Ruthenium monoterpyridine complexes incorporating α,α′-diimine based ancillary functions. Synthesis, crystal structure, spectroelectrochemical properties and catalytic aspect

Article abstract of DOI:10.1016/S0277-5387(02)01131-2

Ruthenium monoterpyridine complexes of the type [Ru^II(trpy)(L′)(X)](ClO₄)_m ·2H₂O (1-2) [trpy = 2,2′:6′,2′′-terpyridine; L′= NC₅H₄CH)=N(C₆H₄)_n NH₂

Full text of DOI:10.1016/S0277-5387(02)01131-2

Polyhedron 21 (2002) 2033Á2043
/
www.elsevier.com/locate/poly
Ruthenium monoterpyridine complexes incorporating a,a?-diimine
based ancillary functions.
Synthesis, crystal structure, spectroelectrochemical properties and
catalytic aspect
Nripen Chanda ^a, Biplab Mondal ^a, Vedavati G. Puranik ^b, Goutam Kumar Lahiri ^a,*
^a Department of Chemistry, Indian Institute of Technology-Bombay, Powai, Mumbai 400 076, India
^b Physical Chemistry Division, National Chemistry Laboratory, Pune, Maharashtra 411 008, India
Received 18 March 2002; accepted 6 June 2002
Abstract
Ruthenium monoterpyridine complexes of the type [Ru^II(trpy)(L?)(X)](ClO₄)_m
NC₅H₄C(H)ÄN(C₆H₄)_nNH₂ (nꢀ1 and 2); Xꢀ 1 (1); XꢀH₂O, mꢀ
Cl^ꢁ, mꢀ
hydrolysis of one of the imine functions present in the preformed stable dinucleating bridging functions, NC₅H₄C(H)Ä
C(H)H₄C₅N (L) (nꢀ
1, 2). The single crystal X-ray structures of the dinucleating bridging function (L¹) and the chloro complex (1a)
(in both cases nꢀ
1) have been determined. The complexes stabilize preferentially in one particular isomeric form where the Cl^ꢁ or
×
/
2H₂O (1Á
2 (2)] have been synthesized via the selective
N(C₆H₄)_nNÄ
/
2) [trpyꢀ
/
2,2?:6?,2ƒ-terpyridine; L?ꢀ
/
/
/
/
/
/
/
/
/
/
/
H₂O molecule is in the trans configuration with respect to the N(imine) center. The chloro complexes (1) exhibit strong MLCT
bands near 500 nm whereas in the case of the aqua complexes (2) the MLCT bands are blue shifted near 470 nm. The chloro
complexes (1) exhibit weak emissions in EtOHÁ
/
MeOH (4:1 v/v) glass at 77 K near 600 nm (quantum yield, F_em
ꢀ
/
0.015Á
/
0.03). In
ruthenium(II) couple near 0.8 V and terpyridine based reduction near 1 V versus
acetonitrile solvent 1 display a ruthenium(III)Á
/
SCE. The aqua complexes (2) exhibit a concerted 2e^ꢁ/2H^ꢂ oxidation process in the acidic region and in the alkaline region, the
complexes display a 2e^ꢁ/H^ꢂ oxidation process. The potentials are observed to decrease linearly with the increase in pH. The proton
coupled redox processes in the acidic and basic regions correspond to [Ru^II(trpy)(L?)(H₂O)]^2ꢂ Á[Ru^IV(trpy)(L?)(O)]^2ꢂ and
/
[Ru^II(trpy)(L?)(OH)]^ꢂ Á[Ru^IV(trpy)(L?)(O)]^2ꢂ couples, respectively. The chemical oxidation of 2 by excess Ce^IV solution in 1 (N)
/
H₂SO₄ also leads to the formation of the corresponding [Ru^IV(trpy)(L?)(O)]^2ꢂ (3). The oxo complexes (3) are stable only in the
presence of excess Ce^IV ion, otherwise they slowly catalyze the oxidation of water to dioxygen and return back to the parent aqua
species. The electrochemically generated oxo-species are found to catalyze the benzyl alcohol oxidation process. # 2002 Elsevier
Science Ltd. All rights reserved.
Keywords: Ruthenium monoterpyridine complexes; Ancillary functions; Crystal structures
1. Introduction
photo- and electrochemical devices [1Á13]. In recent
/
years, it has been observed that the electronic nature of
the ancillary functions in the ruthenium monoterpyr-
idine core plays an important role in directing the
chemical and electrochemical properties of this class of
Ruthenium polypyridine (bipyridine and terpyridine)
complexes have received considerable research interest
in recent years primarily due to their strong metal to
ligand charge-transfer transitions, facile electron-trans-
complexes [14Á21] and this has initiated the present
/
3
fer properties and long lived MLCT excited states and
these in combination make them attractive for designing
program of developing a newer class of ruthenium
monoterpyridine derivatives incorporating the a,a?-dii-
mine based ancillary functions. Since the present trend
in this direction has been primarily focussed towards the
framing of multinuclear to supramolecular assemblies
* Corresponding author. Tel.: ꢂ
3480
E-mail address: lahiri@ether.chem.iitb.ernet.in (G.K. Lahiri).
/
91-22-572-2545; fax: ꢂ91-22-572-
/
[22Á27], we had taken the program of synthesizing
/
0277-5387/02/$ - see front matter # 2002 Elsevier Science Ltd. All rights reserved.
PII: S 0 2 7 7 - 5 3 8 7 ( 0 2 ) 0 1 1 3 1 - 2

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N. Chanda et al. / Polyhedron 21 (2002) 2033Á2043
/
dinuclear ruthenium terpyridine complexes using the
a,a?-diimine based neutral bridging functions NC₅H₄Ã
H₄C₅N (nꢀ1, 2), L.
Although the bridging functions (L) are stable enough
in the free state [28,29], during the reaction with
mately 10^ꢁ3 M. The half-wave potential E8₂₉₈ was set
equal to 0.5(E_paꢂE_pc), where E_pa and E_pc are anodic
and cathodic cyclic voltammetric peak potentials, re-
spectively. A Pt wire-gauze working electrode was used
in coulometric experiments. All experiments were car-
ried out under a dinitrogen atmosphere and were
uncorrected for junction potentials. The elemental
/
/
CHÄ
/
NÃ
/
(C₆H₄)_n Ã
/
NÄ
/
CHÃ
/
/
Ru(trpy)Cl₃ (trpyꢀ2,2?:6,2ƒ-terpyridine) one of the
/
imine functions of L has been selectively hydrolyzed.
This in turn leads to the formation of ruthenium
analyses were carried out with a CarloÁErba (Italy)
/
monoterpyridine
[Ru^II(trpy)(L?)Cl]^ꢂ (1) where L? corresponds to
NC₅H₄ÃCHÄNÃ(C₆H₄)_n ÃNH₂ (nꢀ1, 2).
Herein we report the stepwise syntheses of the
complexes, [Ru^II(trpy)(L?)Cl]^ꢂ (1)0[Ru^II(trpy)(L?)-
H₂O]^2ꢂ (2)0[Ru^IV(trpy)(L?)O]^2ꢂ (3), crystal structures
of L¹ and 1a, and the chemicalÁ
electrochemical reactiv-
complexes
of
the
type
elemental analyzer. Solution emission properties were
checked using a SPEX-fluorolog spectrofluorometer. X-
ray data were collected by using a Nonius MACH 3
/
/
/
/
/
four-circle diffractometer with graphite monochromated
˚
/
Mo Ka radiation (lꢀ/0.71073 A).
/
/
2.3. Preparation of complexes
The complexes [Ru(trpy)(L?)(Cl)](ClO₄)×
and 1b) were prepared by following a general procedure.
ities of the complexes including the catalytic/electro-
catalytic behaviors of the in situ generated oxo species
/2H₂O (1a
(3). The specific role of the electronic nature of L? in 1Á3
/
in comparison with the analogous ancillary functions
present in other known ruthenium monoterpyridine
complexes have been noted.
Details are mentioned for the complex 1a.
2.4. [Ru(trpy)(L?)(Cl)]ClO₄×
/
2H₂O (1a)
2. Experimental
The starting complex Ru(trpy)Cl₃ (100 mg, 0.227
mmol) was taken in 25 ml of hot EtOH. The preformed
bridging ligand L¹ (65 mg, 0.228 mmol) was added to
the above solution and the mixture was heated to reflux
for 14 h. The solvent was removed under reduced
pressure. The residual mass was dissolved in a minimum
volume of MeCN and saturated aq. NaClO₄ solution
was added. The solid product thus obtained on cooling
was filtered and washed with ice-cold water followed by
cold EtOH. The crude product was purified by using an
alumina (neutral) column. Initially the side product,
2.1. Materials
The starting complex Ru(trpy)Cl₃ and the ligands
L^1Á2 were prepared according to the reported proce-
dures [30,28]. 2,2?:6,2ƒ-terpyridine was obtained from
Aldrich, USA. Other chemicals and solvents were
reagent grade and used as received. Alumina (neutral)
was used for column chromatography. For spectro-
scopic and electrochemical studies HPLC grade solvents
were used. Water of high purity was obtained by
distillation of the deionized water from KMnO₄. So-
dium perchlorate for electrochemical work in aqueous
medium was recrystallized from water.
[Ru(trpy)₂](ClO₄)₂×
(5:2) mixture. The pink colored complex, 1a was eluted
by CH₂Cl₂ÁMeCN (5:3) mixture. Another fraction of
the pink solution corresponding to 1a was eluted later
by CH₂Cl₂ÁMeCN (1:1) from the same column. The
/
2H₂O was eluted by CH₂Cl₂Á
/MeCN
/
/
2.2. Physical measurements
complex 1a thus obtained from the two different batches
were further purified separately by following the same
above procedures in order to remove any trace of
UVÁVis spectra were recorded by using a Shimadzu-
/
2100 spectrophotometer. FT-IR spectra were taken on a
Nicolet spectrophotometer with samples prepared as
KBr pellets. Solution electrical conductivity was checked
using a Systronic 305 conductivity bridge. Magnetic
susceptibility was checked with a PAR vibrating sample
magnetometer. NMR spectra were obtained with a 300
MHz Varian FT spectrometer. Cyclic voltammetric,
differential pulse voltammetric and coulometric mea-
surements were carried out using a PAR model 273A
electrochemistry system. Platinum wire working and
auxiliary electrodes and an aqueous saturated calomel
reference electrode (SCE) were used in a three-electrode
configuration. The supporting electrolyte was
[NEt₄]ClO₄ and the solute concentration was approxi-
[Ru(trpy)₂](ClO₄)₂×
/
2H₂O impurity. Similarly the
[Ru(trpy)₂](ClO₄)₂×
/
2H₂O complex obtained from the
above column was also purified again in order to
make it free from 1a. The two pink colored solutions
thus obtained separately from the same column were
found to exhibit identical spectral and electrochemical
features. Evaporation of the solvent mixture resulted in
pure solid complexes, 1a and [Ru(trpy)₂](ClO₄)₂×
Yield: 1a (95.0 mg, 61%) and [Ru(trpy)₂](ClO₄)₂×
(15 mg, 10%). Anal. Calc. for 1a: C, 46.15; H, 3.73; N,
11.97. Found: C, 46.31; H, 3.45; N, 12.22%. L_M/V^ꢁ1
(cm² mol^ꢁ1) in MeCN at 298 K: 148. Anal. Calc. for 1b:
C, 50.90; H, 3.89; N, 10.80. Found: C, 50.52; H, 3.32; N,
11.02%. L_M/V^ꢁ1 (cm² mol^ꢁ1) in MeCN at 298 K: 140.
/
2H₂O.
2H₂O
/

N. Chanda et al. / Polyhedron 21 (2002) 2033Á
/2043
2035
2.5. [Ru(trpy)(L?)(H₂O)](ClO₄)₂×
/
2H₂O (2a)
3. Results and discussion
The aqua complexes (2) were prepared from the
corresponding chloro species using excess AgNO₃. De-
tails are mentioned for 2a.
3.1. Synthesis
The bridging ligands L¹Ã
study differ primarily with respect to the length of the
spacers (Scheme 1). The ligands are designed with the
intention of holding two Ru(trpy)Cl units through the
/
L², used for the present
Silver nitrate (120 mg, 0.70 mmol) was added to the
solution
aqueous
of
the
chloro
complex,
[Ru(trpy)(L?)(Cl)]ClO₄×
/
2H₂O (1a) (100 mg, 0.14 mmol
in 15 ml water) and the solution was heated to reflux for
2.5 h. It was then cooled and the precipitated AgCl was
filtered off through a sintered glass crucible (G-4). The
volume of the filtrate was reduced to 5 ml and saturated
aq. NaClO₄ solution was added to it. The mixture was
kept in the refrigerator overnight. The solid product (2a)
thus obtained was filtered and washed with ice-cold
water and dried in vacuo over P₄O₁₀. Yield: 78 mg
(70%). Anal. Calc. for 2a: C, 41.34; H, 3.60; N, 10.71.
Found: C, 40.92; H, 3.33; N, 10.37%. L_M/V^ꢁ1 (cm²
mol^ꢁ1) in MeCN at 298 K: 230. Anal. Calc. for 2b: C,
46.06; H, 3.75; N, 9.77. Found: C, 46.59; H, 3.43; N,
10.11%. L_M/V^ꢁ1 (cm² mol^ꢁ1) in MeCN at 298 K: 240.
terminal N_p (N_pꢀ
/
pyridine nitrogen) and N_i (N_iꢀimine
/
nitrogen) donor centers of L. However, the reaction of L
with the starting complex Ru(trpy)Cl₃ in a 1:2 mole
ratio in ethanol solvent results in a monomeric species of
the type [Ru(trpy)(L?)Cl]^ꢂ, 1 where L? corresponds to
NC₅H₄CHÄ
/
NÃ
/
(C₆H₄)_n Ã
/
NH₂ (nꢀ
/
1, 1a; nꢀ2, 1b)
/
(Scheme 1).
During the course of the reaction one of the imine
functions of the preformed bridging ligands (L) has been
selectively hydrolyzed and the resulting mononucleating
fragment of the bridging moiety (L?) leads to the
formation of 1 (Scheme 1). The complexes have been
isolated as their dihydrated perchlorate salts,
[Ru^II(trpy)(L?)Cl]ClO₄×
/2H₂O (1).
Under identical reaction conditions (Scheme 1) but in
the absence of ruthenium precursor Ru(trpy)Cl₃, the
preformed bridging functions (L) are found to remain
intact, implying the effective role of the metal fragment
2.6. X-ray structure determination
The single crystals of L¹ were grown by slow diffusion
of a CH₂Cl₂ solution of L¹ in C₆H₁₄ followed by slow
evaporation. The single crystals of 1a were obtained by
slow diffusion of the MeCN solution of 1a in C₆H₆
followed by slow evaporation. Significant crystal data
and data collection parameters are listed in Table 1. The
in transforming L0L? in 1.
/
The synthesis of 1 by using a 1:2 mole ratio of L and
Ru(trpy)Cl₃ is always observed to be accompanied by
the formation of a [Ru(trpy)₂]^2ꢂ complex in an
approximately 1:1 ratio. However, the use of a 1:1
mole ratio of L and Ru(trpy)Cl₃ reduces the yield of
structures were solved by direct methods using ^SHELXS
86 and refined by full-matrix least-squares on F² using
-
[Ru(trpy)₂]^2ꢂ to an appreciable extent {1Á
/
[Ru(trpy)₂]^2ꢂ, 6:1, Section 2}. In order to minimize
the perpetual formation of the undesired product
[Ru(trpy)₂]^2ꢂ, the 1:1 mole ratio of L and Ru(trpy)Cl₃
had always been selectively used.
SHELXL-97 [31].
Table 1
Crystallographic data for NC₅H₄ÃCHÄNÃ(C₆H₄)ÃNÄCHÃH₄C₅N
(L¹) and [Ru^II(trpy){NC₅H₄ÃCHÄNÃC₆H₄ÃNH₂}Cl]ClO₄ (1a)
L¹
1a
Empirical formula
M
C₉H₇N₂
143.17
C₂₇H₂₂N₆Cl₂O₄Ru
666.48
Crystal symmetry
Space group
monoclinic
P2₁/a
monoclinic
P2₁/n
˚
a (A)
11.5290 (14)
4.8118 (6)
13.7074 (14)
109.14 (1)
718.39 (14)
4
8.4410 (10)
13.884 (2)
23.673 (4)
98.710 (10)
2742.4 (7)
4
˚
b (A)
˚
c (A)
b (8)
3
V (A )
˚
Z
m (mm^ꢁ1
R₁
)
0.082
0.0403
0.0940
0.812
0.0877
0.0999
wR₂
Scheme 1. (i) EtOH, heating, N₂.

2036
N. Chanda et al. / Polyhedron 21 (2002) 2033Á2043
/
Although the unsymmetrical nature of L? in 1 leads to
the possibility of the simultaneous formation of two
isomers A and B, here the reaction (Scheme 1) system-
atically results in one particular isomeric product (see
NMR). The existence of the isomeric form B has been
confirmed by single-crystal X-ray structure for 1a (see
later). Based on the similar spectral features of 1a and 1b
(see later), we believe that the complex 1b also exists in
same isomeric form B.
The aqua complexes [Ru^II(trpy)(L?)(H₂O)]^2ꢂ (2) have
been isolated as their dihydrated perchlorate salts from
the corresponding chloro complexes (1) in the presence
of excess aqueous AgNO₃.
Fig. 1. An ORTEP diagram for NC₅H₄CHÄ
/
NÃ
/
C₆H₄Ã
/
NÄCHC₅H₄N,
/
L¹. Atoms are drawn at 50% probability.
The oxo-complexes [Ru^IV(trpy)(L?)(O)]^2ꢂ (3) can be
generated in solution state by chemical oxidation of the
aqua species (2) using excess ceric solution in 1 (N)
H₂SO₄. The isolation of the pure oxo derivative (3) in
the solid state has not been successful as in the absence
of Ce^IV ion the oxo-species reduces back to the parent
aqua species (see later).
The isolated chloro (1) and aqua (2) complexes are
diamagnetic and show 1:1 and 1:2 conductivities,
respectively (Section 2). The complexes exhibit satisfac-
tory elemental analyses (Section 2).
Table 2
˚
Selected bond distances (A) and angles (8) and their standard
deviations for L¹ and 1a
L¹
1a
Bond distances
N(1)ÃC(1)
N(1)ÃC(5)
N(2)ÃC(6)
N(2)ÃC(7)
C(4)ÃC(5)
C(5)ÃC(6)
1.335(2)
1.343(2)
1.264(2)
1.424(2)
1.384(2)
1.473(2)
RuÃN(1)
RuÃN(2)
RuÃN(3)
RuÃN(4)
RuÃN(5)
RuÃCl(1)
N(5)ÃC(21)
1.978(9)
2.080(9)
2.080(9)
2.097(10)
2.057(10)
2.414(3)
1.306(12)
Bond angles
3.2. Crystal structures of NC₅H₄CHÄ
/
NÃ
/
(C₆H₄)Ã
/
NÄ
/
C(6)ÃN(2)ÃC(7)
N(1)ÃC(5)ÃC(6)
C(4)ÃC(5)ÃC(6)
N(2)ÃC(6)ÃC(5)
119.90(16)
114.79(16)
122.45(17)
123.16(17)
N(1)ÃRuÃN(5)
N(1)ÃRuÃN(3)
N(5)ÃRuÃN(3)
N(1)ÃRuÃN(2)
N(5)ÃRuÃN(2)
N(3)ÃRuÃN(2)
N(1)ÃRuÃN(4)
N(5)ÃRuÃN(4)
N(2)ÃRuÃN(4)
N(1)ÃRuÃCl(1)
N(5)ÃRuÃCl(1)
N(3)ÃRuÃCl(1)
N(2)ÃRuÃCl(1)
N(4)ÃRuÃCl(1)
99.5(4)
79.7(5)
89.7(3)
79.4(4)
95.6(3)
159.0(4)
176.1(4)
77.6(4)
103.4(4)
89.5(3)
170.7(3)
89.7(2)
88.2(2)
93.3(3)
CHC₅H₄N (L¹) and [Ru(trpy)(L?)Cl](ClO₄) (1a)
The single crystal X-ray structure of L¹ is shown in
Fig. 1. It shows that each half of the molecule is related
to the other half by symmetry. Selective bond distances
and angles are listed in Table 2. The bond distances and
angles match well with the standard values.
The crystal structure of [Ru(trpy)(L?)Cl](ClO₄) (1a) is
shown in Fig. 2. Selective bond distances and angles are
listed in Table 2. The terpyridine group coordinates to
the ruthenium center in a meridional fashion with the
ligand L? in a cis orientation. The chloride ligand is
trans to the imine nitrogen (N_i) of L? (structure B). The
˚
N(1) distance [1.978(9) A] of terpyridine is
central RuÃ
/
The cationic molecules are packed in a zigzag manner
with anions (ClO₄^ꢁ) in between the zip when viewed
down the a-axis (Fig. 3). Both the hydrogens of the
pendant amine group are involved in hydrogen bonding.
Hydrogen H(6A) forms hydrogen bonds with the
shorter than the terminal RuÃ
/
N(2)/RuÃ
16]. Correspondingly, the geometrical
strain of the meridionally disposed terpyridine ligand is
reflected in the short trans angle, 159.0(4)8 [14Á16]. The
N(5) [imine nitrogen, 2.057(10) A], RuÃN(4)
/
N(3) distances,
˚
2.080(9) A [14Á
/
/
Ru^IIÃ
[pyridine nitrogen of L?, 2.097(10) A] and Ru Ã
/
/
˚
II
˚
chlorine atom Cl(1) [ꢁ
RuÃCl, N(6)ÃH(6A)Á Á ÁCl(1)ꢀ
forms hydrogen bonds with the oxygen atom O(2) of
/
xꢂ
/
3/2, yꢁ
/
1/2, ꢁ
/
zꢂ
/
1/2] of
/
Cl
[2.414(3) A] distances in 1a are in agreement with those
of reported similar complexes [16Á20,32,33].
˚
˚
/
/
/
2.543 A while H(6B)
/

N. Chanda et al. / Polyhedron 21 (2002) 2033Á
/2043
2037
the expected 22 and 26 signals, respectively (Fig. 4(b and
c)). The signals due to the NH₂ group [which is absent in
the free ligands (Fig. 4(a))], the pendant phenyl ring(s)
and the azomethine (Ã
/
CHÄ
/
NÃ) function of L? appear in
/
isolated regions and are therefore assigned. On the other
hand the signals due to the terpyridine ligand and the
pyridine fragment of L? are found to overlap severely
which essentially restricts the identification of the
individual protons. However, the direct comparison of
the intensity of these proton signals with that of the
clearly observable NH₂ protons or Ã
/
CHÄ
/
NÃ
/
proton
reveals the presence of the calculated number of protons
in both the complexes.
Electronic spectral data of the isolated complexes 1a,
1b, 2a and 2b are listed in Table 4. The complexes
display moderately strong MLCT transitions in the
Fig. 2. An ORTEP diagram for [Ru^II(trpy)(L?)Cl]ClO₄ (1a). Atoms are
drawn at 50% probability.
visible region (l_max
ꢀ500 nm for 1 and approximately
/
470 nm for 2) and strong intra ligand transitions in the
UV region (Fig. 5) [34,35]. The observed order of
MLCT band energy, 1(Cl^ꢁ)B
/
2(H₂O) (Table 4, Fig. 5)
is due to relative stabilization of the dp(Ru) state while
moving from Cl^ꢁ 0
H₂O.
the translated perchlorate anion moiety, N(6)Ã
/
˚
H(6B)Á Á ÁO(2)ꢀ
distance of 1.372 A is longer compared to the other
O distances in the ClO₄^ꢁ anion which may be due to
/
2.123 A (Table 3). The Cl(2)Ã
/
O(2)
/
˚
The replacement of one strong p-acidic tridentate trpy
ligand from the [Ru(trpy)₂]^2ꢂcore by L? and Cl^ꢁ
decreases the MLCT transition energy reasonably {the
MLCT transition of [Ru(trpy)₂]^2ꢂ appears at 478 nm
[36]}, however the MLCT transition energy remains
almost unaltered when the combination of L?/H₂O is
used to replace one trpy group from the [Ru(tr-
py)₂]^2ꢂcore.
ClÃ
/
its involvement in the hydrogen bonding.
3.3. Spectral properties
The n(CÄ
/
N) stretching frequency of the coordinated
L? has been observed near 1600 cm^ꢁ1. The bands due to
The MLCT transition energy of the aqua derivative,
2a varies reasonably depending on the nature of the
coordinating solvents [37], however little variation has
been observed in case of 2b (Table 4).
The other known ruthenium terpyridine aqua com-
plexes [Ru(trpy)(Lƒ)(H₂O)]^2ꢂ incorporating analogous
ionic perchlorate and n(RuÃ
/
Cl) have appeared near
1100/630 and 300 cm^ꢁ1, respectively.
The ¹H NMR spectra of the free ligands (L) in CDCl₃
(Fig. 4(a)) exhibit the signals corresponding to half of
the molecule as expected due to the internal symmetry.
The complexes (1a and 1b) in DMSO-d⁶ solvent display
Fig. 3. Packing diagram of the molecule [Ru^II(trpy)(L?)Cl]ClO₄ (1a) viewed down the a-axis.

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N. Chanda et al. / Polyhedron 21 (2002) 2033Á2043
/
Table 3
˚
Hydrogen bonds for 1a [A and (8)]
DÃH
d(DÃH)
d(HÁ Á ÁA)
ꢀDHA
d(DÁ Á ÁA)
A
N(6)ÃH(6A)
N(6)ÃH(6B)
0.998
0.987
2.543
2.123
150.65
166.24
3.448
3.090
Cl(1) [ꢁxꢂ3/2, yꢁ1/2, ꢁzꢂ1/2]
O(2) [ꢁxꢂ2, ꢁyꢂ1, ꢁzꢂ1]
ancillary moieties, Lƒꢀ
azopyridine [15] and 3,6-di(pyrid-2-yl)pyridazine [19]
exhibit MLCT transitions at 477, 494, 487Á490 and
480Á491nm, respectively.
/
bipyridine [21], bipyrazine [18],
The complexes (1) exhibit moderately strong emis-
sions near 590 nm in MeOHÁEtOH (1:4 v/v) glass at 77
K from the lowest energy MLCT transitions (l_excitation
1a, 517 nm; 1b, 520 nm; l_emission: 1a, 590 nm; 1b, 592
/
/
:
/
Fig. 4. ¹H NMR spectra of: (a) NC₅H₄CHÄ
[Ru^II(trpy)(L?)Cl]ClO₄×2H₂O (1b) in DMSO-d⁶.
/
NÃ
/
C₆H₄Ã
/
C₆H₄Ã
/
NÄ
/
CHC₅H₄N, L² in CDCl₃; (b) [Ru^II(trpy)(L?)Cl]ClO₄×
2H₂O (1a); and (c)
/
/

N. Chanda et al. / Polyhedron 21 (2002) 2033Á
/2043
2039
Table 4
Electronic spectral data
Complex UVÁ
/
Vis l (nm) (o , M^ꢁ1 cm^ꢁ1
)
CH₃CN
CH₃OH
H₂O
DMF
1a
1b
521 (8540)
313 (33 480)
275 (34 090)
234 (35 260)
214 (42 510)
503 (5890)
314 (41 230)
278 (37 380)
232 (39 970)
213 (47 220)
2a
2b
471 (6370)
446 (6140)
475 (6780)
474 (5590)
312 (32 000) 310 (26 890) 315 (33 530)
480 (6900)
302 (33 080) 274 (25 740) 273 (21 800) 277 (27 510)
274 (26 310)
473 (7860)
472 (8430)
473 (6820)
474 (9450)
304 (48 870) 304 (50 500) 304 (34 480) 315 (48 870)
280 (32 370) 280 (35 820) 278 (31 800) 285 (36 640)
nm; quantum yield (F_em): 1a, 0.03; 1b, 0.015, Fig. 5,
(inset). The observed emissions are believed to have
originated from the ³MLCT excited states [38]. The
quantum yields (F_em) of the emission processes were
measured in the MeOHÁEtOH (1:4 v/v) glass at 77 K
/
relative to [Ru(bpy)₃]^2ꢂ for which F_em
ꢀ0.35 [39].
/
3.4. Electron-transfer properties
Fig. 5. Electronic spectra of: (a) [Ru^II(trpy)(L?)Cl]ClO₄×
/
2H₂O (1a) in
acetonitrile. Inset shows emission spectrum of [Ru^II(trpy)(L?)Cl]ClO₄×
/
Redox properties of the complexes 1 and 2 have been
studied in acetonitrile and water, respectively using a
platinum working electrode at 298 K. Representative
voltammograms are shown in Fig. 6. The chloro
2H₂O (1a) in EtOHÁ
[Ru^II(trpy)(L?)(H₂O)](ClO₄)₂×
H₂O (------), CH₃CN (-×-×-).
/
MeOH 4:1 (v/v) at 77 K; (b)
/
2H₂O (2a) in DMF (*), MeOH (----),
/
/
/
complexes
ruthenium(III)Á
mV) at 0.80 (90) and 0.85 (90) versus SCE, respectively.
Thus the ruthenium(III)Áruthenium(II) potential in-
creases with the increase in number of phenyl rings in
the ligand framework (L?). Although the complexes (1)
can be coulometrically oxidized to the corresponding
ruthenium(III) congeners (1^ꢂ), the oxidized species are
found to be unstable at room temperature. The observed
1a
and
1b
display
reversible
The complex, 1a exhibits one irreversible reduction,
E_pc at ꢁ1.09 V and 1b displays one quasi-reversible
reduction, E8₂₉₈, V (DE_p, mV), at ꢁ0.96 (190). These
are believed to be terpyridine based reductions [40].
Cyclic voltammograms of the aqua species (2a and 2b)
have been recorded in aqueous medium in the pH range
/
ruthenium(II) couples, E8₂₉₈, V (DE_p,
/
/
/
1Á12. The complexes exhibit one quasi-reversible oxida-
/
tive response each at the positive side of SCE (Fig. 6(b)).
The potentials of the responses are observed to decrease
linearly with the increase in pH (Fig. 6(c)). The
ruthenium(III)Áruthenium(II) potential of 1 is compar-
/
able to that of [Ru(trpy)(bipyridine)Cl]^ꢂ (0.81 V) [18]
but less anodic compared to those of analogous com-
plexes incorporating other types of N,N-donors based
ancillary functions such as, [Ru(trpy){3,6-di(pyrid-2-
electronÁ
the pH range 1Á
of the experimentally derived potentialÁ
6(c)) [21]. In the pH ranges 1Á9 and ꢀ
/
proton content of the redox processes over
12 have been estimated from the slopes
pH plots (Fig.
9.0, the
/
/
/
/
yl)pyridazine}Cl]^ꢂ
(0.89Á
/
1.04
V)
[19];
1.24 V) [15] and
potentials change at the rate of approximately 60 and
30 mV, respectively per unit change in pH. Therefore,
[Ru(trpy)(azopyridine)Cl]^ꢂ (1.10Á
/
[Ru(trpy)(2,2?-bipyrazine)Cl] (1.07 V) [18]. Thus the p-
acceptor strength of L? in 1 can be considered to be
appreciably closer to that of the bipyridine ligand.
the redox processes in the pH range 1Á
associated with 2e^ꢁ/2H^ꢂ and 2e^ꢁ/H^ꢂoxidation pro-
cesses, respectively (Eqs. (1) and (2)) [19Á21]. The pK_a
/
9 and ꢀ
/
9 are
/

2040
N. Chanda et al. / Polyhedron 21 (2002) 2033Á2043
/
the acidity of the coordinated H₂O molecule or in other
words the electronic aspect of the ancillary functions.
3.5. Chemical oxidation of [Ru^II(trpy)(L?)(H₂O)]^2ꢂ
(2)0
[Ru^IV(trpy)(L?)(O)]^2ꢂ (3): role of 3 in
catalyzing the water oxidation process
/
Chemical oxidation of the aqua complex (2) by excess
aqueous ceric solution in 1 (N) H₂SO₄ leads to the
spontaneous formation of a yellow colored species. The
intensity of the MLCT band of [Ru(trpy)(L)(H₂O)]^2ꢂ
near 470 nm is found to decrease systematically on
progressive addition of Ce^IV solution with the concomi-
tant development of a new band near 320 nm (Fig. 7).
The plots of absorbance versus [Ce^IV]/[2] show that
approximately 4.0 mole ratio of Ce^IV: 2 is needed for the
complete oxidation of the aqua species.
Considering the observed electrochemical concerted
2e^ꢁ/2H^ꢂ oxidation process of the aqua complexes in
acidic solution (Eqs. (1) and (2)) it can be assumed that
the chemical oxidation of 2 also leads to the formation
of the same oxo-species, Eq. (3).
Fig. 6. Cyclic voltammograms of: (a) [Ru^II(trpy)(L?)Cl]ClO₄×
2H₂O (2b) in
water at pH 9.5; and (c) variation of Ru^IV/Ru^II couple with pH in
water for 2b.
/
2H₂O
(1b) in acetonitrile; (b) [Ru^II(trpy)(L?)(H₂O)](ClO₄)₂×
/
[Ru^II(trpy)(L?)(H₂O)]^2ꢂ ꢂ2Ce^4ꢂ0
[Ru^IV(trpy)(L?)(O)]^2ꢂ ꢂ2e^ꢁ ꢂ2H^ꢂ ꢂ2Ce^3ꢂ (3)
values of the complexes 2a and 2b, calculated from the
intersection point of the two curves in E versus pH
graphs (Fig. 6(c)), are 9.0 and 8.7, respectively. The
values are in good agreement with the pK_a data (9.1 for
2a and 9.0 for 2b) determined separately by
The oxo-complexes (3) thus formed are found to
reduce back partially to the parent aqua derivatives (2).
The MLCT band at 474 nm, characteristic of the aqua
species, develops slowly with time but levels off before
attaining the calculated intensity of the standard aqua
species (Fig. 7, inset). The percent conversion of the oxo
(3) to aqua (2) for 3a and 3b are calculated to be 63 and
69%, respectively. The further addition of acidic Ce^ꢂ4
solution into the mixture of 2 and 3 oxidizes the solution
completely to the oxo-state and the cycle follows.
Therefore, the oxo-species is stable only in presence of
excess oxidant. The observed partial conversion of oxo
to aqua species possibly can account for the need of
[Ru^II(trpy)(L?)(H₂O)]^2ꢂ0[Ru^IV(trpy)(L?)(O)]^2ꢂ ꢂ2e^ꢁ
ꢂ2H^ꢂ
(1)
[Ru^II(trpy)(L?)(OH)]^ꢂ0[Ru^IV(trpy)(L?)(O)]^2ꢂ ꢂ2e^ꢁ
ꢂH^ꢂ
(2)
spectrophotometric titrations using sodium hydroxide.
The pK_a values of the similar monoterpyridine aqua
complexes [Ru(trpy)(Lƒ)(H₂O)]^2ꢂ, Lƒꢀ
2,2?-bipyridine,
/
1,10-phenanthroline, 2,2?-bipyrazine, 3,6-di(pyrid-2-
yl)pyridazine, tetramethylene diamine, and azopyridine
excess ceric rather than the 1:2 mole ratio of 2Á
Ce^IV as
/
expected from the stoichiometric oxidation reaction (Eq.
(3)). The partial conversion of oxo to aqua species has
essentially precluded the isolation of the oxo-complexes
in the pure solid state. The observed conversion of the
oxo to aqua species and the subsequent reverse reaction,
aqua to oxo on further addition of Ce^4ꢂ can be best
explained on the basis of earlier observations [15,17,41]
i.e. the involvement of the chemically generated oxo-
species in the catalytic water splitting reaction (Scheme
2). It may be noted that in the case of the azopyridine
analogue, the oxo complex was found to transform
quantitatively to the aqua species and the backward
process, aqua to oxo was observed on further addition
of Ce^4ꢂ. Therefore, as far as water splitting is concerned
the present oxo-species (Scheme 2) is much less efficient
as compared to the corresponding azopyridine deriva-
are 9.7, 9.6, 8.8, 10.3, 10.2 and 7.9Á/8.5, respectively
[15,18Á20]. Thus, as far as the acidity of the coordinated
/
aqua molecule is concerned, the present set of complexes
(2a and 2b) are closest to the bipyrazine derivative.
Similar proton coupled electron-transfer processes
have been observed in case of bipyrazine [18] and 3,6-
di(pyrid-2-yl)pyridazine [20] complexes. However, the
bipyridine analogue shows two step processes in the
acidic region, [Ru^II(trpy)(bpy)(H₂O)]^2ꢂ 0
(bpy)(OH)]^2ꢂꢂe^ꢁꢂH^ꢂ and [Ru^III(trpy)(bpy)(OH)]^2ꢂ
[Ru^IV(trpy)(bpy)(O)]^2ꢂꢂ H^ꢂ [21]. On the other
/
[Ru^III(trpy)-
/
/
0
/
/
e^ꢁꢂ
/
hand the azopyridine analogue exhibits 2e^ꢁ/2H^ꢂ-
transfer process specifically in the highly acidic region
[15]. Therefore, electron-transfer behavior of the ruthe-
nium terpyridine aqua species is primarily controlled by

N. Chanda et al. / Polyhedron 21 (2002) 2033Á
/2043
2041
Fig. 7. Change in absorbance of [Ru^II(trpy)(L?)(H₂O)](ClO₄)₂×
/
2H₂O (2a) as a function of [Ce^IV]. Ratio of [Ce^IV]Á
/
2aꢀ
/
(1) 0:1, (2) 0.5:1, (3) 1:1, (4)
1.5:1, (5) 2:1, (6) 2.5:1, (7) 3:1, (8) 3.5:1. Inset shows time evolution of the electronic spectra of a changing solution of [Ru^IV(trpy)(L?)(O)]^2ꢂ (3a)0
/
[Ru^II(trpy)(L?)(H₂O)]^2ꢂ (2a) in water [1 (N) H₂SO₄] at 298 K. The arrows indicate increase or decrease in band intensities as the reaction proceeds.
similar electrocatalytic behavior has been reported in
case of the corresponding bipyrazine and 3,6-di(4-
methylpyrid-2-yl)pyridazine complexes [18Á20]. Here
/
catalytic current increases with the increase in ratio of
[benzyl alcohol]/[2] as expected and maximum catalytic
current is observed in case of 25:1 ratio of [benzyl
alcohol]/[2]. The catalytic effect has been quantifiedly
based on the experimentally observed excess current (i_ex)
with respect to the current only due to the catalyst (i_ct)
(same catalyst concentration has been used for both the
standard and the mixture containing the substrate) at a
particular potential (Eq. (4)) (Fig. 8) [45]. Here i_o is the
observed current for
Scheme 2.
tive, which is certainly due to the greater p-acceptor
character of the azopyridine function.
i_ex ꢀi_o ꢂi_d ꢁi_ct
the mixture and i_d is the difference in current between
the catalyst and the catalystꢂsubstrate at the concerned
base line potential. The turnover numbers (t) of the
processes
(4)
3.6. Electrocatalytic oxidation of benzyl alcohol
/
The cyclic voltammetric experiments of the aqua
species [Ru(trpy)(L?)(H₂O)]^2ꢂ (2) in the presence of
benzyl alcohol have been studied in order to examine the
role of the electrogenerated [Ru(trpy)(L?)(O)]^2ꢂ (3)
tꢀi_ex=i_ct
(5)
towards the oxidaton of benzyl alcohol [18Á
/
20,42Á44].
/
(Scheme 3; Fig. 8) calculated by using Eq. (5) are found
to be 2.7 and 2.3 for 3a and 3b, respectively. Further
studies on the catalytic aspect of 3 are in progress.
The cyclic voltammogram of 2b at pH 9.58 is shown in
Fig. 8. Under identical experimental conditions the
voltammogram of benzyl alcohol does not show any
appreciable current (Fig. 8). However, the voltammo-
gram of 2 in the presence of benzyl alcohol displays
substantially excess anodic current as compared to that
of the standard 2 (Fig. 8). Thus the oxidation of 2 to 3 is
followed rapidly by the reaction (Scheme 3) and the
regenerated 2 is reoxidized before it can diffuse away
from the electrode surface.
4. Conclusion
The role of a,a?-diimine based ancillary (L?) functions
in the ruthenium monoterpyridine [Ru-trpy] core (1Á3)
/
have been scrutinized with special reference to the
chemical and electrochemical behaviors of the oxo
Therefore, the electrogenerated 3 is involved in
catalyzing the benzyl alcohol oxidation process. A
species [Ru(trpy)(L?)(O)]^2ꢂ (3). The ruthenium(III)Á
/

2042
N. Chanda et al. / Polyhedron 21 (2002) 2033Á2043
/
Fig. 8. Cyclic voltammograms of benzyl alcohol in water (20.32ꢃ
/
10^ꢁ3 M) (*
/
); [Ru^II(trpy)(L?)(H₂O)](ClO₄)₂×
-×-).
/2H₂O (2b) in water at pH 9.58
(0.96ꢃ
/
10^ꢁ3 M) (----) and the mixture of the two taken at the same concentrations (-×
/
/
emphasizes the serious impact of the electronic aspect of
the ancillary functions in directing the reactivity pattern
of the ruthenium monoterpyridine aqua species.
5. Supplementary material
Crystallographic data for the structural analysis have
been deposited with the Cambridge Crystallographic
Data Center, CCDC Nos. 170396Á170397 for com-
/
pounds 1a and L¹. Copies of this information may be
obtained free of charge from The Director, CCDC, 12
Union Road, Cambridge, CB2 1EZ, UK (fax: ꢂ44-
/
1223-336033; e-mail: deposit@ccdc.cam.ac.uk or www:
http://www.ccdc.cam.ac.uk).
Scheme 3.
ruthenium(II) potential of the chloro species
[Ru(trpy)(L?)(Cl)]^ꢂ (1) is comparable to that of the
corresponding bipyridine complex but less anodic com-
pared to the analogous complexes incorporating 3,6-
di(pyrid-2-yl)pyridazine, bipyrazine and azopyridine
Acknowledgements
Financial support received from the Council of
Scientific and Industrial Research, New Delhi, India, is
gratefully acknowledged. The X-ray structural studies
were carried out at the National Single Crystal Dif-
fractometer Facility, Indian Institute of Technology,
Bombay. Special acknowledgement is made to the
Regional Sophisticated Instrumental Center, RSIC,
Indian Institute of Technology, Bombay, for providing
NMR facility.
ancillary
functions.
The
aqua
complex
[Ru(trpy)(L?)(H₂O)]^2ꢂ (2) undergoes one-step-2e^ꢁ/
2H^ꢂ and 2e^ꢁ/H^ꢂ transformations in the acidic and
basic regions, respectively to the corresponding oxo-
species [Ru(trpy)(L?)(O)]^2ꢂ (3) like the bipyrazine and
3,6-di(pyrid-2-yl)pyridazine derivatives. The chemically
generated oxo-species (3) catalyzes the water oxidation
process like the azopyridine derivative but much less
efficiently. The electrochemically generated oxo-species
(3) is found to be effective in catalyzing the oxidation of
benzyl alcohol like the bipyrazine and 3,6-di(pyrid-2-
yl)pyridazine derivatives. The present study therefore
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