene group to
which
platinum
in
Pt(CH3)2(Sal)z
of
the
of
z-hexane. to
appears
solutions
to
be
of
about
only
slower,
same
was
no
of
the
as
total
in
the reaction for
product
A similar
this
case
much
2 hours
evidence
the
formed. in
after
complete
isolation be
was
but
the
there
isomer
at
C was
the
expense
never
In
was result
there
was
at
shaded
to
of
dicyclopentadiene
an extent
greater
of
isomer 1 ing
isomer
C did
There
presence
A in of
in
was the
both
a free
may be
B
solvent,
throughout
isomer
isomers
al though
lower-boi
stage
species,
reaction,
present.
any
the
new
while
amount
species
tetrachloroethylene
h.!o
the
the
the
NMR spectra
the
of
constant
A.
total
both
present
fairly
that
the
in
A.
throughout
isomer
pyridine
(isomer
was
to
present
hand
reaction
the
Pt(CHs)2py2(OH)2.
appeared
Former
also
although
that
of
that
was
for
investigated
conversion
and
salicylaldehyde
other
were
dicyciopentadiene,
remaining
50% of
and suggests
in
tended
isomer
free
and
Hc+iever,
were
the
for
state
solutions
isomers
almost
solid
heating
decreased
tetrachloroethylene, fact
of
indicated
in m-dichlorobenzene
compound
complete
tars
and m-dichlorobenzene H and
The
With
formation
IH NMR spectra
i vo1um
necessary
tetrachloroethylene,
metal.
pyridine
substantial
sometimes
80%.
eventual?y
5 minutes
platinum
a smal
addition
Yield
formation
formed
of
to
by
is
solvents
With
B.
formation
also
boiling
reaction.
within
found
the
platinum
m-dichlorobenzene
precipitated charcoal
indicating
platinum
concentrated
acetone.
high
isomer
slcwer,
in
and
other
preparation
with
platinum.
ethanol
was
product
ization
traces
chloroform,
filtrate
crystalline
recrystall
A second
The
fi Itered.
aldehyde
coordinated
solution.
A)
(0.049)
was
dissolved
in
CDC13
(0.5
ml)
136 in the
an NMR tube. reaction 50:50
a stream
of
The
The
confirmed
Zeaction
to
as
during
spectra
which
an NMR tube.
lH
NHR spectra
extracted
6)
time
it
of
and
(isomer A solution
then
the
6)
(0.049)
of
CH3NH2 in
complete to
added.
product
more
amount
separated.
the
free
of
Pt(CH3)2Sal
than
methy!
after to
(isomer A solution
required
of
‘separated.
leaving
in a
spectrum. by
‘H NMR.
was
CDCls,
was
allcwed
to
to
deep
red
products
in
solution.
in
CDC13
treated stand
and
lH
for NMR
of
the
added
were
to
f i 1 tered
ml) until
The
product. to
solution
(0.5
dropwise
desired
concentrated the
2 moles
8)
(0.049)
of
CH3NH2 in
of
being
CHsNH2 per
estimated
resonance
was
of
by
a small
stand, off
NMR spectra
30 minutes
at
room
a beaker, the were
filtered
mole
of
to off
in
yellow
and
the
of
a small
stand
yellaEI air-dried.
dropwise were
the
the The
to
(0.5
until added,
resonances
formation
solution
was
volume
and
prisms
of
Yield
ml)
intensities
methyl-platinum
indicated
and
CDClS
platinum
comparison
temperature.
concentrated solution
dissolved
CDC13 was added
CH3NH2 and
_
These
CDCIS was
These
(Sal=N-CH3)
On allowing
dissolved
30%.
Pt(CHS)2(Sal)2 an NMR tube.
was
On allowing
of Pt(C~qJ3(Sa~=I?T--CA?I)7
added.
dryness
infrared
in
yellow
a beaker,
_Prepa.ration
transferred
to
complete
CsDgT
formation
Yield
product
and
was
confirmed
solution from
ai r-dried.
the
as
decomposition
transferred
n-hexane
of
slightly
its
dissolved
final
changed
reaction
chloroform
nH20 by
B) with
solution
evaporated
with
(O.Obg),
The
A.
indicated
was
crystals
in
was
the
of Pt(CH11~SaZ(SaZ=??T-C~91
in
volume
was
Cisomer
a number
Pt(CH3)2(Sal)2
solution
solution
to
When
Pt(CH3)2Sal(CSDsN)OH
isomer
indicated
P~epaxctioz
the
(isomer
for
dropwise
Pt(CH3)2(OH),-
of Pt(CH~)plSaZl~
CsEsN
3 days
be
added
NMR spectra.
lH
solid
contained
Pt(CHs)2(Sal)2 with
by
CDC13:CSDSN)
air.
solution
was
CgDgN
monitored
(approx.
residue
Neat
of
the
then
n-hexane the
95%.
product
137 Reaction
of P~(CHJ)~(S~Z)~ (isomr B) ~6th aniZi=e
Pt(CHs)2(Sa1)2 in
an
NMR
tube
The
solution
as
confirmed
9
hours
with
and
by
B)
a solution
initially NMR
of
Attempts
to
but
species
intractable
isolate
gums
in
The
to
the
form
on
added
solution
pure
evaporation
dropwise.
during
were
of
for
55’C
consistent
reddish
form
ml)
aniline
at was
became
in
(0.5
unreacted
spectrum
solution
CDC13
(1:lO)
and
NMR
product
in
CDC13
heating
whose
this
tended
line
dissolved
Pt(CH3)2(Sa1)2
(Sal=N-CSHS) .
Pt(CH3)zSal
ani
spectra,
a single
was
(O-039)
contained
lH
produced
time. as
(isomer
this
unsuccessful
the
solution.
Preparation of Pt(CH?l~/SaZ=N-CF;351ISaZ=il-CH~) To
a solution
des cr i bed one
mole
of
CH3NH2 of
hours
of
at
the
The
added,
filtration
and
z-hexane
and
were
and
the added.
fi
ltered
was
methyl
the
added
by
was
ai r-dried.
to
with
crystals
Yield
relative
complete
a beaker,
to of
After
formation
activated
concentrated
yel1o.d
until
resonances.
transferred
heated
as
dropwise
indicated
indicated
then
On standing,
prepared
methyl-platinum
was
solution
was
as
spectra
solution
and
CDC13
present
solution
yellow
off
in
and
NMR
reddish
(Sal=N-CGH3)
CH3NH2
platinum
temperature,
product.
After
per
of
methylamine
room
chloroform
Pt(CH,),Sal
a solution
above,
intensities 6
containing
the
charcoal.
a small
volume
product
formed
90%.
Reaction of Pt(Cli~~7lSaZl7(ison;er31 witi? ethyZenedim%ze Pt(CH3)2(Sal)2 an
NMR
After
tube the
and NMR
a solution
spectrum
ethylenediamine for
2
hours
was
then
which
filtered
to
filtrate
concentrated
a ye1 low
solid.
was
of of
solution at
a mixture
was
time
of
compounds
(0.039)
dissolved in
intermediates added
data
and
had the
for
to
amount
volume this
in
CDC13 been
soluticn
appeared
a small
a small
Analytical
was
ethyienediamine
reaction
remove to
(0.05g)
the
Reaction of Pt/CH~)~(SaZl~ Pt(CH3)2(Sal)z
B)
(isomer
of
and
be
added
(0.5
excess to
complete.
precipitated added
indicated
ml)
dropwise.
recorded, allowed
z-hexane
solid
CDC13
stand
The
solution
sol
Id,
to
precipitate
that
the
there
present.
(isomer Ai with etir.qZenedianine was
dissolved
in
chloroform
(2
ml)
and
a
in
solution
of
immediate This
ethylenadiamine
formation
was
of
filtered
volume
and
crystal
line
r.-hexane
The
id.
to
obtained
by
concentration
yield.
lock
considered
analysed the
and
initial
were
addition
(TMS)
recorded
using
accurate
to
sweep
Pt(CHs)zen(OH)z
as
270
and
coupling
IR
PS-100
Hz.
small
and
was
solid
This
its
a
a white
a yellow
?z-hexane.
width
+-O.Olppm
to
for
JEOL
activated
concentrated
by
a
with
product
of
on
treated
filtrate
was
precipitate.
the
ethylenediimine
NMR spectra
internal
and was
There
dropwise. 1 ine
ethanol
solution
product
bis-(salicylaldehyde) ‘H
in
precipitate
From
70%
added
microcrystal
the
added
in
be
off-white
filtration,
sol
chloroform
dissolved
obtained
to
an
off,
After
charcoal.
in
was
was confirmed
spectrum-
spectrometer
Chemical
on
shifts
constants
to
are
20.5
Hz.
References
1.
R.C.
Menzies,
2.
A.K.
Chatterjee,
J.
Sot.,
(1928)
565
Henzies,
J.R.
Steel
Chem. R.C.
ar;d
F.N.
Youdale,
J.
3.
K.
Kite
and
M. R.
Truter,
J.
Chem.
4.
K.
Kite
and
A.F.
Psaila,
J,
Organomental.
Chem.,
57
(1975) C33
5.
J.R.
Hall
6.
J.R.
Hal
7.
J.R.
Hall
8.
J.R.
Hal
9.
M.R.
Truter
and
10.
J.E.
Lydon,
M.R.
11.
K.
12.
B.E.
Reiehert,
D.E.
Clegg,
13.
I
1
Kite,
Sot.,
A,
(1968)
934
and
G.A.
Swile,
.J.
Organometai.
Chem.,
21
(1970)
237
and
G.A.
Swi le,
J.
Organomqtal.
them.,
47
(1973)
195
and
G.A.
Swi le,
J.
Organometal.
Chem.,
67 (1974)
455
and
G.A.
Swi le,
J.
Organometal.
Chem.,
122
R-C.
Watling,
Truter
J.A.S.
Smith J.
J-R.
J.
and and
R.C.
E.J.
and
Sot.,
Watling,
G.A.
A Proc.
Wilkins,
Organometal. Hall
Chem.
J.
(19763
(1967) Chem.
Chem.
72 (1974) 305
Swile,
J.
1955 (1964) 193
Sot.,
Sot.,
Chem.,
Cl9
(1966)
Organometal.
Chem.,
1744
38
403 14.
K.S.
63
Chem.
(1958) 1706
sot.,
6-E.
Murray,
(1973)
15.
J-R.
Hall
16.
B.E.
Mann,
17.
J.R.
Hall
Reichert
and
8.0.
West,
J.
Organcmetal.
Chem.,
461 and B.L. and
G.A.
Swi le,
Shaw G.A.
and
Swile,
J. N-1.
Organometal. Tucker,
Austral.
Chem., Chem.
J.
Chem.,
Comm.,
56
(1973) (1970)
419 1333
28 (1975) 1507
(1972)
Joumol of OrganometalIic Cizemistry, 161 (19’78) 121-138 0 Elsevier Sequoia S.A., Lausanne - Printed inThe Netherlands
DIMETHYLPLATINUM(IV)
COMPOUNDS. V. PREPARATION AND
REACTIONS OF BIS(SALICYLALDEHYDAT0)
J.R. HALL
and
COMPLEXES
G.A. SWILE
Department of Chemistry, University of Queensland, Brisbane, Australia 4067. (Received
July
17th,
1978)
summa ry
Two geometrical
isomers of Pt(CHa)2(Sal)2 have been prepared and Some reactions of isomer A (phenolic
identified by 'H NMR spectra. and
oxygen atoms traj?s to CH3)
isomer
6
(aldehydic oxygen atoms t?%??s
Isomer B reacts with CgDaN to produce species
to CH3) are reported.
containing unidentate Sal in
while
solution,
Primary amines react with isomer
with formation of hydroxo species. B to form salicylaldimine
isomer A tends to lose Sal
complexes.
isomer A reacts with en to form
Pt(CHa)zen(DH)z.
Introduction Although a large range of f3-dicarbonyl complexes of both trimethylplatinum(lV) far
less
was
prepared
dimeric [g,lO]
[i-6]
and dimethylplatinum(lV)
work on salicylaldehydato
with
by
reaction
bridging
of phenolic
[7-81
complexes.
[Pt(CH3)31], oxygen
with atoms
are kno.,:n,there has been
A compound of formula R(CH;)3Sa' TiSal
both
in
is]
and k/as
the
solid
found
to
state
and in solution [ll], but no reactions of the compound were
reported.
In the dimethylplatinum(lV)
system only the compound
Bur+N[Pt(CH3)2Br2Sal] which is monomeric with Sal tzw?s to CHa groups has been reported 1121. geometrical
In this
paper
we report
the
preparation
of
isomers of formula Pt(CHa)2(Sal)2 and a number of reactions
be
122 these
of
have
compounds with
been
Results
reported
pyridine-dg
amines _
Preliminary
results
[8].
and Discussion
E'nzparatioz
and
identijYca-t;icn -L
Pt(CH3)2(0H)2-2H20 from
and
such
solutions
isolated.
The
is
in
soluble
decomposed
dissolves
a compound
product
is
organic
of the
in boiling
of
formula
by 95% ethanol
or
such
as
aqueous
salicylaldehyde
Pt(CH3)2(Salj2
an orange-yellow
solvents
Pt(CH313(SaZ)7
compozmds
may be
crystalline chloroform
acetone
and
to
and
reform
solid
which
benzene
but
the
hydroxo
cdmpound. Assuming three
bidentate
geometrical
salicylaldehyde
isomers
are
and &s-methyl
possible
for
Pt(CH;)2(Salj2
Fig. 1. Isomers of ci.s-dimethyl-bis(saJicylaldehydato),olatinum(IV),
The
‘H
NMR spectrum
presence
of
only
resonance
(with
and
(I
ruled
lg5Pt out
one sate1
= %,
since
of
for
the
isomer li tes
compound since due
34% abundance)) this
isomer
in
only
CDC13
is twc
(Fig.
a single
to coupling
groups
non-equivalent
(see
present,
Fig.
Pt(CH3)2(SaI)l_
2a:
indicates
the
methyl-platinum
between
observsd.
are
the methyl
Isaner
protons
C may be
methyl-platinum
-* The compound Pt(CHsj2 (OHj2;2H20 has been reported f rem the reaction df [Pt(CH3)2Br2] with NaOH ES]. Subsequent preparations indicate that freshly pre;ared samples approach this formulation, but there is loss of weight with ageing and the compound is probably better described as Pt(CH3)2(OH),nH,O(n=l-2).
lj
_
123
I
,
I
I
Fig. 2. ‘H n.m.r. spectra of Pt(CH,)Z(Sal)2
resonances to
the
influence
positions
of
Hz,
Table
atoms
trall.s
trmzs
to
to
phenol
CH3 tim?s
1)
in CDCI,;
(a), isomer A and (b), isomer B. *ThIS.
to
to
salicylaldehydato This
value
8 of
Fig.
is
phenolic
of the
(74.1
the
to
be
compared Hz)
be
expected
atoms
in
the
coup1 ing
wi th
appears
when
donor
would
presence more
with
and
constant
aldehydic
trays
observed
of
oxygen
consistent
the
due
donor
with
CH3
obtained
valties
Hz)
(78.6
in
[12]. Table ligands
substantially
1 (where
of tent
and
i c oxygens
BubN[Pt(CH3)2Br2Sal] Reference
consis
CH3 [13]
constants
types
magnitude
is
I
8
r
coupling
different
The
1131.
(72.4
for
different
with
’
I
6
1
4
2
0
the
1 shows
that
the
to
lg5Pt
couple higher coup1 ing
than
would
aldehydic with that
protons
of
the
a magnitude
of
121 .O Hz.
expected
be expected
to
for
either
be of
the
isomer same
124 TABLE ‘ii
1
NMR SPECTRA OF ISOMERS CF Pt(CH3)2(Sal)2
AND THEIR
Pt-CH3
P t-O=CH
Compowd r
T
J
REACTION
PRODUCTS
P t-N=CH *
J
Pt-N-CHs
J
T
J
In Ifi-dichlorobeozene Pt(CH3)2(Sal)2
In
A
a.13
72.5
B
8.12
77.5
C
8.07
77.2
a.23
72.7
A
8.23
72.4
1.83
B
a. 13
16.3 15.9
CDCl?
Pt(CH3)2(Sa1)2
Pt(CH3)+al
(Sal=N-CH;)
77.5
0.62
8.31
79-I
0.67
121.0
1.89
22.0
6.61
8.7a
1.95
22.5
6.67
9.1 6
I.83
19.6
6.58
y-1'
8.55
67.1
Pt(CH3)2(Ss1=N-CH3),
8-66
68.4
Pt(CH3)2(Sal)
a. 14
78.7
8.44
68.5
8.49
68.4
2.04
22.2
a.55
70.4
1.90
19.2
(Sal=N-C6Hs)
(Sal=N-CH?)
Pt(CH3)2(Sal=N-C6H5)
Pt(CH3)2(Sal)2,S
+ en:
Ini tiai Products:
8.32
78.8
a.52
66.6
a.&0 a.52
66.6
Major
8.64
68.6
Minor
8.65
69.0
Major
Minor
Final
In
Products:
79.1
0.68
15.4
1.83
Igd
0.61
15.2
1.93
20'7
1.92
21.2
c
CDCI~-CSD~N
Pt(CH3)2(Sal)2C+$~
Pt(CH3)2(Sal)z(C~DSN)~ Pt(CH3)2(Sal)
(CSDSN)OH
Pt(CH3)2(CSD,N),(OH), In
16.0
0.78
a.025
77-
a.57’i
71.6
-0.62'~
-
8.07
71.4
-0.48
-I
1
17.2
0.62’
8.3+
73.2
1.46
8.49:
72.0
O.Oy'i
8.63
71.8
8.87
70.7
76.2 -
D,O
Pt(CH;)zen(DH)z
(L d 5
3J (CHj-N=CH)
1.2
Error
’
~1
Slight
50% by
Hz.
Hz. Region
downfield
shift
g
Slight
volume. 50%
increased
to
increased
to 50%
’
by volume. by
volume.
1.4 Hz.
3J(CH3-N=CH) complex,
(3-4
Hz)
upfield IL
only as
peaks
(2
move5
Hz)
as
1.3 Hz.
identified.
CSDsN concentration
shift Peak
major
3J(CH3-N=CH)
=
increased
to
CsDSN concentration
to T -0.73
as CSDSN
concentration
125 order
as
[14]
since
Fig.
1
when
allowance
with
that
found
the
is
methyl
can
for
with
only
isomer,
be
[16].
found
it
for
assigned
to
heating
not
the
and
and
reactions
metallic
reported
this
below
for
more
orientation been
compounds
to
a particular
with
the
found
consistent
results
that
Hz
those
compound
can
be
1. is
indefinitely
stable
boiling
according
are
Hz
assignment
these
the
121
I)
of
of 40
in alken$lplatinum(l
unequivocal
compared
15 and
a favourable
al though
of
are
have
solvents
dicyclopentadiene
is
of
0
coup1 ings
couplings
evi dence, an
Fig.
terms
of
isanerA
of
the
CH3NH2
Hz)
be expected
influence
value
large
comparison
high
new species
the
to
usually
results
lH
dependent
such
in
the
by
state,
tetrachloroethylene,
in
the
formation rate
The
temperature
accompanied
solid
as
NMR spectra.
on
the
of
of
of formation
reaction,
some
decomposition
m-dichiorobenzene
solutions
to
platinum.
Accord (Table
i ng
l),
three Two of
Hz)
at
remain from is
in
than
was made The increased
NMR spectra
these
equal
species
isolate
third in
to
one-third
with
be
of
(T
8.07,
throughout
the
the
appear
J 77.2
C of
total
Fig.
species
during
Hz;
reaction
non-equivalent
isomer
T 8.23, and
methyl
1 in
but
the
so
J 72.7 probably This
groups.
was
never
solution
and
present no
attempt
it.
methyl-platinum intensity
resonances
resonances
intensity
postulated
to
of
new methyl-platinum
a single
species more
‘H
to
reaction.
arise
by
in
new species
these
Similar
compound
m-dichlorobenzene
of
in
above
A of
isomer
high
or
might
, where
CH3 and
(22-27
CH$
Hz)
tiqar?s 3+
to
to
( 0, 60
abnormally
isomer
solutions
several
tia7z.s
smaller
trans
allow
only
other
Al though
value
rationalized
The
is
the
is
case
H couplings
A.does
and
each
the
H groups.
Hz)
isomer
for
The
Pt*=C-
(120-148
[pt(CH,),Br,Sal=N-RI-
higher
protons
Pt-O=C-
trails
complexes
*[Pt(CH3)2(CH,NH2)4]-
[ 151)).
coupling the
made
(cf.,
respectively
of
in
a somewhat
[13]
methylamine
the
coupling
(where
CH3
in
as
resonance the
reaction
(T
8.12,
proceeded
J 77.5 and
was
Hz)
gradually
ultimately
126
the only such resonance present. species
a yellow
solid
analysing
From solutions containing this for Pt(CHx)z(Sal)z was isolated.
This
solid is soluble in chloroform and benzene and, in contrast to the previous
isomer, dissolves in ethanol and acetone without decomposition.
The IH NMR spectrum of this isomer in CDC13 is shown in Fig. 2b. The NMR data (Table 1) are consistent with this compound being isomer B of Fig. 1.
A single methyl-platinum
resonance is observed
with a coupling constant of 77.5 Hz consistent with CH3 trazs to oxygen donors [13] while the salicylaldehyde with lg%t
aldehydic protons couple
with a magnitude of 16.3 Hz, comparable with the coupling
of the aldimine proton in
[Pt(CH3)2Br2Sal=N-R]-
[lb].
It
may be
noted
that for this isomer there is no enhanced coupling of the aidehydic proton to lgsPt. Since the magnitude of the coupling constant gives an indication of tend strength
[13] it would be predicted that the coupling
constant of a methyl group i=rans to an aldehyde group as in isomer B would
be greater
than
that traisz to a phenolic oxygen as in isomer A.
The couplings observed for the two isomers (77.5
Hz for isomer B;
72.4 Hz for the initial isomer) tend to confirm that the initial isomer is isomer A.
Reactions of the compounds Pt(CH?)T(Sai)q
When CsDsN is added dropwise to a CDC13 solution of isomer B, two new methyl-platinum (Table
1).
resonances appear in the NMR spectrum
These resonances are of equal intensity and are presumably
due to a single species with non-equivalent methyl groups.
The
coupling constants, 71.6 and 77.1 Hz are consistent with methyl groups t~ans to CgDgN and an aldehydic oxygen respectively, so that
:‘:
CsDsN rather than CsHsN resonances to be observed.
was used to enable the aldehydic proton
127 the
species
and
one
is
unidentate
The
ligand.
presumed
to
be Pt(CH3)2(Sai)2(CSDsN)
the
(via
aldehydic
phenol
proton
ic
region
oxygen
atom)
supports
with one bidentate
sal
the
icylaldehyde
presence
of
such
a species since two separate resonances are observed, one at T 0.62 (J 17.2 Hz) which is attributable
to CHs and a second at ~0.62
group zkans
fi rst
to bidentate Sal with the aldehydic
and shows
no evidence
for
which
is broader than the
coup1 ing with lg 5Pt.
There
is
apparently an equilibrium between isomer B and this species
since
there
addition
is
still
an
appreciable
amount
of
isomer
B. present
on
of more than two moles of CsDsN per mole of Pt(CHs),(Sal),.
There
is no further change in the spectrum on allcwing the solution to stand.
On the other hand,the relative amounts of each species are
altered
by Further
changing
the
addition
concentration
of
Pt(CH,),(Sal)2(CsDSN),
CsDsN
of
results
slight changes
CDC13. in
in
increased the
formation
chemical
shifts
of of
the
methyl and coordinated aldehydic protonsand a more marked downfield shift of the free aldehyde proton which also tends to sharpen. Continued addition of CsDsN results in the formation of a new species with only a single methyl-platinum
resonance (T 8.07, J 71.4 Hz)
which is postulated to be Pt(CHs)2(Sal)2(CsDsN)2 trcvzs to CH3 and two unidentate salicylaldehyde
with CsDsN
(via the phenolic oxygen atom)
ligands. A single.sharp
resonance (T - 0.48) appears
in the aldehydic proton region with no evidence for coupling with 19Spt.
Further addition of CsDsN increases the amount of this species
at the expense of Pt(CH,)2(Sal),(CsDSN) species is present.
until only the bis pyridine
On allowing such solutions to stand for several
days decomposition apparently occurs,since
the colour of the solution
becomes deep red and the NMR spectrum shows a large number of new peaks in the methyl-platinum
region.
When a solution of isomer A is treated dropwise with C5D5N, two new methyl-platinum
resonances appear in the NMR spectrum.
The
resonances are of equal intensity and presumably arise from a single
128 species
with
constants tiazs to
observed
to
CsDsK
stand
in
platinum, isomer One
second
Two
position
cis
is
present
at
~0.09
chemical
(T
the
methyl
than
which
is
probably
shift
is
almost
the
more
species
yields
large
The due
0.06).
The
likely
from
121.0
with
the
Hz
in
in each
in isomer
arising
a change of
this
further
with
resonance Furthermore,
the
pattern
found
in
ligands
have
probably
of
aromatic
its
salicylaldehyde solution
could
with
CsDsN or
formulation containing
this
infrared
the
coordinated
species
is
orientation
spectrum. aldehyde
also of
effect
a second 8.63,
consistent the
would
region
to
of
the
sat icylaldehyde. and
the
solution
OH and CsDsN as
to
J 71.8
aldehyde
not
the
(Table
1)
aldehyde
proton
increases
in
spectrum
resembles
the
This
indicates
methyl-platinum for
give
a solid by
Hz)
exhibiting
T 0.06)
Support
confirmed
species
CSDSN while
(shifted
displaced
the
singlet
the
influence
(+
I%ZV_S to
Pt(CH3)2(CsDsN),(OH),_
by evaporation coordinated
been
a trazs
be
in a
a sharp
in
latter
this
can
salicylaldehyde
(CsDsN)OH
of
a particular
resonance
previously
free
in
and
platinum
for
solutions
constant
species.
since
present
of of
second
bidentate
in
mole
expense
Hz)
is
solution
magnitude.
CH3 groups
observed
of
Hz
the
the
per
the
to
found
The
CsDSN produces
methyl-platinum
consistent
76.2
from since
of
atom.
coupling
A to
that
OH vibrations
with
the
one
Pt(CHs),Sal
evaporation
compound,
Addition a single
since
a product
coupling
in
oxygen
for
bonded
species
or
at
salicylaldehyde
with
CH3 groups
CsDsN
resonance
free
to
lq5Pt(76.2
that
second
to
of
present
with
so
identical
(T
moles
group
groups,
aldehydic
decrease
are
coup 1 i ng
On allowing
increases
coupling
[Pt(CH3)zSal(CsDsN),If to
two
gradually
compound.
The
respectively.
more
shows
the
appears
result
of
groups.
may be assigned
on an aldehydic
solutions
OH ~&ES
group
i c oxygen
in
be either
Hz)
resonances
1.46)
to
73.2
species
a proton
similar
The
and
aldehydic
resonance to
(72.0
presence
this A.
methyl-platinum
and phenol
the
assigned
in
non-equivalent
IR.
this
that
The
both
species
is
formulation
containing compound
intensity.
Sal
most is
obtained
both is
however
129
unstable
and
When
loses
a one
Pt(CHS)2(Sal)2 a
new
species
CsDsN
to
form
Pt(CH3),(DH)2nH20
mole ratio of methylamine (isomer 6) in
CDCl3
there
on
standing.
is added to a solution of is
an
immediate
formation
of
two noll-equivalent methyl-platinum groups as
with
evidenced by the presence of two methyl-platinum equal intensity in the NMR
spectrum
(Fig.
resonances of
3a).
The
spectrum
can
be
i i Fig. 3. Pt(CH,)2(Sal)2
(isomer
(b) 2 mol of CHxNHI.
*TMS.
l
I
I 4
I
2
6
interpreted
in terms
of
!
B) plus (a) 1 mol of CHlNH2;
the
I
-r
structure
in Fig.
4A
(R=CH3),
platinum which
resonances are
consistent
Thus
have coupling constants of with
CH3
trajzs
to
an
79.1
aldehydic
the
where
and
iigands
two 67.1
oxygen
methylHZ (cf.,
I
10
8
methylamine has condensed with one of the salicylaldehyde to form an N-methyl salicylaldimine complex.
,
I
I
6
(Table 77.5
11, Hz
130
B Fig. 4. Structures CH,NHz (B)
in
of the reaction
isomer B) and txizs
products
to
of isomer B with one mol of CH,NH?
group
an aldimine
Ph,As[Pt(CH,),Bt-,Sal=N-CHs][l41).
(cf., 67.1
with lq5Pt (Fig. 3a).
together with sate11 ites
The
in
The N-methyl resonance consists of
a central doublet due to coupling between the CH3 proton (3J(HC=NCH3)1.2Hz)
(A) and two mol of
magnitude
of
this
latter
group due
and to
the
imine
coupling
coupling
(8.7 Hz)
is somewhat less than those found in M[Pt(CH3)2Br2Sal=N_CH31 (13.0-13.2 Hz)[14] and [Pt(CHs)sSal=N-CH3L)
(14-16 Hz) [17] indicating
a weaker Pt-N bond in Pt(CH3)2(Sal)(Sal=N-CH3).
This is supported also
by the magnitude of the coupling of the aldimine proton with lg5Pt (22.0 Hz) which
[141.
is less than that in Bu4N[Pt(CH3)zBr2Sal=N-CH3](26.4
Hz)
The aldehydic proton couples with lg5Pt with a magnitude of
15.9 Hz, which is of the same order as that found in isomer B (16.3 Addition of a two mole ratio of methylamine to a CM13 of Pt(CH3)2(Sal)2
Hz).
solution
(isc;nerB) immediately produces Pt(CHS)2Sal(Sal=N-CH3)
as for a one mole ratio.
However, on allowing the solution to stand,
formation of a new species, whose spectrum is shown in Fig. 3b, occurs over a period of about 30 minutes.
The spectrum indicates that the
compound is the bis (N-methylsalicylaldimine) is shcwn in Fig. 46 (R=RI=cH,).
compound whose structure
Thus a single methyl-platinum
resonance is observed with a coupling constant of 68.4 Hz, coupling
of
lg5Pt
proton
(22.5
in
compound
the
Hz)
with are
both of
the
Pt(CH3)zSal
the same
N-methyl order
(Sal=N-CHs).
group as
is
(9.1 found
Hz) for
while
and these
the
aldimine
couplings
131
Although a second mole of CHsNH, reacted quite readily with Pt(CHs)$al(Sal=N-CHs)
as shown above, an attempt to react the latter
species with a-methylbenzylamine
was unsuccessful since no apparent
reaction occurred after heating for 10 hours at 55'C. Reaction of isomer B with a two mole ratio of aniline was extremely slow at room temperature but at 55'C reaction occurred over a period of 3 hours to produce a species whose NMR spectrum was consistent with Pt(CHs)2Sal(Sal=N-CsHS)
(Fig. 4A, R=C6HS).
Thus two non-equivalent
resonances are observed with coupling
methyl-platinum
constants
of
78.7 Hz (tram
to aldehyde group)
Roth aldehydic
6.0 Hz) and aldimine (T 1.83, J 13.6 Hz) (T 0.78, J 1'
protons were observed
and
e 1). (Tab 1'
6815 Hz (trans to aldimine group).
The larger value of 2J(1g5Pt-CH,) t?mls
to N and the smaller value of 3J(1g5Pt-N=CH) compared with the values in Pt(CHs)zSal (Sal=N-CHs) consistent
compound, of
the No
aryl
group
attempt
with
i ndicate a weaker Pt-N bond in the former the
greater
electron
such
a
(Sal=N-CsHs)
reaction. with
was
made
to extend
the
5:
However
CH,NH,
, reaction
reaction
to the
formation
of
extreme
in
view
of
a solution
the
of
of
the
sladness
Pt(CH3)zSal
proceeded at a reasonable rate with the reaction
being complete after 6 hours at 55'C. Pt(CH3)2(Sal=N-C6HS)(Sal=N-CH3) 'H NMR.
properties
[lb].
bis (N-phenylsalicylaldiminato) compound of
- withdrawing
Two methyl-platinum
The product of the reaction was
(Fig. 48, R=CH3;R1=C6HS) according to
resonances are observed with coupling
constants of 70.4 Hz (CHj trans to N-CsHS) and 68.4 Hz (CH3 trarrs to N-CHs) and two aldimine proton resonances at T 1.30, J 19.2 Hz (EC-N-CsHS) and T 2.04, J 22.2 Hz (H_C-N-CHs). Reaction of Pt(CH3)2(Sal)2
(isomer 8) with ethylenediamine
complex than the above reactions and the results more equivocal.
is more Dropwise
addition of en to a CDC13 solution of isomer B produces three new methylplatinum resonances in the lH NMR spectrum.
The intensities of these
7: Species of the type Pt(CHs)2(Sal=N-R)2 would probably be best prepared as has been done with by reaction of Pt(CH 3 2(OH) 2- nH20 with HSal=N-R H acac=N-R ligands [6].
132 resonances indicate that two species, each with two non-equivalent methyl groups are present in so ution in
the
approximate
ratio
of
2:1 with one
resonance from each spec es be ?g accidentally degenerate (Table 1). The magnitudes of the coupling constants indicate that for
each species
one CHS group is trcwzs to an a dehyde oxygen (78.8 and 79.1 Hz respectively) and one trczzs to an aldimine group (66.6 Hz for each). Each species exhibits one aidehyde aldimine (T 1.83 and i possible
structures
resonances
but
it
1.93
which is
(7 0.68 and;
respectively)
would
impossible
give to
0.61 respectively) and one Fig.
resonance. non-equivalent
assign
5 shows
two
methyl-platinum
structures
from
the
NHR spectra.
-NH2
B Fig. 5. Possible products of the reaction of isomer 'B with en.
Further addition of ethylenediamine produces two new species each with equivalent methyl groups truzs to aldimine ligands (Table I).
A
large number of monomeric, dimeric and even polymeric structures could be postulated with equivalent methyl groups so that the species cannot be identified by 'H NMR spectra.
The formation of insoluble material
probably indicates that polymeric species
have
form&d
in the reaction.
Reaction of Pt(CHs)2(Sal),( isomer A) with ethylenediamine immediate precipitation of a white microcrystalline analyses
for
Pt(CHs)2en(OH)2".
solid
results in which
The 'H NMR spectrum of this compound
in D20 exhibits a single methylplatinum constant of 70.7 Hz, consistent wth
resonance with a coupling
CHs group trms
to nitrogen donor
The same species may be prepared by reaction of Pt(CHS)3(0H)3-nH20 with en.
133 atoms
[131.
coordinated From
the
The
infrared
OH at
3591
filtrate
of
(u(OH)),
the
above
coordinated presence even
the
and
acetone.
(phenolic)
[Is],
1 i gands .
On the
appear
be
bonds
trms
this
other
the
reactions
(cSD~N)
formation
of
in
by
remain
the
intact
due
I3 the
and
such
in
the
and to
their
high
tzw:s
the
salicylaldehyde
groups the
involved
in
either
-
The
do not
Pt-0
suggests
formation
the
tend
of
(amines)
the
A)
groups
only
systems
by IR spectra.
OH groups
phenolic is
it are
during
of bis-
(isomer
to
that
of
to
(w(Pt-0))
ethylenediamine
methyl
due
cm-l
confirmed
by
CSDSN,
reactions
in
species
as
displacement
which
condensation
hydroxo
as
558
crystals
displaced
isomer
groups
and
peaks
Pt(CH3)2(Sal)2
positions
OH groups
methyl
in
complete
in
contains
(6(OH))
yellow
Since
trcrrzs
hand,
or
bonds
in
results
displaced to
(phenolic)
such
ethanol Pt-0
969
that
readily
ligands
compound
be obtained
are
of
influence
to
groups
and
can
indicate
a variety
aqueous
weaken
reactions
the
reaction,
imine
aldehyde of
989
above
(salicylaldehyde)cethylenedi The
of
spectrum
the
(aldehydic)
displacement lack
of
the
Pt-0
Schiff
base
complexes. Experimental Analytical
,
Z%epaz-atioiz
results of
for
Ptr (Cfiq)
9 (Sa ZI 7
Pt(CH,),(OH),*nH,O
and
the
several
heated
minutes
heating
was
required
evaporated
orange-yellow
solution to
plates
sample
solutions
the
sol
id
1ization. off,
compound
appears
remaining the
on
solid
addition
of
water
to The
washed to
unchanged
compound
in
The
was
are
bath
product,
after treated
Table
2.
sal icylaldehyde
the
with
solution The
the
and n-hexane form
and
of
air
indefinitely 4 months.
was
air.
chloroform,
volume
z-hexane
ml)
of
When
95% ethanol
added
orange-yellow
dried. in
ml)
after
orange
a stream in
in
(0.5
resultant
in
(5
dissolved
ethanol
The
a small
stable
in
usually
dissolved
with
be
listed
/.I
dissolution.
concentrated
filtered
of
1ine
are
suspended
boi ling.
ready
dryness
crystal
crystal
was The
one
to
was
although
for
fi ltered,
induce
to
compounds
(isonisr
(0.69)
mixture
sometrmes
the
the
Yield solid
chloroform or
aqueous
952.
state,
_
134 TABLE
ANALYTICAL
2
DATA
Empirica? formula
Compound
Analysis
(calcd, (found)) (%) H
C C1sHxeOri”t
B
Cl6H16gL;Pt
Pt(CHs),fSa!)(Sal=N-CH3)
Cl7HlsNu3Pt
ClaH2zN20zPt
PtfCH3)2(Sal=N-CsHs) (Sal=N-CH3)
Czd%.$WW’~
C4H16N202Pr
41.1
3.5
(41.2)
(3.5)
41.1
3.5
(41.2)
(3.51
N
4.0
2.9
(42.3)
(4-O)
(3-o)
43.8
4.5
5.7
(43.9)
(k-61
(5.6)
49.7
4.4
5-o
(49.7)
(4.5)
(5.0)
15.0
5.;
8.8
(14.8)
(5.51
(8.4)
42.5
acetane the solution becomes cloudy and the odour of salicylaldehyde becomes noticeable,
Evaporation of the solution and extraction with
chloroform leaves a pale yellow residue which has an identical infrared spectrum to that of Pt(CHs)2(0H)2*nHz0.
Pt(CH3)g(Sal)2
(isomer A) (0.5s) was dissolved in m-dichlorobenzene
(8 ml) and the solution heated to boiling.
Metallic platinum began to
precipitate from solution after 30 seconds but heating was continued for 8 minutes at which time the IiiNMR spectrum confirmed that only a single species was present in solution,. The solvent was then evaporated by heating on a water bath in a stream of air.
The residue was
extracted with chloroform, charcoal added to adsorb the colloidal platinum, and
135 the
solution
and
the
yellow
remove
all
stable
indefinitely
of
Several
both
of
NMR spectra
boiling.
Initial
amount
of
occurred
difficult
as
intractable
was
with
C.
Both
than
30-402,
increased
at
rise
to
no evidence
amount
the
expense it
On the
reaction.
dicyclopentadiene group to
which
platinum
in
Pt(CH3)2(Sal)z
of
the
of
z-hexane. to
appears
solutions
to
be
of
about
only
slower,
same
was
no
of
the
as
total
in
the reaction for
product
A similar
this
case
much
2 hours
evidence
the
formed. in
after
complete
isolation be
was
but
the
there
isomer
at
C was
the
expense
never
In
was result
there
was
at
shaded
to
of
dicyclopentadiene
an extent
greater
of
isomer 1 ing
isomer
C did
There
presence
A in of
in
was the
both
a free
may be
B
solvent,
throughout
isomer
isomers
al though
lower-boi
stage
species,
reaction,
present.
any
the
new
while
amount
species
tetrachloroethylene
h.!o
the
the
the
NMR spectra
the
of
constant
A.
total
both
present
fairly
that
the
in
A.
throughout
isomer
pyridine
(isomer
was
to
present
hand
reaction
the
Pt(CHs)2py2(OH)2.
appeared
Former
also
although
that
of
that
was
for
investigated
conversion
and
salicylaldehyde
other
were
dicyciopentadiene,
remaining
50% of
and suggests
in
tended
isomer
free
and
Hc+iever,
were
the
for
state
solutions
isomers
almost
solid
heating
decreased
tetrachloroethylene, fact
of
indicated
in m-dichlorobenzene
compound
complete
tars
and m-dichlorobenzene H and
The
With
formation
IH NMR spectra
i vo1um
necessary
tetrachloroethylene,
metal.
pyridine
substantial
sometimes
80%.
eventual?y
5 minutes
platinum
a smal
addition
Yield
formation
formed
of
to
by
is
solvents
With
B.
formation
also
boiling
reaction.
within
found
the
platinum
m-dichlorobenzene
precipitated charcoal
indicating
platinum
concentrated
acetone.
high
isomer
slcwer,
in
and
other
preparation
with
platinum.
ethanol
was
product
ization
traces
chloroform,
filtrate
crystalline
recrystall
A second
The
fi Itered.
aldehyde
coordinated
solution.
A)
(0.049)
was
dissolved
in
CDC13
(0.5
ml)
136 in the
an NMR tube. reaction 50:50
a stream
of
The
The
confirmed
Zeaction
to
as
during
spectra
which
an NMR tube.
lH
NHR spectra
extracted
6)
time
it
of
and
(isomer A solution
then
the
6)
(0.049)
of
CH3NH2 in
complete to
added.
product
more
amount
separated.
the
free
of
Pt(CH3)2Sal
than
methy!
after to
(isomer A solution
required
of
‘separated.
leaving
in a
spectrum. by
‘H NMR.
was
CDCls,
was
allcwed
to
to
deep
red
products
in
solution.
in
CDC13
treated stand
and
lH
for NMR
of
the
added
were
to
f i 1 tered
ml) until
The
product. to
solution
(0.5
dropwise
desired
concentrated the
2 moles
8)
(0.049)
of
CH3NH2 in
of
being
CHsNH2 per
estimated
resonance
was
of
by
a small
stand, off
NMR spectra
30 minutes
at
room
a beaker, the were
filtered
mole
of
to off
in
yellow
and
the
of
a small
stand
yellaEI air-dried.
dropwise were
the
the The
to
(0.5
until added,
resonances
formation
solution
was
volume
and
prisms
of
Yield
ml)
intensities
methyl-platinum
indicated
and
CDClS
platinum
comparison
temperature.
concentrated solution
dissolved
CDC13 was added
CH3NH2 and
_
These
CDCIS was
These
(Sal=N-CH3)
On allowing
dissolved
30%.
Pt(CHS)2(Sal)2 an NMR tube.
was
On allowing
of Pt(C~qJ3(Sa~=I?T--CA?I)7
added.
dryness
infrared
in
yellow
a beaker,
_Prepa.ration
transferred
to
complete
CsDgT
formation
Yield
product
and
was
confirmed
solution from
ai r-dried.
the
as
decomposition
transferred
n-hexane
of
slightly
its
dissolved
final
changed
reaction
chloroform
nH20 by
B) with
solution
evaporated
with
(O.Obg),
The
A.
indicated
was
crystals
in
was
the
of Pt(CH11~SaZ(SaZ=??T-C~91
in
volume
was
Cisomer
a number
Pt(CH3)2(Sal)2
solution
solution
to
When
Pt(CH3)2Sal(CSDsN)OH
isomer
indicated
P~epaxctioz
the
(isomer
for
dropwise
Pt(CH3)2(OH),-
of Pt(CH~)plSaZl~
CsEsN
3 days
be
added
NMR spectra.
lH
solid
contained
Pt(CHs)2(Sal)2 with
by
CDC13:CSDSN)
air.
solution
was
CgDgN
monitored
(approx.
residue
Neat
of
the
then
n-hexane the
95%.
product
137 Reaction
of P~(CHJ)~(S~Z)~ (isomr B) ~6th aniZi=e
Pt(CHs)2(Sa1)2 in
an
NMR
tube
The
solution
as
confirmed
9
hours
with
and
by
B)
a solution
initially NMR
of
Attempts
to
but
species
intractable
isolate
gums
in
The
to
the
form
on
added
solution
pure
evaporation
dropwise.
during
were
of
for
55’C
consistent
reddish
form
ml)
aniline
at was
became
in
(0.5
unreacted
spectrum
solution
CDC13
(1:lO)
and
NMR
product
in
CDC13
heating
whose
this
tended
line
dissolved
Pt(CH3)2(Sa1)2
(Sal=N-CSHS) .
Pt(CH3)zSal
ani
spectra,
a single
was
(O-039)
contained
lH
produced
time. as
(isomer
this
unsuccessful
the
solution.
Preparation of Pt(CH?l~/SaZ=N-CF;351ISaZ=il-CH~) To
a solution
des cr i bed one
mole
of
CH3NH2 of
hours
of
at
the
The
added,
filtration
and
z-hexane
and
were
and
the added.
fi
ltered
was
methyl
the
added
by
was
ai r-dried.
to
with
crystals
Yield
relative
complete
a beaker,
to of
After
formation
activated
concentrated
yel1o.d
until
resonances.
transferred
heated
as
dropwise
indicated
indicated
then
On standing,
prepared
methyl-platinum
was
solution
was
as
spectra
solution
and
CDC13
present
solution
yellow
off
in
and
NMR
reddish
(Sal=N-CGH3)
CH3NH2
platinum
temperature,
product.
After
per
of
methylamine
room
chloroform
Pt(CH,),Sal
a solution
above,
intensities 6
containing
the
charcoal.
a small
volume
product
formed
90%.
Reaction of Pt(Cli~~7lSaZl7(ison;er31 witi? ethyZenedim%ze Pt(CH3)2(Sal)2 an
NMR
After
tube the
and NMR
a solution
spectrum
ethylenediamine for
2
hours
was
then
which
filtered
to
filtrate
concentrated
a ye1 low
solid.
was
of of
solution at
a mixture
was
time
of
compounds
(0.039)
dissolved in
intermediates added
data
and
had the
for
to
amount
volume this
in
CDC13 been
soluticn
appeared
a small
a small
Analytical
was
ethyienediamine
reaction
remove to
(0.05g)
the
Reaction of Pt/CH~)~(SaZl~ Pt(CH3)2(Sal)z
B)
(isomer
of
and
be
added
(0.5
excess to
complete.
precipitated added
indicated
ml)
dropwise.
recorded, allowed
z-hexane
solid
CDC13
stand
The
solution
sol
Id,
to
precipitate
that
the
there
present.
(isomer Ai with etir.qZenedianine was
dissolved
in
chloroform
(2
ml)
and
a
in
solution
of
immediate This
ethylenadiamine
formation
was
of
filtered
volume
and
crystal
line
r.-hexane
The
id.
to
obtained
by
concentration
yield.
lock
considered
analysed the
and
initial
were
addition
(TMS)
recorded
using
accurate
to
sweep
Pt(CHs)zen(OH)z
as
270
and
coupling
IR
PS-100
Hz.
small
and
was
solid
This
its
a
a white
a yellow
?z-hexane.
width
+-O.Olppm
to
for
JEOL
activated
concentrated
by
a
with
product
of
on
treated
filtrate
was
precipitate.
the
ethylenediimine
NMR spectra
internal
and was
There
dropwise. 1 ine
ethanol
solution
product
bis-(salicylaldehyde) ‘H
in
precipitate
From
70%
added
microcrystal
the
added
in
be
off-white
filtration,
sol
chloroform
dissolved
obtained
to
an
off,
After
charcoal.
in
was
was confirmed
spectrum-
spectrometer
Chemical
on
shifts
constants
to
are
20.5
Hz.
References
1.
R.C.
Menzies,
2.
A.K.
Chatterjee,
J.
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(1928)
565
Henzies,
J.R.
Steel
Chem. R.C.
ar;d
F.N.
Youdale,
J.
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K.
Kite
and
M. R.
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J.R.
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J.R.
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J.R.
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J.R.
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J.E.
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M.R.
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