Luminescent property and catalytic activity of Ru(II) carbonyl complexes containing N, O donor of 2-hydroxy-1-naphthylideneimines

Article abstract of DOI:10.1016/j.saa.2006.03.017

The reaction of the chelating ligands (obtained by the condensation of 2-hydroxy-1-naphthaldehyde with various primary amines) with [RuHCl(CO)(EPh₃)₂(B)] (where E = P; B = PPh₃, py or pip: E = As; B = AsPh₃) in

Full text of DOI:10.1016/j.saa.2006.03.017

Spectrochimica Acta Part A 66 (2007) 427–433
Luminescent property and catalytic activity of Ru(II) carbonyl complexes
containing N, O donor of 2-hydroxy-1-naphthylideneimines
M. Sivagamasundari, R. Ramesh^∗
School of Chemistry, Bharathidasan University, Tiruchirappalli 620 024, India
Received 17 August 2005; received in revised form 6 March 2006; accepted 22 March 2006
Abstract
The reaction of the chelating ligands (obtained by the condensation of 2-hydroxy-1-naphthaldehyde with various primary amines) with
[RuHCl(CO)(EPh₃)₂(B)] (where E = P; B = PPh₃, py or pip: E = As; B = AsPh₃) in benzene afforded new stable ruthenium(II) carbonyl complexes
of the general formula [Ru(Cl)(CO)(EPh₃)(B)(L)] (L = anion of bidentate Schiff bases). The structure of the new complexes was investigated using
elemental analyses, spectral (FT–IR, UV–vis and ¹H NMR) and electrochemical studies and is found to be octahedral. All the metal complexes
exhibit characteristic MLCT absorption and luminescence bands in the visible region. The luminescence efficiency of the ruthenium(II) complexes
was explained based on the ligand environment around the metal ion. These complexes catalyze oxidation of primary and secondary alcohols into
their corresponding carbonyl compounds in the presence of N-methylmorpholine-N-oxide (NMO) as the source of oxygen. The formation of high
valent Ru^IV = O species as a catalytic intermediate is proposed for the catalytic process.
© 2006 Elsevier B.V. All rights reserved.
Keywords: Ru(II) carbonyl complexes; Synthesis; Characterization; Luminescence; Oxidation
1. Introduction
of ruthenium(II) complexes containing Schiff bases is not well
developed.
Multidentate ligands are extensively used in coordination
chemistry, since they can be applied in the construction of new
frameworks with interesting properties [1]. Among these ligands
the linear or cyclic Schiff bases obtained by the condensation
of primary amines with carbonyl compounds and their metal
complexes find a variety of applications including biological,
clinical, analytical and industrial, in addition to their impor-
tant role in catalysis and organic synthesis [2,3]. The central
metal ion in these complexes act as active sites and thereby suc-
cessfully catalyzes chemical reactions [4,5]. Metal-ligand lumi-
nescence probes with microsecond decay time have numerous
potential applications in the biophysical and clinical sciences.
Ruthenium(II) MLCT compounds display long luminescence
life time and are extremely photo stable [6,7]. Recently light-
emittingdevices(LED)basedonthesmallmoleculeliketris-2,2^ꢀ
bipyridyl ruthenium(II) were demonstrated [8]. In contrast to
the considerable growth of literature on the chemistry of ruthe-
nium bi or polypyridyl complexes, the luminescent chemistry
The catalytic conversion of primary and secondary alco-
hols into their corresponding aldehydes and ketones is an
essential reaction in organic synthesis. Traditional methods
for performing such transformation generally involve the use
of stoichiometric quantities of inorganic oxidants like Cr(VI)
and generate large quantities of waste. The development of
effective, greener catalytic systems that use clean and inexpen-
sive oxidants is an important challenge [9]. The Schiff base
transition metal complexes are attractive oxidation catalysts
because of their cheap, easy synthesis and their chemical
and thermal stability [10]. Ruthenium complexes have been
extensively investigated as catalysts for alcohol oxidation in
combination with various oxidants such as dioxygen [11],
iodosobenzene [12], t-BuOOH [13], H₂O₂ [14] and NMO [15].
Further the catalytic activities of ruthenium complexes con-
taining tertiary phosphine or arsine ligands are well established
[16,17].
Therefore, in continuation of our interest in synthesis of new
ruthenium compounds [18–20], we describe here the synthesis,
characterization, luminescent and redox properties of ruthe-
nium(II) complexes containing bidentate Schiff bases along
with their catalytic activity towards oxidation of organic sub-
∗
Corresponding author. Tel.: +91 431 2407035; Fax: +91 431 2407045/20.
E-mail address: ramesh bdu@yahoo.com (R. Ramesh).
1386-1425/$ – see front matter © 2006 Elsevier B.V. All rights reserved.
doi:10.1016/j.saa.2006.03.017

428
M. Sivagamasundari, R. Ramesh / Spectrochimica Acta Part A 66 (2007) 427–433
2.4. Synthesis of Ru(II) carbonyl complexes
All operations were carried out under strictly anhydrous
conditions. All the new complexes were prepared by the fol-
lowing general procedure. To a preheated benzene (20 cm³)
solution of [RuHCl(CO)(EPh₃)₃] (where E = P or As) or
[RuHCl(CO)(PPh₃)₂(B)] (where B = PPh₃, py or pip) (76.9–
108.4 mg; 0.1 mmol) the Schiff base (16.9–32.6 mg; 0.1 mmol)
(HL1-HL4) was added slowly. The solution was refluxed for 5 h
until the mixture gradually changed to deep color. The solution
mixture was concentrated to ca. 3 cm³ under reduced pressure
and cooled. The complex separated out upon the addition of
petroleum ether (60–80 ^◦C). The solid was filtered off washed
with petroleum ether and recrystallised from CH₂Cl₂/petroleum
ether and dried under vacuum. The purity of the compounds was
checked by TLC.
Scheme 1. Structure of the bidentate Schiff bases.
strates in the presence of NMO. The bidentate Schiff bases were
derived from the condensation of 2-hydroxy-1-naphthaldehyde
with methylamine, cyclohexylamine, 2-aminopyridine and 4-
bromoaniline. The Schiff bases used to prepare the new ruthe-
nium(II) complexes were shown in Scheme 1.
2. Experimental
2.1. Materials
2.5. Catalytic oxidation of alcohol
All the reagents used were chemically pure and AR grade.
Solvents were purified and dried according to standard pro-
cedure. RuCl₃·3H₂O was purchased from Loba Chemie Pvt
Ltd. Bombay, India and was used without further purifica-
tion. 2-Hydroxy-1-naphthaldehyde and N-methylmorpholine-
N-oxide were purchased from Aldrich. [RuHCl(CO)(PPh₃)₃]
[21], [RuHCl(CO)(PPh₃)₂(B)] [22] (where B = py, pip) and
[RuHCl(CO)(AsPh₃)₃] [23] were prepared by reported litera-
ture methods.
Catalytic oxidation of primary and secondary alcohols to cor-
responding aldehydes and ketones respectively by ruthenium(II)
carbonyl complexes was studied in the presence of NMO as co-
oxidant. A typical reaction using the ruthenium complexes as
catalyst and benzyl alcohol, cinnamyl alcohol, cyclohexanol and
benzoin as substrates at 1:100 molar ratio is described as follows.
Asolutionofrutheniumcomplex(0.01 mmol)in20 cm³ CH₂Cl₂
was added to the solution of substrate (1 mmol) and NMO
(3 mmol). The solution mixture was refluxed for 3 h and the sol-
vent was then evaporated from the mother liquor under reduced
pressure. The solid residue was then extracted with petroleum
ether (60–80 ^◦C) (20 cm³) and the ether extracts were evap-
orated to give corresponding aldehydes/ketones, which were
then isolated and quantified as their 2,4-dinitrophenylhydrazone
derivative [25].
2.2. Physical measurements
The analysis of carbon, hydrogen and nitrogen were per-
formed on elementar systeme model vario EL111 at Sophisti-
cated Test and Instrumentation center, Cochin, India. IR spectra
were recorded in KBr pellets in the range 4000–400 cm⁻¹ region
in Jasco 400 plus spectrophotometer. Electronic spectra were
recorded in CH₂Cl₂ solution with a Cary 300 Bio UV–vis Var-
3. Results and discussion
1
ian spectrophotometer in the range of 800–200 nm. H NMR
spectra were recorded on a Bruker 400 MHZ instrument using
TMS as an internal reference. Using Jasco FP-6500 spectrofluo-
rimeter with 5 nm exit slit the emission intensity measurements
were carried out. Electrochemical measurements were made
using a Princeton EG and G- PARC model potentiostat using
a glassy carbon working electrode and all the potentials were
referenced to Ag/AgCl electrode. Melting Points were recorded
with a Boetius micro-heating table and are uncorrected.
Diamagnetic, stable hexa-coordinated low spin ruthenium(II)
complexes of general formula [RuCl(CO)(PPh₃)(B)(L)] and
[RuCl(CO)(AsPh₃)₂(L)] (where B = PPh₃, py or pip; L =
bidentate Schiff bases) are prepared by reacting
[RuHCl(CO)(PPh₃)₃], [RuHCl(CO)(py)(PPh₃)₂], [RuHCl(CO)
(pip)(PPh₃)₂] and [RuHCl(CO)(AsPh₃)₃] with the respective
Schiff bases in a 1:1 mole ratio in benzene as shown in
Scheme 2.
All the new Schiff base ruthenium(II) complexes are highly
colored, stable in air, non-hygroscopic in nature and highly sol-
uble in common solvents such as dichloromethane, acetonitrile,
chloroform and DMSO. The analytical data are listed in Table 1
and are in good agreement with the general molecular formula
proposed for all the complexes. In all reactions, the Schiff base
replaced one PPh₃/AsPh₃ group and a hydride from the start-
ing complexes. The Schiff bases behave as monobasic bidentate
ligand in all cases. The heterocyclic nitrogen bases (pyridine,
piperidine)remainedintactbecausetheRu–Pbondismorelabile
than the Ru–N bond, because of the better σ donating ability of
the nitrogen bases compared to triphenylphosphine.
2.3. Preparation of Schiff base ligands
The monobasic bidentate Schiff base ligands were pre-
pared by the condensation of 2-hydroxy-1-naphthaldehyde
(0.43 g; 0.0025 mmol) with primary amines such as
methylamine, 2-aminopyridine, cyclohexylamine and p-
bromoaniline (0.08–0.43 g; 0.0025 mmol) in 1:1 molar ratio in
methanol(20 cm³) [24]. The solution was heated under reflux
for 2 h and then concentrated to 5 cm³. On cooling the product
was separated out which was then recrystallised from hot
methanol and the purity was checked by TLC.

M. Sivagamasundari, R. Ramesh / Spectrochimica Acta Part A 66 (2007) 427–433
429
assigned to the ν(OH) and this band is absent in the spectra of
all the complexes, implying the deprotonation of the Schiff base
prior to coordination. The hydroxy protons are displaced by the
metal leading to higher ν(C–O) (1364–1316 cm⁻¹) compared to
that of the free ligands ν(C–O) (1324–1314 cm⁻¹) suggesting
that the other coordinating atom is phenolic oxygen [25]. The
binding of the metal to the ligand through nitrogen and oxy-
gen atom is further supported by the appearance of new band
in 460–400 cm⁻¹ and 540–510 cm⁻¹ ranges due to ν(M–N) and
ν(M–O) [27], respectively in the spectra of all the complexes.
A strong band in the region 1957–1935 cm⁻¹ due to terminally
coordinatedcarbonylgroupathigherfrequencythanintheruthe-
nium starting complexes. In the complexes 2, 3, 6, 7, 10, 11, 14,
15 a medium intensity band is observed in the 1020 cm⁻¹ region
characteristic of the coordinated pyridine or piperidine [27]. In
addition Schiff base complexes show strong vibrations near 520,
695, 740 and 1430 cm⁻¹, which are attributed to the triphenyl
phosphine or triphenyl arsine fragment [28].
The nuclear magnetic resonance spectra of the diamagnetic
compounds taken in CDCl₃ solution confirms the complex for-
mation (Table 3). In the spectra of all the complexes a sharp
singlet appeared at around 8.11–9.12 ppm has been assigned to
azomethine proton (>C N). The positions of azomethine signal
in the complexes are up field compared to that of the free ligands
indicating coordination through the azomethine nitrogen atom
[10]. Multiplets are observed around 6.51–8.00 ppm in all the
complexes and have been assigned to the aromatic protons of
triphenylphosphine, triphenylarsine, pyridine and naphthalene
Schiff base ligands [29]. Methyl protons appear as singlet in
the region 2.17–2.50 ppm in the complexes 1, 2 and 4. A broad
singlet appeared in the region 1.30–1.41 ppm for the methy-
lene protons of the cyclohexyl group for 5, 6, 7 and 8. In the
spectra of 7, 11 and 15 the methylene protons appear as sin-
glet around 1.30–2.05ppm and another singlet in the region
9.50–9.72 ppm due to NH protons. The absence of a resonance
at 13.25–15.21 ppm in the complexes indicate deprotonation of
the phenolic group of the Schiff bases on complexation and coor-
Scheme 2. Formation of Ru(II) carbonyl Schiff base complexes (where E = P;
B = PPh₃, py or pip; E = As, B = AsPh₃ R = –CH₃, –C₆H₁₁, –C₅H₄N, –C₆H₄Br).
3.1. Spectroscopic characterization
The IR spectra of the complexes, in comparison with those
of the free ligands, display certain changes, which give an idea
about the type of co-ordination and their structure. Significant IR
spectral bands of the complexes are listed in Table 2. Free Schiff
bases show a very strong absorption around 1642–1618 cm⁻¹
characteristic of azomethine (>C N) group [19]. Coordination
of the Schiff bases to the ruthenium ion through the azome-
thine nitrogen atom is expected to reduce the electron density
in the azomethine link and thus, lower the ν(C N) absorption
frequency. Hence this band undergoes a shift to lower frequency
to 1620–1599 cm⁻¹ after complexation, indicating coordination
of the azomethine nitrogen to ruthenium [18,26]. The free lig-
ands exhibit a broad band at 3435–3427 cm⁻¹, which may be
Table 1
Analytical data of Ru(II) carbonyl complexes containing N, O donors of 2-hydroxy-1-napthylideneimines
S. number
Complexes
Formula
Colour
m.p. (^◦C)
Found (calculated) (%)
C
H
N
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
[Ru(Cl)(CO) (PPh₃)₂(L1)]
[Ru(Cl)(CO)(PPh₃)(py)(L1)]
[Ru(Cl)(CO)(PPh₃)(pip)(L1)]
[Ru(Cl)(CO)(AsPh₃)₂(L1)]
[Ru(Cl)(CO)(PPh₃)₂(L2)]
[Ru(Cl)(CO)(PPh₃)(py)(L2)]
[Ru(Cl)(CO)(PPh₃)(pip)(L2)]
[Ru(Cl)(CO)(AsPh₃)₂(L2)]
[Ru(Cl)(CO)(PPh₃)₂(L3)]
[Ru(Cl)(CO)(PPh₃)(py)(L3)]
[Ru(Cl)(CO)(PPh₃)(pip)(L3)]
[Ru(Cl)(CO)(AsPh₃)₂(L3)]
[Ru(Cl)(CO)(PPh₃)₂(L4)]
[Ru(Cl)(CO)(PPh₃)(py)(L4)]
[Ru(Cl)(CO)(PPh₃)(pip)(L4)]
[Ru(Cl)(CO)(AsPh₃)₂(L4)]
C₄₉H₁₀NO₂P₂ClRu
C₃₆H₃₀N₂O₂PClRu
C₃₆H₃₅N₂O₂PClRu
C₄₉H₄₀NO₂As₂ClRu
C₅₄H₄₇NO₂P₂ClRu
Green
Green
Green
Green
Green
Green
Green
Brown
Brown
Brown
Brown
Brown
Green
Green
Brown
Brown
222
154
160
176
147
137
148
148
217
180
131
135
167
150
148
132
67.39(67.61)
62.65(62.33)
62.20(62.46)
61.20(61.08)
69.00(69.37)
65.00(65.41)
64.60(64.29)
63.20(63.48)
69.80(69.57)
63.70(63.49)
63.36(63.60)
62.14(62.41)
63.95(63.63)
56.80(56.51)
58.91(58.67)
58.84(58.51)
4.61(4.72)
4.38(4.25)
5.07(5.32)
4.19(4.02)
5.10(5.33)
4.91(4.46)
5.50(5.25)
4.71(4.89)
4.40(4.19)
4.20(4.29)
4.78(4.54)
4.03(4.31)
4.07(4.19)
3.60(3.87)
4.30(4.16)
3.75(3.82)
1.61(1.88)
4.05(4.25)
4.02(4.31)
1.45(1.60)
1.42(1.43)
3.60(3.81)
3.61(3.34)
1.36(1.51)
2.99(2.73)
5.56(5.36)
5.50(5.39)
2.71(2.85)
1.30(1.46)
3.22(3.09)
3.30(3.12)
1.72(1.49)
C₄₁H₃₇N₂O₂PClRu
C₄₁H₄₂N₂O₂PClRu
C₅₄H₄₈NO₂As₂ClRu
C₅₃H₄₁N₂O₂P₂ClRu
C₄₀H₃₂N₃O₂PClRu
C₄₀H₃₆N₃O₂PClRu
C₅₃H₄₁N₂O₂As₂ClRu
C₅₄H₄₁NO₂P₂ClBrRu
C₄₁H₃₁N₂O₂PClBrRu
C₄₁H₃₆N₂O₂PClBrRu
C₅₄H₄₁NO₂As₂ClBrRu

430
M. Sivagamasundari, R. Ramesh / Spectrochimica Acta Part A 66 (2007) 427–433
Table 2
Important IR, electronic and fluorescence^a spectral data of the Ru(II) carbonyl Schiff base complexes
Complexes
␥
(cm⁻¹
)
␥
(cm⁻¹
)
␥
(cm⁻¹
C O
)
λ_max (nm)(ε)(dm³ mol⁻¹ cm⁻¹
)
Fluorescence data
C
N
C
O
(λ_max (nm))
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
1617
1617
1616
1617
1616
1613
1616
1620
1615
1615
1617
1616
1599
1600
1601
1600
1318
1319
1338
1316
1339
1338
1338
1336
1336
1341
1364
1335
1338
1337
1362
1335
1946
1944
1942
1935
1942
1935
1941
1954
1950
1949
1950
1950
1946
1945
1948
1957
694(380)^b, 456(3404)^c, 321(9520)^d, 266(15296)^e
679(270)^b, 436(3324)^c, 319(9900)^d, 260(13460)^e
653(386)^b, 440(4580)^c, 319(10032)^d, 258(15052)^e
670(224)^b, 427(4744)^c, 323(12048)^d, 259(16432)^e
661(536)^b, 419(4192)^c, 314(11024)^d, 262(15448)^e
657(448)^b, 426(5388)^c, 330(13644)^d, 272(17340)^e
631(504)^b, 417(4491)^c, 310(12024)^d, 261(17168)^e
680(364)^b, 416(3712)^c, 314(10836)^d, 264(15980)^e
464(3240)^c, 321(12812)^d, 259(17024)^e
512
510
516
503
501
502
508
496
538
540
543
518
502
497
506
505
694(228)^b, 456(6000)^c, 326(13952)^d, 259(16064)^e
464(3044)^c, 327(11512)^d, 257(17624)^e
719(358)^b, 460(5060)^c, 321(11940)^d, 271(17752)^e
697(472)^b, 420(4678)^c, 320(10928)^d, 254(15128)^e
690(380)^b, 431(4056)^c, 323(11003)^d, 258(166632)^e
431(3582)^c, 324(9888)^d, 267(15948)^e
688(140)^b, 435(3054)^c, 319(9892)^d, 271(15852)^e
a
Excitation at MLCT.
b
c
d
e
1
¹A_1g → T_1g
.
Charge transfer.
n–␲*.
␲–␲*.
330–310 nm and 272–254 nm has been designated as n–␲^* and
␲–␲ transitions respectively for the electrons localized on the
azomethine group of the Schiff bases. The pattern of the elec-
tronic spectra for all the complexes indicate the presence of an
octahedral environment around the ruthenium(II) ion similar to
that of other ruthenium octahedral complexes [18,19,31,32].
dination to ruthenium through the phenolic oxygen [18,19]. The
spectra did not show any signal in the up field region for the
hydride ligand, thus proving its substitution by the Schiff bases.
Electronic spectra of all the complexes in chloroform showed
three to four bands in the region 719–254 nm. All the com-
plexes are diamagnetic, indicating the presence of ruthenium
in the +2 oxidation state. The ground state of ruthenium(II)
*
1
6
in an octahedral environment is A_1g, arising from the t_2g
3.2. Luminescence property
3
3
1
configuration. The excited state terms are T_1g, T_2g, T_1g
1
and T_2g. Hence four bands corresponding to the transition
Emission properties of the ruthenium(II) Schiff base com-
plexes were examined in chloroform at room temperature. The
excitation of these complexes was made at their charge transfer
band. The emission maxima fall in the range 496–543 nm and
the emission maxima of the complexes are listed in Table 2. The
emission maxima for all the complexes have experienced a pos-
itive shift of the order of 56–91 nm, when compared to those of
excitation maxima. A representative spectrum is shown in Fig. 1.
The observed CT luminescence in these complexes may be due
to the presence of the imine functional group. It is likely that
the emission originates from the lowest energy metal to ligand
charge transfer (MLCT) state, probably derived from the exci-
tation involving a d␲(Ru) → ␲^*(imine) MLCT transition [33].
The present results show that the Ru(II) Schiff base carbonyl
complexes have decreased emission intensity when compared to
ruthenium(II) bipyridyl complexes[34]. The emission maxima
are influenced by the substituents on the coordinating imines
and it decreases slightly with increasing number of substituents
at the coordinated nitrogen [35]. Hence complexes 5–8 have
lower emission maxima [34] than 1–4, where methyl is the sub-
stituent. Furtherthepresenceofthiselectronrichmethylgroupin
1–4 makes them have higher emission maxima compared to the
complexes 13–16 where the substituent is electron-withdrawing
bromine. Complexes 9–12 having the amino pyridine substituent
¹A_1g → T_1g, ¹A_1g → T_2g, ¹A_1g → T_1gand ¹A_1g → T_2g are
3
3
1
1
possible in order of increasing energy. The electronic spec-
1
1
tral bands at around 719–653 nm are assigned to A_1g → T_1g
(Table 2). The other high intensity band in the visible region
around 464–419 nm has been assigned to charge transfer transi-
tions arising from the metal t_2g level to the unfilled ␲^* molecular
orbital of the ligand [18,30–32]. The high intensity bands around
Table 3
¹H NMR data for selected Ru(II) carbonyl Schiff base complexes
Complexes
¹H NMR data (ppm)
1
2
4
5
6
6.65–7.19(Ar, m), 9.12(CH N, s), 2.25(CH₃, s)
6.90–7.81(Ar, m), 8.82(CH N, s), 2.17(CH₃, s)
6.58–7.72(Ar, m), 8.11(CH N, s), 2.50(CH₃, s)
6.51–8.00(Ar, m), 8.72(CH N, s), 1.30(CH₂, s)
6.80–7.81(Ar, m), 8.70(CH N, s), 1.41(CH₂, s)
6.91–7.80(Ar, m), 8.36(CH N, s), 1.30(CH₂, s), 9.50(NH, s)
6.90–7.70(Ar, m), 8.30(CH N, s), 1.35(CH₂, s)
6.54–7.72(Ar, m), 8.41(CH N, s)
6.75–7.80(Ar, m), 8.36(CH N, s), 2.05(CH₂, s), 9.65(NH, s)
6.80–7.91(Ar, m), 8.36(CH N, s)
6.91–7.92(Ar, m), 8.80(CH N, s)
6.81–7.74(Ar, m), 8.63(CH N, s), 1.3(CH₂, s), 9.72(NH, s)
6.90–7.80(Ar, m), 8.25(CH N, s)
7
8
10
11
13
14
15
16

M. Sivagamasundari, R. Ramesh / Spectrochimica Acta Part A 66 (2007) 427–433
431
Fig. 2. Cyclic voltammogram of [Ru(Cl)(CO)(PPh₃)(py)(L4)].
Fig. 1. Absorption (—), fluorescence (– – –) and excitation (. . . . . . . . .) spectra
of [Ru(Cl)(CO)(PPh₃)(py)(L2)] in chloroform.
oxidation with E_1/2 value +0.61 to +0.82 V (Ru^III/Ru^II) and an
irreversiblereductionintherange−0.72to−0.95withrespectto
the Ag/AgCl at scan rate 100 mVs⁻¹. The oxidation observed is
quasi-reversible in nature characterized by a large peak-to-peak
separation (ꢀE) of 110–220 mV and the cathodic peak current
(i_pc) is less than the anodic peak current (i_pa). The one electron
nature of this oxidation has been verified by comparing its cur-
rent height (i_pa) with that of the ferrocene-ferrocenium couple
under identical experimental conditions [37].
have the greatest emission maxima compared to other com-
plexes and this may be attributed to the presence of an addi-
tional chromophoric group >C N of the pyridine [36]. Among
triphenylphosphine and triphenylarsine complexes, the emission
maxima are slightly reduced in the arsine complexes where the
heavier atom As induces the spin forbidden transition.
3.3. Electrochemical study
[Ru^IICl(CO)(EPh₃)(B)(L)]ꢀ[Ru^IIICl(CO)(EPh₃)(B)(L)]⁺+e⁻
The redox properties of all the complexes were investigated
in acetonitrile solution by cyclic voltammetry and the redox
potentials are expressed with reference to Ag/AgCl. The voltam-
metric data are presented in Table 4 and a representative cyclic
voltammogram of 13 is shown in Fig. 2. Cyclic voltammo-
gram of the complexes (1 × 10⁻³) exhibit a quasi-reversible
The reason for irreversibility observed in the reduction of
all the complexes may be due to short lived reduced state of
the metal ion [38] or due to oxidative degradation [39] of the
ligands. It has been observed from the electrochemical data that
there is little variation in the redox potentials due to replacement
of triphenylphosphine by pyridine or piperidine or by tripheny-
larsine [19]. Hence it is inferred from the electrochemical data
that the present ligand system is ideally suitable for stabilizing
the higher oxidation state of ruthenium ion.
Table 4
Cyclic voltammetry data of Ru(II) carbonyl Schiff base complexes
Complexes
Metal based oxidation Ru^III/Ru^II
Metal based
reduction
Ru^II/Ru^I
3.4. Catalytic activity
E_pa (V)
E_pc (V)
ꢀE_p (mV)
E_1/2 (V)
E_pc (V)
The primary and secondary alcohols (1 mmol) were effi-
ciently oxidized by using 0.01 mmol of the catalyst in the coexis-
tence of 3 mmol of NMO in dichloromethane (Table 5). All the
complexes oxidize primary alcohols to corresponding aldehy-
des and secondary alcohols to corresponding ketones with high
yield. This reaction provides an environmentally friendly route
to the conversion of alcoholic functions to carbonyl groups and
water is the only by product during the course of the reaction
which was removed by using molecular sieves. The aldehydes
and ketones formed after 3 h of reflux were isolated and quanti-
fied as their 2,4-dinitrophenylhydrazone derivatives. In the case
of benzoin, the oxidation product was isolated and characterized
by melting point, IR, ¹H NMR. Control experiments were car-
ried out without the ruthenium catalyst under the same reaction
conditions and in no case was there any detectable oxidation of
alcohols.
1
2
3
4
5
6
8
9
10
11
12
13
14
15
16
0.89
0.71
0.93
0.86
0.92
0.90
0.78
0.81
0.85
0.86
0.88
0.93
0.88
0.89
0.93
0.69
0.51
0.72
0.72
0.71
0.70
0.67
0.68
0.68
0.69
0.72
0.71
0.72
0.70
0.71
0.79
0.61
0.84
0.79
0.81
0.80
0.72
0.74
0.76
0.77
0.80
0.82
0.80
0.79
0.82
200
200
210
140
210
192
110
130
170
180
160
220
160
190
220
−0.95
−0.94
−0.89
−0.91
−0.72
−0.85
−0.78
−0.89
−0.77
−0.88
−0.99
−0.82
−0.84
−0.93
−0.87
Supporting electrolyte: NBu₄ClO₄ (0.005 M); complex: 0.001 M; solvent:
CH₃CN; ꢀE_p = E_pa − E_pc. Where E_pa and E_pc are anodic and cathodic poten-
tials, respectively; E_1/2 = 0.5 (E_pa + E_pc); scan rate: 100 mV s⁻¹
.

432
M. Sivagamasundari, R. Ramesh / Spectrochimica Acta Part A 66 (2007) 427–433
to dryness) which showed a band at 859 cm⁻¹, characteristic of
Ru(IV)-oxo species, which is absent in the ruthenium catalyst.
Except for the above difference noted, the IR spectra of the cat-
alyst and solid mass appear quite similar, which suggests that
the coordinated ligands remain intact in the oxidation process.
Hence, it had been suggested that catalytic oxidation proceeds
through metal-oxo intermediate. Furthermore, it is relevant from
the cyclic voltammetric data that the oxidation effected by cat-
alysts is likely to occur via higher ruthenium oxidation states,
which is easily accessible through chemical oxidation with co-
oxidatants like NMO, t-BuOOH, PhIO, etc [17,42].
Table 5
Catalytic oxidation of alcohols by ruthenium complexes/NMO
Complex
Substrate
Product
Yield^a (%)
TON^b
2
Benzyl alcohol
Cinnamyl alcohol
Cyclohexanol
Benzoin
A
A
K
K
55.8^c
91.0^c
30.0^c
32.3^d
55.8
91.0
30.0
32.3
5
12
15
Benzyl alcohol
Cinnamyl alcohol
Cyclohexanol
Benzoin
A
A
K
K
59.6^c
85.4^c
35.3^c
37.1^d
59.6
85.4
35.3
37.1
Benzyl alcohol
Cinnamyl alcohol
Cyclohexanol
Benzoin
A
A
K
K
52.7^c
90.3^c
33.6^c
40.0^d
52.7
90.3
33.6
40.0
4. Conclusion
Benzyl alcohol
Cinnamyl alcohol
Cyclohexanol
Benzoin
A
A
K
K
60.9^c
93.5^c
28.5^c
35.0^d
60.9
93.5
28.5
35.0
The synthesis, characterization and redox properties of
new ruthenium(II) Schiff base complexes of the type
[Ru(Cl)(CO)(EPh₃)(B)(L)] are described. These complexes are
found to have luminescent properties and attempts will be
made for further investigation on this study. The results of the
present studies demonstrate the catalytic ability of the ruthe-
nium(II) complexes to oxidize primary and secondary alcohols
efficiently to their corresponding carbonyl compounds. A high-
valent Ru(IV)-oxo species is proposed as the active intermediate
in the catalytic process.
A or K: corresponding aldehyde or ketone.
a
Yield based on substrate; alcohol (1 mmol); NMO (3 mmol); catalyst
(0.01 mmol).
b
Ratio of moles of product obtained to the moles of the catalyst used.
Isolated as 2,4-dinitrophenylhydrazone derivative, characterized by ¹H
c
NMR and IR.
d
Isolated yield, characterized by melting point, ¹H NMR and IR.
Acknowledgements
The corresponding author express his sincere thanks to Uni-
versity Grants Commission (UGC), New Delhi [Ref. No. F12-
45/2003(SR)] for financial support. One of the authors (M.S)
thank UGC for the award of Project Fellow.
The relatively higher product yield obtained for oxidation of
cinnamyl alcohol is due to the presence of ␣-CH unit in cin-
namyl alcohol, which is more acidic than in benzyl alcohol,
cyclohexanol or benzoin. Also, the oxidation of cinnamyl alco-
hol to cinnamaldehyde takes place with retention of C C double
bond, which is an important characteristic of ruthenium/NMO
system. In the case of oxidation of secondary alcohols, it has
been observed that the oxidation of cyclohexanol is substantially
lower than that of benzoin. This may be due to the fact that the
saturated cyclic ketones are generally prone to undergo dehydro-
genation faster than acyclic ketones [40]. These ruthenium(II)
Schiff base complexes have better catalytic activity compared
to similar other ruthenium complexes as catalyst in the presence
of NMO/t-BuOOH [41–43].
References
[1] W.Y. Sun, J. Fan, T. Okamura, N. Ueyama, Inorg. Chem. Comm. 3 (2000)
541.
[2] X.M. Ouyang, B.L. Fei, T.A. Okamura, W.Y. Sun, W.X. Tang, N. Ueyama,
Chem. Lett. (2002) 362.
[3] W.T. Gao, Z. Zheng, Molecules 7 (2002) 511.
[4] R.A. Sheldon, J.K. Kochi, Metal-catalyzed Oxidation of Organic Com-
pounds, Academic press, New York, 1981.
[5] L. Canali, D.C. Sherington, Chem. Soc. Rev. 28 (1999) 85.
[6] F.N. Castellano, J.D. Dattelbaum, J.R. Lakowicz, Anal. Biochem. 255
(1998) 165.
[7] H. Wolpher, O. Johansson, M. Abrahamson, M. Kritikos, L. Sun, B. Aker-
mark, Inorg. Chem. Commun. 7 (2004) 337.
Results of the present investigation suggest that the ruthe-
nium complexes are able to react efficiently with NMO to yield
a high valent ruthenium-oxo species [17,44] capable of oxy-
gen atom transfer to alcohols. The formation of ruthenium-oxo
species were supported by spectral changes that occur by the
addition of NMO to a dichloromethane solution of the ruthe-
nium(II) complexes. The appearance of a peak at 390 nm is
attributed to the formation of high-valent Ru(IV)-oxo species
which is in conformity with other oxo-ruthenium (IV) com-
plexes [42,44]. However, compelling evidence in favor of the
formation of Ru(IV)-oxo species came from the IR spectrum of
the solid mass (obtained by evaporation of the resultant solution
[8] K. Kalyanasundaram, Coord. Chem. Rev. 46 (1982) 85.
[9] E.B. Hergovich, G. Speier, J. Mol. Catal. A: Chem. 230 (2005) 79.
[10] H.S. Abbo, S.J.J. Titinchi, R. Prasad, S. Chand, J. Mol. Catal. A: Chem.
225 (2005) 225.
[11] G. Csjernyik, A.H. Ell, L. Fadini, B. Pugin, J. Backvall, J. Org. Chem. 67
(2002) 1657.
[12] P. Muller, J. Godoy, Tetrahedron Lett. 22 (1981) 2361.
[13] Y. Tsuji, T. Ohta, T. Ido, H. Minbu, Y. Watanabe, J. Organomet. Chem. 270
(1984) 333.
[14] G. Barak, J. Dakka, Y. Sasson, J. Org. Chem. 53 (1988) 3553.
[15] V. Farmer, T. Welton, Green Chem. 4 (2002) 97.
[16] W.H. Leung, C.M. Che, Inorg. Chem. 28 (1989) 4619.
[17] W.K. Wong, X.P. Chen, J.P. Gao, Y.G. Chi, W.X. Pan, W.Y. Wang, J. Chem.
Soc., Dalton Trans. (2002) 113.

M. Sivagamasundari, R. Ramesh / Spectrochimica Acta Part A 66 (2007) 427–433
433
[18] R. Ramesh, M. Sivagamasundari, Synth. React. Inorg. Met-Org. Chem. 33
(2003) 899.
[31] K. ChiChak, U. Jacquenard, N.R. Branda, Eur. J. Inorg. Chem. (2002)
357.
[19] K. Naresh Kumar, R. Ramesh, Spectrochim. Acta Part A 60 (2004) 2913.
[20] G. Venkatachalam, R. Ramesh, Tet. Lett. 46 (2005) 5215.
[21] N. Ahmed, J.J. Lewison, S.D. Robinson, M.F. Uttley, Inorg. Synth. 15
(1974) 48.
[32] K. Natarajan, R.K. Poddar, C. Agarwala, J. Inorg. Nucl. Chem. 39 (1977)
431.
[33] V.W. Yam, B.W. Chu, C. Ko, K. Cheung, J. Chem. Soc., Dalton Trans.
(2001) 1911.
[22] S. Gopinathan, I.R. Unny, S.S. Deshpande, C. Gobinathan, Ind. J. Chem.
25A (1986) 1015.
[23] R.A. Sanchez-pelgado, W.Y. Lee, S.R. Choi, Y. Cho, M.J. Jun, Trans. Met.
Chem. 16 (1991) 241.
[34] N. Aydin, C. Schlaepfer, Polyhedron 20 (2001) 37.
[35] S. Balasubramanian, J. Lumin. 106 (2004) 69.
[36] Y.V. Korovin, R.N. Lozitskaya, N.V. Rusakova, Russ. J. Gen. Chem. 73
(2003) 1641.
[24] A.I. Vogel, Text Book of Practical Organic Chemistry, 5th ed., Longman,
London, 1989.
[37] S. Dutta, S.M. Peng, S. Bhattacharya, J. Chem. Soc., Dalton Trans. (2000)
4623.
[25] R.C. Maurya, P. Patel, S. Rajput, Synth. React. Inorg. Met-org. Chem. 23
(2003) 817.
[38] A.M. Bond, R. Colton, D.R. Mann, Inorg. Chem. 29 (1990) 4665.
[39] A. Basu, T.G. Kasan, N.Y. Sapre, Inorg. Chem. 27 (1988) 4639.
[40] Y. Shvo, V. Goldman-Lev, J. Organomet. Chem. 650 (2002) 151.
[41] M.S. El- Shahawi, A.F. Shoair, Spectrochim. Acta Part A 60 (2004)
121.
[42] A.M. El-Hendawy, A.H. Alkubaisi, A.E. Kourashy, M.M. Shanab, Polyhe-
dron 12 (1993) 2343.
[43] D. Chattergee, A. Mitra, B.C. Roy, J. Mol. Catal. A: Chem. 161 (2000) 17.
[44] M.M.T. Khan, C. Sreelatha, S.A. Mirza, G. Ramachandraiah, S.H.R. Abdi,
Inorg. Chim. Acta. 154 (1988) 103.
[26] S.N. Pal, S. Pal, J. Chem. Soc., Dalton Trans. (2002) 2102.
[27] K. Nakamoto, Infrared and Raman spectra of Inorganic and Co-ordination
compounds, Wiley Interscience, New York, 1971.
[28] A.K. Das, S.M. Peng, S. Bhattacharya, J. Chem. Soc., Jpn. 49 (1976) 287.
[29] J.R. Dyer, Application of Absoption Spectroscopy of Organic Compounds,
Prentice-Hall, New Jersey, 1978.
[30] A.B.P. Lever, Inorganic Electronic Spectroscopy, 2nd ed., Elsiever, New
York, 1984.