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Nickel(II) complexes of N,N′-dicyclohexyl- and N,N′-dibenzyl-dithiooxamide
INORG.
NUCL.
CHEM.
LETTERS
NICKEL(II)
Voh 8, pp. 299-303, 1972.
Pergamon
Press.
Printed
in
Great
Britain.
COMPLEXES OF N , N ' - D I C Y C L O H E X Y L - A N D
N~ N' -DIBENZYL-DITHIOOXAMIDE
G.C. Pellacani and G. Peyronel Istituto di Chimica Generale e Inorganica, Universit~ di Xodena Italy (Received 14 December 1971)
Dithiooxamide and N,N'-disubstituted
dithiooxamides in neu-
tral media generally give polymeric and insoluble (NIL) x complex es (1,2), while tetraethyldithiooxamide strong acid media dithiooxamide, xyethyl-dithiooxamide
does not react
(2). In
N,N'-dimethyl- and N,N'-dihydro
give S,N-coordinated low-spin complexes
NiL2X 2 (X=CI,Br,HS04,CI04)
(3), while tetramethyl- and tetra
ethyl-dithiooxamide give S,S-coordinated high-spin complexes NiL3(CI04) 2 (4). We investigated the nickel(II) N,N'-dicyclohexyl-
complexes of
(DCH2DH2) and dibenzyl-dithiooxamide (DBz2DH2)
in order to study the behaviour of these ligands with a greater st eric hindrance. All these complexes are well crystallized.
Those obtained
from HAc and a strong mineral acid are blue-violet and have the general stoichiometry NiL2X 2 (X:CI,Br,I,CIO 4 for DCH2DH 2; X=CI, ~r, CIO 4 for DBz2DH2).
The chlorides contain two molecules of HAc
in the stoichiometric unit. DCH2DH 2 give from neutral solutions a crystalline red complex Ni(DCH2DH)2.2EtOH,
ethanolic in which
two protons of the ligand molecules are substituted by the metal ion without forming a polymer, dithiooxamides
as they do in the case of other
(1,2). All the complexes are diamagnetic.
The I.R. spectra of these complexes, according to the assign ments given for the ligands
(5), indicate that nickel(ll)
299
is
NICKEL(II) COMPLEXES
300
S,N-eoordinated
to the ligands
other dithiooxamides split.
The increase
corresponds
as in the analogous
The v(CN)
in v(CN)
and ~(CS)
in V(CN)
and the increase
in v(CS)
The far I.R. bands of the ligands the complexes
of
(Table I) are
in v(CS)
S-bonded
to that half of the molecule N-bonded
complexes
bands
and the decrease
to that half of the molecule
The decrease sponds
(3).
Vol. 8, No. 3
frequencies
to the metal.
frequencies
to the metal
corre-
(3,6).
unaltered in -I in the region of 505-445 cm ,
which show new bands
are practically
assignable 342-290
to v(NiN) modes (3,9,10), and new bands in the region -I cm , assignable to v(NiS) modes (3,11,12).
As for the nickel(ll)
complexes
of other dithiooxamides (3), -I two new strong bands appear at 1200-1190 and 1125-1120 cm for the N i ( D C H 2 D H 2 ) X 2 complexes and apparently -I 1135 cm for the Ni(DBz2DH2)X 2 complexes. also appear
in other similar
modes being
enhanced
The electronic plexes
through nitrogen
Two bands may correspond
spectra
signments
complexes
symmetry
four directions
to the two differ-
15.2-16.0 k_K, which may
for a square
with chromophores
coordination [NiN2S 2] (13).
and ligand atoms pointing
intermediate
By using a correction ~ I (16)
to the xy axes
The a~
factor
•
in
(15) of 2800 cm -I the splitting
di~hiooxamides
t
(3)
This value
series of the
(~I in kK) as follows:
Dmtnmooxammde~18.4) < DCH2DH 2 = DBzDiI2(18.7) dithiooxamide(19.1)
to the metal
is 18.7 k~ for both perchiorates.
other S,N coordinating .
of the
(14).
places DCH2DH 2 and DBzDH 2 in the spectrochemical
~
stronger
of the d-d band in Table I are made by assuming a D2h
trams-planar
parameter
to V(RN)
(Table I) of these low-spin NiL2X 2 co~
as characteristic
low-spin Ni(ll)
which
of the ligand molecule.
show the first band in the range
be considered
These new bands,
(8), were assigned
by a complexation
than through sulphur. ently bonded halves
complexes
only one band at 1165-
< N,N'-dihydroxyethy~
< N,N'-dimethyldithiooxamide(19.6).
The complex Ni(DCH2DH)2"2EtOH
has identical
electronic
spec-
Vol. 8, No. 3
NICKEL(II) COMPLEXES
301
tra in the solid state and in CHCI 3 or pyridine solutions. dicates
that
This i~
even in the strong coordinating pyridine the complex
has the same c o o r d i n a t i o n as in the solid. tions show that the bamds at 18.7-19.1
The high molar
extinc-
and 20.2 kK are charge-
- t r a n s f e r rather than d-d in character. The I.R. bands of the p e r c h l o r a t e tion of this ion from T d symmetry n a t i v e axial
ion correspond to a deforma-
(7). Any possibility of a coord~
interaction on the metal may be excluded on account
of the good constancy of the d-d bands of the complexes of the same ligand,
irrespective of the anions.
tion may be better
The p e r c h l o r a t e deforma-
explained as being due to an electrostatic
teraction of this ion either with the metal with a positively
in-
ion or, more probably,
charged HHN-group of the coordinated ligand
(3).
This i n t e r a c t i o n may also take place for the other anions CI-,Br-, I-, since the I.R. and the electronic spectra of these complexes are very similar. Experimental All reagents were of the best chemical grade. Acid used: HAc(glacial),
HCI(37%),
HBr(48%),
HI(57%),
HCI04(60%).
For the
p r e p a r a t i o n of the complexes Ni acetate and the ligand were separately dissolved
in glacial HAc containing the mineral
ratio of about 9:1.
The nickel
the solution of the ligand.
solution was added at about 60 ° to
P r e c i p i t a t i o n was instantaneous
cept for N i ( D C H 2 D H 2 ) 2 C I 2 . 2 H A c
in air. N i ( D B z 2 D H 2 ) 2 C I 2 . 2 H ~ c
was obtained only from glacial HAc containing about
10% of anhy-
N i ( D C H 2 D H ) 2 - 2 E t 0 H was prepared by m i x i n g the Et0H sol~
tions of Ni acetate and of the iigand and p r e c i p i t a t e s Table
ex-
(12 h.) and N i ( D B z 2 D H 2 ) 2 C I 2 . 2 H A c
(72 ~), which are also very unstable
drous HCI.
acid in the
in the molar ratio M:L=I:7,
in 48 h at 5°C. Analytical results are given in
I.
~dagne~=c susceptibilities
were measured and infrared and elec-
302
NICKEL(II)
COMPLEXES
V o l . 8, N o . 3
E~ C~
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r'~ O0
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(1)
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No 4~ %
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0.~00 ~'~'- 0 0000
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O~ 0 CO~D CO ~."-
~O ~ 00~0 O0 b~
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0 L~ b--- r ~ CO O0
0 0~1 t"~ O~ COCO
"d
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~
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~ 0
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c,.I
,rO"5
.,..4
O O
Vol. 8, No. 3
NICKEL(II) COMPLEXES
303
~ronic spectra were recorded by conventional methods as previously described
(3). Acknowl ed~em ent s
This work was supported by financial aid from the Consiglio Nazionale delle Ricerche of Italy. References I. P.Ray and R.M.Ray,
J.Indian Chem. Soc.,_3,
2. R.N.Hurd, G.De La Mater, G.C.~cElheny Chem. Soc., 84, 4454 (1960). 3. G.Peyronel, in press.
G.C.Pellacami
A.Pigmedoli
5. H.0.Desseyn and ~.A.Herman,
7. I.M.Procter, (1968).
B.J.Hataway
Inorg. Chim.Acta,
and G.Benetti,
Spectrochim.Acta,
amd P.Nicholls, and Z.A.Hermam,
9. J.R.During and D.W.Wertz,
11. D.M.Adams
23A, 2457 (1967)
and J.B.Cornell,
Inorg. Chem., 8_, 2341
J.Chem. Soc.(A),
25A,
22, 627 (1968). (1969).
1299 (1968).
13. G.Battistoni, C.Mattogno, A.Monaci and F.Tarli, Chem. Letters, 7, 981 (1971).
Trans.Metal
1678
Spectrochim.Acta,
12. D.C,.Adams, "Metal-Ligand and Related Vibrations", Publ., London 1967, p.325.
15. H.B.Gray,
Inorg.
J.Chem. Soc.(A),
Appl. Spectroscopy,
Lakshmi and U.Agarwala,
14. O.Siiman and J.Fresco,
J.Am.
J.Inorg.Nucl. Chem., 29, 2787 (1967).
8. H.0.Desseyn, W.A.Jacobs i685 (1968).
10. B.Singh,
and L.V.Peiffer,
and A.Pigmedoli,
4. G.Peyronel, G.C.Pel!acami, Chim.Acta, 5, 263 (1971).
6. S.C.Jain and R.Rivest,
118 (1926).
E.Arnold
Inorg.Nucl.
J.Am. Chem. Soc., 92, 2652 (1970). Chem., 1, 278 (1965).
16. H.B.Gray and C.J.Ballhausen,
J.Am. Chem. Soe., 85, 260 (1963).
NUCL.
CHEM.
LETTERS
NICKEL(II)
Voh 8, pp. 299-303, 1972.
Pergamon
Press.
Printed
in
Great
Britain.
COMPLEXES OF N , N ' - D I C Y C L O H E X Y L - A N D
N~ N' -DIBENZYL-DITHIOOXAMIDE
G.C. Pellacani and G. Peyronel Istituto di Chimica Generale e Inorganica, Universit~ di Xodena Italy (Received 14 December 1971)
Dithiooxamide and N,N'-disubstituted
dithiooxamides in neu-
tral media generally give polymeric and insoluble (NIL) x complex es (1,2), while tetraethyldithiooxamide strong acid media dithiooxamide, xyethyl-dithiooxamide
does not react
(2). In
N,N'-dimethyl- and N,N'-dihydro
give S,N-coordinated low-spin complexes
NiL2X 2 (X=CI,Br,HS04,CI04)
(3), while tetramethyl- and tetra
ethyl-dithiooxamide give S,S-coordinated high-spin complexes NiL3(CI04) 2 (4). We investigated the nickel(II) N,N'-dicyclohexyl-
complexes of
(DCH2DH2) and dibenzyl-dithiooxamide (DBz2DH2)
in order to study the behaviour of these ligands with a greater st eric hindrance. All these complexes are well crystallized.
Those obtained
from HAc and a strong mineral acid are blue-violet and have the general stoichiometry NiL2X 2 (X:CI,Br,I,CIO 4 for DCH2DH 2; X=CI, ~r, CIO 4 for DBz2DH2).
The chlorides contain two molecules of HAc
in the stoichiometric unit. DCH2DH 2 give from neutral solutions a crystalline red complex Ni(DCH2DH)2.2EtOH,
ethanolic in which
two protons of the ligand molecules are substituted by the metal ion without forming a polymer, dithiooxamides
as they do in the case of other
(1,2). All the complexes are diamagnetic.
The I.R. spectra of these complexes, according to the assign ments given for the ligands
(5), indicate that nickel(ll)
299
is
NICKEL(II) COMPLEXES
300
S,N-eoordinated
to the ligands
other dithiooxamides split.
The increase
corresponds
as in the analogous
The v(CN)
in v(CN)
and ~(CS)
in V(CN)
and the increase
in v(CS)
The far I.R. bands of the ligands the complexes
of
(Table I) are
in v(CS)
S-bonded
to that half of the molecule N-bonded
complexes
bands
and the decrease
to that half of the molecule
The decrease sponds
(3).
Vol. 8, No. 3
frequencies
to the metal.
frequencies
to the metal
corre-
(3,6).
unaltered in -I in the region of 505-445 cm ,
which show new bands
are practically
assignable 342-290
to v(NiN) modes (3,9,10), and new bands in the region -I cm , assignable to v(NiS) modes (3,11,12).
As for the nickel(ll)
complexes
of other dithiooxamides (3), -I two new strong bands appear at 1200-1190 and 1125-1120 cm for the N i ( D C H 2 D H 2 ) X 2 complexes and apparently -I 1135 cm for the Ni(DBz2DH2)X 2 complexes. also appear
in other similar
modes being
enhanced
The electronic plexes
through nitrogen
Two bands may correspond
spectra
signments
complexes
symmetry
four directions
to the two differ-
15.2-16.0 k_K, which may
for a square
with chromophores
coordination [NiN2S 2] (13).
and ligand atoms pointing
intermediate
By using a correction ~ I (16)
to the xy axes
The a~
factor
•
in
(15) of 2800 cm -I the splitting
di~hiooxamides
t
(3)
This value
series of the
(~I in kK) as follows:
Dmtnmooxammde~18.4) < DCH2DH 2 = DBzDiI2(18.7) dithiooxamide(19.1)
to the metal
is 18.7 k~ for both perchiorates.
other S,N coordinating .
of the
(14).
places DCH2DH 2 and DBzDH 2 in the spectrochemical
~
stronger
of the d-d band in Table I are made by assuming a D2h
trams-planar
parameter
to V(RN)
(Table I) of these low-spin NiL2X 2 co~
as characteristic
low-spin Ni(ll)
which
of the ligand molecule.
show the first band in the range
be considered
These new bands,
(8), were assigned
by a complexation
than through sulphur. ently bonded halves
complexes
only one band at 1165-
< N,N'-dihydroxyethy~
< N,N'-dimethyldithiooxamide(19.6).
The complex Ni(DCH2DH)2"2EtOH
has identical
electronic
spec-
Vol. 8, No. 3
NICKEL(II) COMPLEXES
301
tra in the solid state and in CHCI 3 or pyridine solutions. dicates
that
This i~
even in the strong coordinating pyridine the complex
has the same c o o r d i n a t i o n as in the solid. tions show that the bamds at 18.7-19.1
The high molar
extinc-
and 20.2 kK are charge-
- t r a n s f e r rather than d-d in character. The I.R. bands of the p e r c h l o r a t e tion of this ion from T d symmetry n a t i v e axial
ion correspond to a deforma-
(7). Any possibility of a coord~
interaction on the metal may be excluded on account
of the good constancy of the d-d bands of the complexes of the same ligand,
irrespective of the anions.
tion may be better
The p e r c h l o r a t e deforma-
explained as being due to an electrostatic
teraction of this ion either with the metal with a positively
in-
ion or, more probably,
charged HHN-group of the coordinated ligand
(3).
This i n t e r a c t i o n may also take place for the other anions CI-,Br-, I-, since the I.R. and the electronic spectra of these complexes are very similar. Experimental All reagents were of the best chemical grade. Acid used: HAc(glacial),
HCI(37%),
HBr(48%),
HI(57%),
HCI04(60%).
For the
p r e p a r a t i o n of the complexes Ni acetate and the ligand were separately dissolved
in glacial HAc containing the mineral
ratio of about 9:1.
The nickel
the solution of the ligand.
solution was added at about 60 ° to
P r e c i p i t a t i o n was instantaneous
cept for N i ( D C H 2 D H 2 ) 2 C I 2 . 2 H A c
in air. N i ( D B z 2 D H 2 ) 2 C I 2 . 2 H ~ c
was obtained only from glacial HAc containing about
10% of anhy-
N i ( D C H 2 D H ) 2 - 2 E t 0 H was prepared by m i x i n g the Et0H sol~
tions of Ni acetate and of the iigand and p r e c i p i t a t e s Table
ex-
(12 h.) and N i ( D B z 2 D H 2 ) 2 C I 2 . 2 H A c
(72 ~), which are also very unstable
drous HCI.
acid in the
in the molar ratio M:L=I:7,
in 48 h at 5°C. Analytical results are given in
I.
~dagne~=c susceptibilities
were measured and infrared and elec-
302
NICKEL(II)
COMPLEXES
V o l . 8, N o . 3
E~ C~
•
r'~ O0
0
~oo~
~
co
~
~
0
O~
C~
~
o
,.a O~
I '~" 0 r~
oo
•H
I:1=1 v
O % 4~
o
;
(1)
0
~
r'~
O~
O0
~.~
L~,
~
L~
Lr~
C~ ,--
I
m -,-t
~ LID
~
v
~ m
m
~
~ 0
~ 0
~ 0
~
~
O ~ P-4
c/
•H
£
No 4~ %
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r..)
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C~
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g
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.~
I>
o
O
c,.I
,rO"5
.,..4
O O
Vol. 8, No. 3
NICKEL(II) COMPLEXES
303
~ronic spectra were recorded by conventional methods as previously described
(3). Acknowl ed~em ent s
This work was supported by financial aid from the Consiglio Nazionale delle Ricerche of Italy. References I. P.Ray and R.M.Ray,
J.Indian Chem. Soc.,_3,
2. R.N.Hurd, G.De La Mater, G.C.~cElheny Chem. Soc., 84, 4454 (1960). 3. G.Peyronel, in press.
G.C.Pellacami
A.Pigmedoli
5. H.0.Desseyn and ~.A.Herman,
7. I.M.Procter, (1968).
B.J.Hataway
Inorg. Chim.Acta,
and G.Benetti,
Spectrochim.Acta,
amd P.Nicholls, and Z.A.Hermam,
9. J.R.During and D.W.Wertz,
11. D.M.Adams
23A, 2457 (1967)
and J.B.Cornell,
Inorg. Chem., 8_, 2341
J.Chem. Soc.(A),
25A,
22, 627 (1968). (1969).
1299 (1968).
13. G.Battistoni, C.Mattogno, A.Monaci and F.Tarli, Chem. Letters, 7, 981 (1971).
Trans.Metal
1678
Spectrochim.Acta,
12. D.C,.Adams, "Metal-Ligand and Related Vibrations", Publ., London 1967, p.325.
15. H.B.Gray,
Inorg.
J.Chem. Soc.(A),
Appl. Spectroscopy,
Lakshmi and U.Agarwala,
14. O.Siiman and J.Fresco,
J.Am.
J.Inorg.Nucl. Chem., 29, 2787 (1967).
8. H.0.Desseyn, W.A.Jacobs i685 (1968).
10. B.Singh,
and L.V.Peiffer,
and A.Pigmedoli,
4. G.Peyronel, G.C.Pel!acami, Chim.Acta, 5, 263 (1971).
6. S.C.Jain and R.Rivest,
118 (1926).
E.Arnold
Inorg.Nucl.
J.Am. Chem. Soc., 92, 2652 (1970). Chem., 1, 278 (1965).
16. H.B.Gray and C.J.Ballhausen,
J.Am. Chem. Soe., 85, 260 (1963).