- Email: [email protected]
Nickel(II) heterochelates
|NOEG.
NUCI..
CHEM.
LETTERS
¥oL
4,
pp.
625-629,
NICKEL(II)
1968.
Pergamon Press.
Printed in
Great
Britain.
HETEROCHELATES*
A. Syamal Dept. of Chemistry, Emory University Atlanta, Georgia 30322, U.S.A. ~R~,d1!
July 1968)
As a part of our work on the synthesis, resolution and kinetic metals
characterization,
studies on heterochelates
of transition
(1-7), this communication reports the synthesis of some
nickel(ll)
heterochelates,
orthophenanthroline
the ligands used being picolylamine,
and ~ - ~ ' - d i p y r i d y l
having N-C-C-N chelating
group in common. Heterochelate
complexes
of metal ions may be readily
thesized provided that the complexes are inert.
syn-
A number of
working schemes could be conceived so as to lead to such synthesis: (i)
The addition of bidentate
ligand(s)
to the mono or bis
complex. (2)
The breaking o f ~ - d i o l
type complex by a bidentate
ligand at a suitable pH. (3)
Ligand exchange in the tris complex.
(4)
Direct synthesis.
Whereas
the third and fourth schemes are in exploratory
stage in
this laboratory for the synthesis of Mn(lll), Fe(III),V(IV) Mo(VI) heterochelates,
and
the outcomes of the first and second schemes
have been reported earlier
(1-7).
In the present work the first
scheme has been utilized for the synthesis of nickel(ll)
This work was carried out at the Dept. of Burdwan, Burdwan, India.
625
of Chemistry,
heteroche-
University
(P21
lates.
HICKEL(II) HI[TIEROCHELATIES
Y*I. 4, He. 10
The probable drawback for the isolation of heterochelate
complexes is the danger of formation of homochelate However, thls difficulty
complexes.
could be overcome by working at a suit-
able pH and under controlled conditions. Dichloro mono-plcolylamlno react wlth two molecules orthophenanthrollne,
nlckel(II)
(8) has been found to
of strongly chelating llgands such'as
0(- ~'-dlpyrldyl,
etc. in methanol solution
at the temperature of steam bath, resulting In the formation of new nlckel(II)
heterochelate
complexes.
In aqueous medium indicate bl-unlvalent
Conductance measurements nature of the complexes.
The room temperature magnetic susceptiblllty measurements were done on solid specimens In a Gouy Balance and the complexes were found to be paramagnetlc
(~B
= 2.9 - 3.i B.M.).
The electronic
absorption spectra In aqueous solution were recorded In the range 10,000 ~ 25,000 cm "l In a Hllger Uvispeck Spectrophotometer
using
one cm. cells and the complexes were found to exhibit bands around 12,600 cm -1 and 19,200 cm -1.
The appearance of these two
bands wlth low intensity Is typical of octahedral nlckel(II) plexes
(9, 10).
com-
The complexes are quite stable In the solid state~
being not decomposed on heating at 120°C for hours.
The colour
of these complexes Is plnk In contrast to the bright green colour of the he~a-aquo nlckel(II)
ion.
Thls Is because of shifts in
the absorption bands when aquo molecules are replaced by strong field llgands llke plcolylamlne dlpyrldyl.
and orthophenanthroline
or
~-~'-
Magnetic moments are also In accord with the octahed-
ral configuration
(9, 10).
Equivalent weights of the complexes were determined by runnlng the aqueous solutions through H + form of a cation exchange resin (Amberllte IR 120) column and then tltratlng the eluate wlth standard NaOH.
Equivalent weight values agree well wlth the the-
%N
%ci
Analytical results
%Ni
8.57 12.20 10.31 13.08
Reqd:
318
350
315
344
Found Reqd~*
235
230
Molar conductance *** mhos ~m 2 mole -~
2.95
3.11
Magnetic moment (B.M.) T=3030
11.5
19,420 I19,230-
Chemistry", Prentice Hail, 1964, p-254.).
*** Expected range of A M for 1:2 electrolyte is 225-270 mhos (M. M. Jones,
"Elementary Coordination
** These values have been deduced on the basis of elemental analysis and conductance measurements.
7.0
6.8
12,50012,660
12,50012,660
11.3
&nee
Molar absorb-
19,230
~ max cm-i
* The water is lost in all cases at IIO°C and hence it is outside the coordination zone.
= orthophenanthroline and dipy : c-~'-dipyridyl.
9.35 13.31 11.25 12.83
Found: 9.21 13.20 LI.O0 12.42
Reqd:
where Pic-am = picolylamine;ophen
4.5 H20
[Ni(Pic-am)(dipY)2]Cl ~"
5H20
Equivalent
0* weight
[Ni(Pic-am)(ophen)2]Cl 2- Found: 8.32 12.41 I0.I0 13.47
Compound
Analysis, Molar Conductance, Equivalent Weight, Magnetic Moment and Spectral Character of Nickel(II) Heterochelates
TABLE I
-4
p-
o
m
x
m r
R
z
62B
HICKEL(II) HETEROCHELATES
Yoh 4, No. 10
oretical values. The analysis,
electrical
spectral characteristics heterochelates
and magnetic moments of the nickel(ll)
data alone does not preclude the possibility
of homochelated
when the heterochelate nickel(ll)
equivalent weight,
are given in Table i.
Analytical 2:1 mixtures
conductance,
tris complexes.
picolylamino
of
It was observed that
bis(ortho-phenanthroline)
chloride was dissolved in 3N HCI, the original red col-
our gradually turned blue and on standing deposited blue shining crystals of bis(ortho-phenanthroline)nickel(ll) hydrate.
~ Found:
17,860 cm -I. CI, 1 2 . 2 4 ~ nickel(ll) cm -I.
Ni, 10.22; N, 9.60; CI, 12.02~;
[Ni(phen)2 .
chloride penta~max
=
C12]. 5H20 requires Ni, 10.17; N, 9.65;
x '-dipyridyl
The mono oft ho-phenanthroline/
ion usually absorbs
(ii, 12) around 16,390 - 16,660
In 3N H2S0 ~ solution the heterochelate
[Ni(Pic-am)(ophen)2]Cl 2.
5H20 exhibits a peak around 18,510 cm -I, it shifts further to 16,660 cm -I in 5N H2SO 4 solution and still retains the blue colour. These changes on increasing acid concentration the presence
is reminiscent with
of firstly a bis and then a mono ortho-phenanthroline/
-~' -dipyridyl complex of nickel(ll)
(11,12).
Experimental Dichloro mono-picolylamino
nickel(ll)monohydrate
was prepared
according to the method presented by Utsuno and Sone (8). General method of syntheses
of the nickel(ll)
Dichloro mono-picolylamino
nickel(ll)monohydrate
mole) and o r t h o p h e n a n t h r o l i n e / ~ - ~ ' - d i p y r i d y l dissolved separately
heterochelates: (i.3 g, one
(two moles) were
in minimum amount of methanol.
These two
solutions were then mixed and the resulting pink solution was refluxed on a steam bath for half an hour.
The solution was then
Voh 4, He. 10
FIICKEL(II) HETEROCHELATES
629
cooled and to this was added few millilitres The separated imum amount
pink crystals
of methanol
washed with ether. solid CaCI 2.
were filtered
of ether with stirring.
off, redissolved
and again precipitated
with ether and
The compounds were dried in a desiccator
over
Yield = 70%.
Further work on similar other nic~el(ll) copper(ll)
in min-
heterochelates
and.corresponding
is in progress.
Acknowledgement~s: The author wishes Dutta of Department U.S.A.,
to record his heartfelt
of Chemistry,
for keen interest
thanks to Dr. R. L.
Ohio State University,
and constant
Columbus,
encouragement.
References i.
R. L. DUTTA and A. SYAMAL, (1965).
J. Inorg.
Nucl.
Chem.,
2.
R. L. DUTTA and A. SYAMAL,
Coord.
3.
R. L. DUTTA, 526 (1966).
A. SYAMAL and S. GHOSH,
4.
R. L. DUTTA,
D. DE and A. SYAMAL,
5.
A. SYAMAL,
6.
R. L. DUTTA and A. SYAMAL,
7.
A. SYAMAL, et al., Ind. J. Chem., (India), (in press).
8.
S. UTSUNO and K. SONE, Bull.
9.
C. J. BALLHAUSEN, Introduction to Ligand Field Theory, Hill Book Co., I n ~ . ] - ~ Y - ~ 7 3~-[ ~
Chem. Revs.,
2_~7, 2447
2, 441 (1967).
J. Ind. Chem.
ibid,
Soc.,
43,
4~4, 353 (1967).
ibid, 45, 74 (1968). ibid, 45, 219, 226 (1968).
Chem.
(in press);
J. Inst.
Soc., Japan,
Chem.
37, 1038
(1964).
McGraw
i0.
F. A. COTTON and G. WILKINSON, Advanced Inor@anic Chemistry, Interscience Publishers, Inc., New York, 735 (1962).
Ii.
F. BASOL0, J. C. HAYES and H.M. NEUMANN, 5102 (1953).
12.
R. G. WILKINS and M. J. G. WILLIAMS, P. ELLIS, R. HOGG and R. G. WILKINS~
J. Am. Chem.
J. Chem. J. Chem.
Soc., Soc.,
Soc.,
7_~5,
4514 (1957), 3308 (1959).
NUCI..
CHEM.
LETTERS
¥oL
4,
pp.
625-629,
NICKEL(II)
1968.
Pergamon Press.
Printed in
Great
Britain.
HETEROCHELATES*
A. Syamal Dept. of Chemistry, Emory University Atlanta, Georgia 30322, U.S.A. ~R~,d1!
July 1968)
As a part of our work on the synthesis, resolution and kinetic metals
characterization,
studies on heterochelates
of transition
(1-7), this communication reports the synthesis of some
nickel(ll)
heterochelates,
orthophenanthroline
the ligands used being picolylamine,
and ~ - ~ ' - d i p y r i d y l
having N-C-C-N chelating
group in common. Heterochelate
complexes
of metal ions may be readily
thesized provided that the complexes are inert.
syn-
A number of
working schemes could be conceived so as to lead to such synthesis: (i)
The addition of bidentate
ligand(s)
to the mono or bis
complex. (2)
The breaking o f ~ - d i o l
type complex by a bidentate
ligand at a suitable pH. (3)
Ligand exchange in the tris complex.
(4)
Direct synthesis.
Whereas
the third and fourth schemes are in exploratory
stage in
this laboratory for the synthesis of Mn(lll), Fe(III),V(IV) Mo(VI) heterochelates,
and
the outcomes of the first and second schemes
have been reported earlier
(1-7).
In the present work the first
scheme has been utilized for the synthesis of nickel(ll)
This work was carried out at the Dept. of Burdwan, Burdwan, India.
625
of Chemistry,
heteroche-
University
(P21
lates.
HICKEL(II) HI[TIEROCHELATIES
Y*I. 4, He. 10
The probable drawback for the isolation of heterochelate
complexes is the danger of formation of homochelate However, thls difficulty
complexes.
could be overcome by working at a suit-
able pH and under controlled conditions. Dichloro mono-plcolylamlno react wlth two molecules orthophenanthrollne,
nlckel(II)
(8) has been found to
of strongly chelating llgands such'as
0(- ~'-dlpyrldyl,
etc. in methanol solution
at the temperature of steam bath, resulting In the formation of new nlckel(II)
heterochelate
complexes.
In aqueous medium indicate bl-unlvalent
Conductance measurements nature of the complexes.
The room temperature magnetic susceptiblllty measurements were done on solid specimens In a Gouy Balance and the complexes were found to be paramagnetlc
(~B
= 2.9 - 3.i B.M.).
The electronic
absorption spectra In aqueous solution were recorded In the range 10,000 ~ 25,000 cm "l In a Hllger Uvispeck Spectrophotometer
using
one cm. cells and the complexes were found to exhibit bands around 12,600 cm -1 and 19,200 cm -1.
The appearance of these two
bands wlth low intensity Is typical of octahedral nlckel(II) plexes
(9, 10).
com-
The complexes are quite stable In the solid state~
being not decomposed on heating at 120°C for hours.
The colour
of these complexes Is plnk In contrast to the bright green colour of the he~a-aquo nlckel(II)
ion.
Thls Is because of shifts in
the absorption bands when aquo molecules are replaced by strong field llgands llke plcolylamlne dlpyrldyl.
and orthophenanthroline
or
~-~'-
Magnetic moments are also In accord with the octahed-
ral configuration
(9, 10).
Equivalent weights of the complexes were determined by runnlng the aqueous solutions through H + form of a cation exchange resin (Amberllte IR 120) column and then tltratlng the eluate wlth standard NaOH.
Equivalent weight values agree well wlth the the-
%N
%ci
Analytical results
%Ni
8.57 12.20 10.31 13.08
Reqd:
318
350
315
344
Found Reqd~*
235
230
Molar conductance *** mhos ~m 2 mole -~
2.95
3.11
Magnetic moment (B.M.) T=3030
11.5
19,420 I19,230-
Chemistry", Prentice Hail, 1964, p-254.).
*** Expected range of A M for 1:2 electrolyte is 225-270 mhos (M. M. Jones,
"Elementary Coordination
** These values have been deduced on the basis of elemental analysis and conductance measurements.
7.0
6.8
12,50012,660
12,50012,660
11.3
&nee
Molar absorb-
19,230
~ max cm-i
* The water is lost in all cases at IIO°C and hence it is outside the coordination zone.
= orthophenanthroline and dipy : c-~'-dipyridyl.
9.35 13.31 11.25 12.83
Found: 9.21 13.20 LI.O0 12.42
Reqd:
where Pic-am = picolylamine;ophen
4.5 H20
[Ni(Pic-am)(dipY)2]Cl ~"
5H20
Equivalent
0* weight
[Ni(Pic-am)(ophen)2]Cl 2- Found: 8.32 12.41 I0.I0 13.47
Compound
Analysis, Molar Conductance, Equivalent Weight, Magnetic Moment and Spectral Character of Nickel(II) Heterochelates
TABLE I
-4
p-
o
m
x
m r
R
z
62B
HICKEL(II) HETEROCHELATES
Yoh 4, No. 10
oretical values. The analysis,
electrical
spectral characteristics heterochelates
and magnetic moments of the nickel(ll)
data alone does not preclude the possibility
of homochelated
when the heterochelate nickel(ll)
equivalent weight,
are given in Table i.
Analytical 2:1 mixtures
conductance,
tris complexes.
picolylamino
of
It was observed that
bis(ortho-phenanthroline)
chloride was dissolved in 3N HCI, the original red col-
our gradually turned blue and on standing deposited blue shining crystals of bis(ortho-phenanthroline)nickel(ll) hydrate.
~ Found:
17,860 cm -I. CI, 1 2 . 2 4 ~ nickel(ll) cm -I.
Ni, 10.22; N, 9.60; CI, 12.02~;
[Ni(phen)2 .
chloride penta~max
=
C12]. 5H20 requires Ni, 10.17; N, 9.65;
x '-dipyridyl
The mono oft ho-phenanthroline/
ion usually absorbs
(ii, 12) around 16,390 - 16,660
In 3N H2S0 ~ solution the heterochelate
[Ni(Pic-am)(ophen)2]Cl 2.
5H20 exhibits a peak around 18,510 cm -I, it shifts further to 16,660 cm -I in 5N H2SO 4 solution and still retains the blue colour. These changes on increasing acid concentration the presence
is reminiscent with
of firstly a bis and then a mono ortho-phenanthroline/
-~' -dipyridyl complex of nickel(ll)
(11,12).
Experimental Dichloro mono-picolylamino
nickel(ll)monohydrate
was prepared
according to the method presented by Utsuno and Sone (8). General method of syntheses
of the nickel(ll)
Dichloro mono-picolylamino
nickel(ll)monohydrate
mole) and o r t h o p h e n a n t h r o l i n e / ~ - ~ ' - d i p y r i d y l dissolved separately
heterochelates: (i.3 g, one
(two moles) were
in minimum amount of methanol.
These two
solutions were then mixed and the resulting pink solution was refluxed on a steam bath for half an hour.
The solution was then
Voh 4, He. 10
FIICKEL(II) HETEROCHELATES
629
cooled and to this was added few millilitres The separated imum amount
pink crystals
of methanol
washed with ether. solid CaCI 2.
were filtered
of ether with stirring.
off, redissolved
and again precipitated
with ether and
The compounds were dried in a desiccator
over
Yield = 70%.
Further work on similar other nic~el(ll) copper(ll)
in min-
heterochelates
and.corresponding
is in progress.
Acknowledgement~s: The author wishes Dutta of Department U.S.A.,
to record his heartfelt
of Chemistry,
for keen interest
thanks to Dr. R. L.
Ohio State University,
and constant
Columbus,
encouragement.
References i.
R. L. DUTTA and A. SYAMAL, (1965).
J. Inorg.
Nucl.
Chem.,
2.
R. L. DUTTA and A. SYAMAL,
Coord.
3.
R. L. DUTTA, 526 (1966).
A. SYAMAL and S. GHOSH,
4.
R. L. DUTTA,
D. DE and A. SYAMAL,
5.
A. SYAMAL,
6.
R. L. DUTTA and A. SYAMAL,
7.
A. SYAMAL, et al., Ind. J. Chem., (India), (in press).
8.
S. UTSUNO and K. SONE, Bull.
9.
C. J. BALLHAUSEN, Introduction to Ligand Field Theory, Hill Book Co., I n ~ . ] - ~ Y - ~ 7 3~-[ ~
Chem. Revs.,
2_~7, 2447
2, 441 (1967).
J. Ind. Chem.
ibid,
Soc.,
43,
4~4, 353 (1967).
ibid, 45, 74 (1968). ibid, 45, 219, 226 (1968).
Chem.
(in press);
J. Inst.
Soc., Japan,
Chem.
37, 1038
(1964).
McGraw
i0.
F. A. COTTON and G. WILKINSON, Advanced Inor@anic Chemistry, Interscience Publishers, Inc., New York, 735 (1962).
Ii.
F. BASOL0, J. C. HAYES and H.M. NEUMANN, 5102 (1953).
12.
R. G. WILKINS and M. J. G. WILLIAMS, P. ELLIS, R. HOGG and R. G. WILKINS~
J. Am. Chem.
J. Chem. J. Chem.
Soc., Soc.,
Soc.,
7_~5,
4514 (1957), 3308 (1959).