New One-Pot Synthetic Route and Spectroscopic Characterization of Hydroxo-Bridged Stepped-Cubane Copper(II) Complexes

Asian Journal of Applied Science and Technology (AJAST)
Volume 6, Issue 4, Pages 21-31, October-December 2022
ISSN: 2456-883X
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New One-Pot Synthetic Route and Spectroscopic Characterization of
Hydroxo-Bridged Stepped-Cubane Copper(II) Complexes
Olufunso O. Abosede1*
& Joshua A. Obaleye2
1
Department of Chemistry, Federal University Otuoke, PMB 126, Bayelsa State, Nigeria.
2
Department of Chemistry, University of Ilorin, P.M.B. 1515, Ilorin, Kwara State, Nigeria.
Corresponding Author (Olufunso O. Abosede) - abosedeoo@fuotuoke.edu.ng*
DOI: https://doi.org/10.38177/ajast.2022.6402
Copyright: © 2022 Olufunso O.Abosede & Joshua A.Obaleye. This is an open-access article distributed under the terms of the Creative Commons Attribution
License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Article Received: 08 August 2022 Article Accepted: 23 October 2022 Article Published: 24 November 2022
░ 1. INTRODUCTION
Preponderance of metals in nature propels their uses as crucial components of enzymes and as catalyst for most
biological reactions. In particular, transition metals, their alloys and other metallic compounds have extensive uses
in our daily lives, in medical sector and as catalysts in a variety of industrial processes because of their unique and
tunable properties. Metals and their compounds have also been widely applied as materials for memory and data
storage; they play key roles in electrochemical sensor devices in addition to their uses as drugs and diagnostic tools
[1],[2].
Transition metals such as copper and their compounds feature significantly in biological systems by directing the
geometry of enzymatic active sites, acting as enzyme activators, and facilitating reactions of enzymes by shutting
electrons out or by helping to bind to substrate. For instance, copper is an essential trace element that constitutes
important cellular components and plays crucial roles in important biological, technological and industrial
processes.
The distinctive and diverse properties of metal complexes have been widely employed in the application of
metal-containing medicinal agents, diagnostic tools which can be used to quantify detect, or affect biological
processes at microscopic level [3].
Currently, scientists are designing a wide range of metal complexes to advance new therapeutics with custom-made
designs and features that model the desirable properties of biomolecules. Polynuclear Cu(II) complexes are a class
of complexes with rich versatile structural varieties and magnetic properties which elicit their interesting
applications in bio-inorganic chemistry, catalysis and magnetism [4-7]. Examples of such metal complexes which
have considerable importance are cubane complexes with Cu4O4 chromophore which possess rich magnetic and
ABSTRACT
A new convenient and efficient route for the synthesis of two very important hydroxo-bridged stepped-cubane copper complexes viz:
[Cu4(bpy)4Cl2(OH)4]Cl2.6H2O (1) and [Cu4(phen)4Cl2(OH)4]Cl2.6H2O (2) have been obtained. This synthetic route from the mononuclear CubpyCl2
complex is easier, more reproducible and afforded the complex in a much higher yield than the other two previously reported procedures which were
equally serendipitously discovered. The purity and formation of the complexes were confirmed with elemental (C,H,N) analysis and the details of the
UV-Vis, Fourier transform infrared, electrospray ionization mass spectra of both complexes and the single crystal X-ray crystallography of 1 are
presented and discussed. X-ray crystallography confirms the absolute structure of the complexes. The complexes were formed via the connection of
four copper atoms to four hydroxide bridging ligands and four bipyridyl ligands with two chloride ligands. There are two coordinate environments
around two pairs of copper atoms (CuN2ClO2 and CuN2O3) and each copper atom is pentacoordinate with square pyramidal geometry.
Keywords: Copper; Tetranuclear; Cubane; Synthesis; Complexes; Spectroscopy.

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structural properties that have enabled their applications as single molecule magnets [8],[9] in biological inorganic
chemistry [4],[7],[10] and in catalysis [9],[10],[13]. Such metal complexes have been widely applied as efficient
water oxidation electrocatalysts in aqueous alkaline conditions because of their similarities to natural
oxygen-evolving complex (OEC) in photosystem II [11],[12]. Some of these complexes have also been tested as
catalysts [9],[10], and as DNA binding and nuclease agents [5],[7],[10].
In this present study, based on the crucial roles of copper complexes and the afore-mentioned applications of
tetranuclear copper cubane complexes, we report new one-pot, efficient, reproducible synthetic method for
hydroxo-bridged stepped cubane complexes viz: [Cu4(bpy)4Cl2(OH)4]Cl2.6H2O (1) and [Cu4(phen)4Cl2(OH)4]
Cl2.6H2O (2). The ESI-MS, UV-Vis and FTIR spectra of hydroxo-bridged stepped-cubane copper complexes
corroborates the synthesis of the complexes in good yield.
░ 2. MATERIALS AND METHODS
2.1. Materials
Analytical grade reagents and solvents were purchased from VWR International and used without further
purification. Elemental (C, H and N) analyses were carried out using standard methods with Elementar Analysen
Systeme Vario® MICRO VI 6.2 GmbH. UV–Vis spectra were measured using a JASCO V-730 UV-Vis
spectrophotometer. FTIR spectra were recorded in a range of 4,000–400 cm-1
on Shimadzu FTIR-8400S
instrument. Melting points were taken on a Jenway analytical instrument and were uncorrected. The electrospray
mass spectra were recorded on a THERMO Finningan LCQ Advantage max ion trap mass spectrometer. The
single-crystal X-ray diffraction data for 1 were collected at room temperature using Mo-Kα radiation. All
measurements were taken at room temperature.
2.2. Synthesis
2.2.1. Synthesis of precursor complexes
CubpyCl2
CubpyCl2was prepared by the following procedure. 0.0937 g (0.6 mmol) of 2, 2'-bipyridine was added to a solution
of 0.100g (0.6 mmol) of CuCl2.2H2O in 30 ml acetonitrile and the solution stirred for 1 hour. The precipitated light
green powder was filtered and dried in vacuum desiccator. FT-IR (KBr, /cm-1
): 3107, 3066, 3053, 3034, 1600,
1568, 1496, 1471, 1444, 1417, 1319, 1284, 1246, 1219, 1159, 1116, 1058, 1026, 974, 906, 804, 777, 729, 659, 634,
474, 441, 418. UV-Vis (H2O, nm): 300, 310, 369, 743. UV-Vis (CH3CN, nm): 242, 269, 298, 727, 746.
CuphenCl2
CuphenCl2was prepared by the following procedure. 0.1190 g (0.6 mmol) of 1, 10-phenthroline was added to a
solution of 0.100g (0.6 mmol) of CuCl2.2H2O in 30 ml acetonitrile and the solution stirred for 1 hour. The
precipitated light green powder was filtered and dried in vacuum desiccator. FT-IR (KBr, /cm-1
): 3078, 33057,
3043, 3012, 1626, 1606, 1583, 1514, 1494, 1423, 1348, 1222, 1199, 1145, 1107, 1047, 987, 902, 856, 779, 736,
721, 644, 542, 430.

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2.2.2. Synthesis of complexes
[Cu4(bipy)4Cl2(OH)4]Cl2.6H2O (1)
A mixture of 0.231 g (0.5 mmol) of lincomycin hydrochloride monohydrate, 0.144 g (0.5 mmol) of CubpyCl2 and
0.2 ml of triethyl amine in 5 ml of methanol was allowed to stand for one week. The blue precipitated crystals were
filtered and purified with about 10 ml methanol. Calculated: C, 40.14; H, 4.04; N, 9.36. Found: C, 40.22; H, 4.57;
N, 8.96. UV-Vis (H2O, nm): 235, 300, 311, 341, 370, 401, 618. FT-IR (KBr, /cm-1
): 3437, 3362, 3111, 3076,
3026, 1627, 1602, 1475, 1444, 1323, 1253, 1220, 1163, 1105, 1028, 997, 910, 810, 771, 731 690, 659, 628, 567,
545, 489, 472, 437, 414. Melting point: 165 o
C (dec).
[Cu4(phen)4Cl2(OH)4]Cl2.6H2O (2)
A mixture of 0.231 g (0.5 mmol) of lincomycin hydrochloride monohydrate, 0.157 g (0.5 mmol) of CuphenCl2 and
0.2 ml of triethyl amine in 5 ml of methanol was allowed to stand for one week. The blue precipitated crystals were
filtered and purified with about 10 ml methanol. Calculated: C, 45.22; H, 3.64; N, 8.79. Found: C, 45.07; H, 3.89;
N, 8.77. UV-Vis (H2O, nm): 204, 272, 294, 389, 639. FT-IR (KBr, /cm-1
): 3412, 3335, 3236, 3055, 2939, 2875,
2675, 2492, 1630, 1585, 1518, 1429, 1311, 1145, 1103, 1049, 991, 852, 723, 607, 430. Melting point: 178 o
C (dec)
░ 3. RESULT AND DISCUSSION
3.1. Spectroscopic Characterization
In an attempt to synthesize ternary CuII
complexes of lincomycin with bipyridine and phenanthroline, stepped
cubane tetranuclear hyroxo bridged CuII
complexes of the polypyridyl ligands were obtained. The UV-Vis, FT-IR,
ESI-Mass spectra of both complexes 1 and 2 and single crystal date of 1 have been obtained. Table 1 summarizes
the yield, physic-chemical and UV-Visible spectroscopic characterization of the complexes. The complexes exhibit
π-π*, metal-ligand charge transfer and d-d transitions. The d-d transitions for complexes 1 and 2 were at 618 and
639 nm respectively and are characteristic of a square pyramidal geometry around copper. The first example of an
hydroxo-bridged tetranuclear cubane-like copper(II) complex with a Cu4(OH)4 core was [Cu(2,2’-bipy)
(OH)]4(PF6)4 [14].
Table 1. UV-Vis and physico-chemical data of complexes 1 and 2
Compound λmax (nm) Transition Yield (%) Colour
Melting
Point (o
C)
1
235 π-π*
85 blue 165
300,311, 341,
370, 401
MLCT
618 d-d
2
204, 272, 294 π-π*
82 blue 178
389 MLCT
639 d-d

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In the FT-IR spectra of 1 strong absorption bands arising from O-H stretching vibration of both the hydroxo
bridging ligands and aqua outside the coordination sphere appear at 3437 and 3362 cm-1
. Sharp bands at 1602,
1501, 1475 and 1440 cm-1
arose from the alkene and imine vibrational stretching of bipyridine. The vibration
(weak) at about 950 cm-1
is due to O-H bend. The band at 489 cm-1
is assigned to copper-oxygen vibration as it falls
in the same range (480-515 cm-1
) with what is previously reported for hydroxyl-bridge CuII
complexes. For 2, the
band at 771 cm-1
is from imine C-N stretching of 1,10-phenanthroline while the stretching frequencies of both the
hydroxo bridging ligands and aqua outside the coordination sphere appeared at 3412 and 3335 cm-1
. Alkene and
imine stretching frequencies of 1,10-phenanthroline are found at 1630 cm-1
and at 1585 and 1518 cm-1
respectively.
The ESI-MS of complexes 1 and 2 provide additional evidence for the formation of the complexes with the
observed daughter ion peaks from the complexes. The peak at 512.0 (calculated: 509.2) in Complex 1 corresponds
to [Cu4bpy4Cl2(OH)4]2+
. Complex 2 showed a peak corresponding to [Cu2phen2Cl(OH)2]2+
at 557 (calculated:
556.592). Peaks at 278.0, 310.0 and 375.0 (calculated: 279, 313 and 376.6) correspond to CuphenCl,
[CuphenCl(OH)2] and [CuphenCl(OH)2 +Cu] respectively.
(a) (b)
Figure 1. Structures of (a) [Cu4(bpy)4Cl2(OH)4]Cl2.6H2O (1), and (b) [Cu4(phen)4Cl2(OH)4]Cl2.6H2O (2)
3.2. Single Crystal Analysis
The crystal structure of complex 1 has been solved and described previously [12],[13]. The complexes are typical
examples of tetranuclear copper(II) with Cu4(OH)4 core. The asymmetric unit possesses both μ2-OH and μ3-OH and
the structure of the compounds have chair-like stepped cubane structure. Two crystallographically independent
pentacoordinate copper atoms are found in the two complexes. The two copper atoms possess different
environments: CuN2O3 and CuN2O2Cl though the two coordination arrangements are square pyramids.
Even though the crystal structure of complex 1 has been previously reported, we have serendipitously obtained a
new route for the synthesis of this very important stepped-cubane complex. This synthetic route from the
mononuclear CubpyCl2 is easier, more reproducible and afforded the complex in a much higher yield than the other
two previously reported procedures [15,[16] of which the latter was also serendipitously discovered.
Crystallographic data showing the π-π stacking interaction and hydrogen bonding in the complex 1 have also been
collected and are presented in Figure 2. The structure contains centrosymmetric [Cu4(bpy)4Cl2(OH)4]2+
cations.
Each Cu(II) ion has five-coordinate, square pyramidal geometry and is coordinated to one bidentate bpy and two

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bridging hydroxo donors in the basal plane. The coordination sphere of Cu1 is completed by a chloride ion, while
Cu2 is coordinated to a μ3-OH, linking the two halves of the dimer together (under symmetry operation
-x+2,-y+2,-z+2). There is also a π-π interaction between the bpy ligands (mean interplanar distance 3.38 Å). The
bond lengths and angles are unexceptional; as might be expected the Cu-OH bonds are longer to the μ3-OH group
than to the μ2-OH bridge and the apical Cu-OH bond is considerably longer than the basal plane values. The Cu1 –
Cu2 distance in the Cu2(OH)2 unit is 2.897(4)Å. The hydroxo and chloro ligands, together with the solvate water
molecules are involved in hydrogen bonding, generating 2D sheets in which the cations are linked by H-bonded
rings. The sheets are linked via intermolecular π-stacking.
(a) (b)
Figure 2. Crystal structure of Cu4(bipy)4Cl2(OH)4]·Cl2·6H2O of (1): (a) at 50% ellipsoids; (b) H-bond sheet
(c) (d)
Figure 2. contd.: Crystal structure of Cu4(bipy)4Cl2(OH)4]Cl2·6H2O (c) π-π stacking; (d) Packing plot viewed
down b axis

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(e)
Figure 2. contd.: Crystal structure of Cu4(bipy)4Cl2(OH)4]Cl2·6H2O (e) Packing plot showing π-stacking
Table 2. Selected bond lengths [Å] and angles [°] for complex 1
Bond lengths [Å]
Cu(1)-O(2) 1.906(4)
Cu(1)-O(1) 1.954(4)
Cu(1)-N(21) 1.981(4)
Cu(1)-N(22) 2.008(4)
Cu(1)-Cl(1) 2.525(4)
Cu(1)-Cu(2) 2.897(4)
Cu(2)-O(2) 1.908(4)
Cu(2)-O(1) 1.938(4)
Cu(2)-N(12) 1.970(4)
Cu(2)-N(11) 1.986(4)
Cu(2)-O(1)#1 2.281(4)
Bond angles [°]
O(2)-Cu(1)-O(1) 80.83(19)
O(2)-Cu(1)-N(21) 165.69(14)
O(1)-Cu(1)-N(21) 96.77(19)
O(2)-Cu(1)-N(22) 96.34(19)
O(1)-Cu(1)-N(22) 157.33(15)
N(21)-Cu(1)-N(22) 80.4(2)

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Symmetry transformations used to generate equivalent atoms: #1 -x+2,-y+2,-z+2
Table 3. Atomic coordinates ( x 104) and equivalent isotropic displacement parameters (Å2x 103) for 1. U(eq) is
defined as one third of the trace of the orthogonalized Uij tensor
x y z U(eq)
Cu(1) 10440(1) 10540(1) 7755(1) 19(1)
Cu(2) 11399(1) 10664(1) 9741(1) 18(1)
N(11) 12832(4) 9368(4) 10542(3) 19(1)
C(10) 13171(5) 8004(4) 10555(4) 23(1)
C(11) 14239(5) 7187(5) 11081(4) 25(1)
C(12) 14965(6) 7795(5) 11644(4) 27(1)
C(13) 14618(6) 9196(5) 11653(4) 25(1)
C(14) 13555(5) 9955(4) 11084(3) 19(1)
C(15) 13101(5) 11450(4) 11025(3) 20(1)
C(16) 13712(6) 12259(5) 11527(4) 25(1)
C(17) 13179(6) 13648(5) 11423(4) 26(1)
C(18) 12064(6) 14210(5) 10863(4) 24(1)
C(19) 11511(5) 13356(4) 10381(4) 23(1)
O(2)-Cu(1)-Cl(1) 99.60(13)
O(1)-Cu(1)-Cl(1) 99.16(13)
N(21)-Cu(1)-Cl(1) 94.71(15)
N(22)-Cu(1)-Cl(1) 103.48(16)
O(2)-Cu(2)-O(1) 81.20(18)
O(2)-Cu(2)-N(12) 97.99(19)
O(1)-Cu(2)-N(12) 177.24(14)
O(2)-Cu(2)-N(11) 166.11(14)
O(1)-Cu(2)-N(11) 99.09(18)
N(12)-Cu(2)-N(11) 81.1(2)
O(2)-Cu(2)-O(1)#1 99.68(17)
O(1)-Cu(2)-O(1)#1 85.53(16)
N(12)-Cu(2)-O(1)#1 97.21(17)
N(11)-Cu(2)-O(1)#1 94.18(18)

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N(12) 12024(4) 12003(4) 10455(3) 19(1)
N(21) 9837(4) 9228(4) 6983(3) 19(1)
C(20) 10307(5) 7877(4) 7055(4) 22(1)
C(21) 9823(6) 7034(5) 6502(4) 25(1)
C(22) 8819(6) 7623(5) 5850(4) 26(1)
C(23) 8326(6) 9028(5) 5759(4) 24(1)
C(24) 8865(5) 9800(4) 6334(3) 21(1)
C(25) 8446(5) 11293(4) 6279(3) 20(1)
C(26) 7418(6) 12071(5) 5698(4) 27(1)
C(27) 7101(6) 13476(5) 5707(4) 28(1)
C(28) 7815(6) 14049(5) 6291(4) 27(1)
C(29) 8828(6) 13218(5) 6866(4) 24(1)
N(22) 9131(4) 11863(4) 6866(3) 20(1)
O(1) 10868(4) 9349(3) 8978(2) 19(1)
O(2) 10491(4) 11874(3) 8712(2) 21(1)
Cl(1) 13245(1) 10068(1) 6588(1) 28(1)
Cl(2) 13053(1) 16094(1) 8498(1) 27(1)
O(3) 11533(4) 14112(3) 7700(3) 28(1)
O(4) 15168(5) 13076(4) 3749(3) 42(1)
O(5) 13274(5) 13048(4) 5774(3) 43(1)
Table 4. Hydrogen bonds for complex 1 [Å and °].
D-H...A d(D-H) d(H...A) d(D...A) <(DHA)
O(1)-H(1)...Cl(2)#2 0.809(19) 2.55(2) 3.341(6) 166(5)
O(2)-H(2)...O(3) 0.81(2) 2.04(3) 2.820(6) 162(5)
O(3)-H(3A)...O(5) 0.836(19) 1.86(2) 2.674(6) 164(5)
O(3)-H(3B)...Cl(2) 0.831(19) 2.28(2) 3.094(5) 168(5)
O(4)-H(4A)...Cl(2)#3 0.832(19) 2.35(4) 3.108(6) 152(6)
O(4)-H(4B)...Cl(1)#4 0.829(19) 2.29(2) 3.117(7) 174(5)
O(5)-H(5A)...O(4) 0.817(19) 1.97(3) 2.723(7) 153(5)
O(5)-H(5B)...Cl(1) 0.841(19) 2.32(2) 3.142(7) 167(5)
Symmetry transformations used to generate equivalent atoms:
#1 -x+2,-y+2,-z+2 #2 x,y-1,z #3 -x+3,-y+3,-z+1 #4 -x+3,-y+2,-z+1

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░ 4. CONCLUSION
Two very important hydroxo-bridged stepped-cubane copper(II) complexes viz: [Cu4(bpy)4Cl2(OH)4]Cl2.6H2O (1)
and [Cu4(phen)4Cl2(OH)4]Cl2.6H2O (2) have been successfuly synthesized and obtained in excellent yield.
Detailed UV-Vis, FT-IR and electrospray ionization mass spectroscopic data of the complexes in addition to X-ray
crystallographic data of 1 which provides sufficient evidence for the formation of the complexes. The one-pot
synthetic method is simple, reproducible and more convenient producing the complexes in high yield compared to
previously reported methods.
Acknowledgments
Olufunso Abosede appreciates DBT-TWAS for Postgraduate Fellowship (FR number: 3240240274) to Savitribai
Phule Pune University. The authors thank Prof. Vickee Mckee for collecting the crystal data.
Declarations
Source of Funding
This research is funded by DBT-TWAS Postgraduate Fellowship (FR number: 3240240274) at Savitribai Phule
Pune University.
Competing Interests Statement
The authors declare no competing financial, professional, or personal interests.
Consent for publication
The authors declare that they consented to the publication of this research work.
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ZAAC907%3E3.0.CO;2-K.

ISSN: 2456-883X
31
░ Cite this article
Olufunso O. Abosede & Joshua A. Obaleye. New One-Pot Synthetic Route and Spectroscopic
Characterization of Hydroxo-Bridged Stepped-Cubane Copper(II) Complexes. Asian Journal of Applied
Science and Technology 6(4), 21–31 (2022).
░ Publisher’s Note
Nemeth Publishers remain neutral with regard to jurisdictional claims in the published maps and
institutional affiliations.

New One-Pot Synthetic Route and Spectroscopic Characterization of Hydroxo-Bridged Stepped-Cubane Copper(II) Complexes

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