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Investigating the effect of anion substitutions on the structure of silver-based coordination polymers
Accepted Manuscript Investigating the effect of anion substitutions on the structure of silver-based coordination polymers Azizolla Beheshti, Hamid Reza Zafarian, Carmel T. Abrahams, Giuseppe Bruno, Hadi Amiri Rudbari PII: DOI: Reference:
S0020-1693(15)00444-2 http://dx.doi.org/10.1016/j.ica.2015.09.006 ICA 16681
To appear in:
Inorganica Chimica Acta
Received Date: Revised Date: Accepted Date:
17 December 2014 5 September 2015 7 September 2015
Please cite this article as: A. Beheshti, H.R. Zafarian, C.T. Abrahams, G. Bruno, H.A. Rudbari, Investigating the effect of anion substitutions on the structure of silver-based coordination polymers, Inorganica Chimica Acta (2015), doi: http://dx.doi.org/10.1016/j.ica.2015.09.006
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1
Investigating the effect of anion substitutions on the structure of silver-based coordination polymers
1 2
Azizolla Beheshtia, Hamid Reza Zafariana, Carmel T. Abrahamsb, Giuseppe Brunoc and Hadi Amiri Rudbarid
3 4 5
a
6
Ahvaz, Iran b Department of Chemistry, Latrobe University, Bundoora 3086, Victoria,
7
Australiac Dipartimento di Chimica Inorganica, Vill. S. Agata, Salita Sperone 31,
8
Università di Messina, 98166 Messina, Italy
Department of Chemistry, Faculty of Sciences, Shahid Chamran University of Ahvaz,
d
9 10 11
Faculty of Chemistry, University of Isfahan, Isfahan 81746-73441, Iran.
*
E-mail: [email protected].: +98 611 33331042; Fax: +98 611 33331042
12 13
Abstract
14
Five silver(I) compounds namely, [Ag(tdmpp)(NO3)]n (1), [Ag2(SeCN)2(tdmpp)]n (2),
15
[Ag(tdmpp)]PF6
16
[WS4Ag4I2(tdmpp)]1.5CH3CN (5) were prepared by the reactions of 1,1,3,3-tetrakis(3,5-
17
dimethyl-1-pyrazolyl)propane (tdmpp) with various silver(I) salts in order to investigate the
18
impact of the variation of the inorganic anions on the structure of these complexes. In the
19
chain structures of 1 and 2, each tdmpp ligand acts as a bridge between a pair of adjacent
20
silver(I) centers. In the structure of 1, the nitrate ion act as a terminal, monodentate ligand,
21
while in compound 2 the SeCN anion functions as bidentate-bridging ligand between two
22
neighboring Ag(I) centers. The parallel adjacent chains in 1 and 2 are linked together by
23
means of non-covalent interactions to generate two-dimensional structures. In contrast to
24
the distorted AgN4O square–pyramidal structure of 1, in the structure of 2 each of the silver
25
ions possesses a distorted tetrahedral with an AgN3Se coordination geometry. Crystals of
26
compounds 3-5 were not suitable for X-ray diffraction studies.
(3),
[WS4Ag3Cl
(tdmpp)1.5].2CH3CN
(4)
and
27 Silver
coordination
polymers;
Tetradentate
28
Keywords:
29
Heterothiometallic cluster compounds; Chelating ligands.
30 31
1. Introduction
pyrazolyl-based
ligands;
2 32
The rational design and synthesis of silver (I) coordination polymers have been widely
33
studied. This study was motivated not only by the possibility of their application as
34
functional materials i.e. fluorescent materials, but also by the prospect of obtaining
35
fascinating structures that can be accessed by the variable coordination numbers from 2 to 6
36
and different conformations adopted by the silver ions [1-19]. The study of the coordination
37
chemistry with the pyrazole-based ligands began in 1889 with a report of the polymeric
38
[Ag(pz)]n complex [20]. Much later, Trofimenko et al. stimulated further research with the
39
introduction of poly(pyrazol-1-yl)borate chelating ligands in coordination chemistry [21-
40
24]. Following the discovery that chelating poly(pyrazol-1-yl)borate ligands formed strong
41
interactions with metal centres, the coordination chemistry of these ligands became the
42
focus of considerable attention [25-27]. These ligands may be used as synthetic analogs of
43
imidazole and mimic the coordinating sites found in metal enzymes or metalloproteins [28].
44
Unlike monodentate pyrazole and the rigid poly(pyrazol-1-yl)borate chelating ligands [29-
45
32], flexible pyrazole-based ligands, offer the prospect of conformtaions that will lead to
46
variation in coordination geometries, influenced by the spacer length and the orientations of
47
the donor atoms of the organic bridging ligands. The flexibility of these ligands can lead to
48
the generation of structures with interesting properties. Architectures with specific
49
structural motifs can be achieved by careful selection of organic ligands with the suitable
50
coordinating groups, metal centers with preferred coordination geometries and variation of
51
reaction conditions [33-36]. As a part of our research devoted to the synthesis, structural
52
and spectroscopic characterization of the coordination chemistry of pyrazole ligands, here
53
we report the synthesis and structural characterization of five new silver (I) coordination
54
polymers formed by the reaction of tdmpp ligand (Scheme 1) with appropriate silver(I)
55
salts. It is anticipated that this investigation will provide insights into the effect of different
56
inorganic anions on the structures of the silver(I) coordination polymers.
57
N N
N N
N N
N N
58 59
Scheme 1: Structure of the tdmpp ligand used in this work.
60 61
2. Experimental
3 62
2.1. Materials and physical measurements
63
All synthetic procedures were performed without precautions to exclude air. Starting
64
materials were purchased from commercial sources and used without further purification.
65
The tdmpp [36] and (NH4)2WS4 [37] were prepared from them by published methods. The
66
infrared spectra (4000–400 cm-1) were recorded on KBr disks with an FT-IR model
67
BOMEN MB102 spectrometer. The UV-Vis. spectra (700–270 nm) of [WS4]2- anion and
68
complexes 4 and 5 were recorded on a GBC Cintral 101 spectrophotometer from freshly
69
made samples in acetonitrile solution. X-ray powder diffraction patterns were recorded on a
70
Philips X’PertPro diffractometer (Cu Kα radiation, λ = 1.54184 Å) in the 2θ range 5-50°.
71
The elemental analyses for C, H and N were performed on a Costech-ECS 4010 CHNSO
72
analyzer.
73 74
2.2.Preparation of coordination polymers
75
2.2.1.Synthesis of [Ag(tdmpp)(NO3)] n (1)
76
A mixture of AgNO3 (0.190 g, 1 mmol) and tdmpp (0.420 g, 1 mmol) in acetonitrile (20
77
mL) was stirred at room temperature for 2 h. The precipitate was centrifuged and filtered
78
off. The residue was washed with ethanol (2×2 mL) and diethyl ether (2×3 mL) and dried
79
in vacuum to give a white powder of the product (439 mg, yield: 74% based on Ag).
80
Colorless needle-shaped single crystals suitable for X-ray diffraction studies were obtained
81
after 2 days by diffusion of diethyl ether into an acetonitrile solution of 1. Anal. Calc. for
82
AgC23 H32N9O3: C, 46.8; H, 5.5; N, 21.3. Found: C, 46.3; H, 5.1; N, 21.1%. IR (KBr,cm-1 ):
83
3126 (m) and 2918 (m) (-CH2- of spacer), 1635 (m), 1559 (s) (C=N of tdmpp), 1450(m),
84
1415 (m) and 1320 (s) (ʋ3 of NO3), 1030 (m), 781 (m), 572 (m).
85 86
2.2.2. Synthesis of [Ag2(SeCN)2(tdmpp)]n (2)
87
KSeCN (0.228 g, 2 mmol) and AgNO3 (0.340 g, 2 mmol) were added to DMSO (20 mL)
88
and the mixture was stirred and heated under reflux conditions at 80 ºC for 1h. To this
89
solution, tdmpp (0.420 g, 1 mmol) was added and the mixture was stirred for another 4 h.
90
The reaction mixture was filtered and colorless supernatant was decanted off. The
91
precipitate was washed with ethanol (2×2 mL) and diethyl ether (2×3 mL) and dried in
92
vacuo to give the required product as a white powder (526 mg, yield: 70% based on Ag).
93
Colorless hexagonal-shaped single crystals suitable for X-ray crystallography were
94
obtained by slow evaporation of the filtrate after 5 days. Anal. Calc. for Ag2C25 H32N10Se2:
4 95
C, 35.5; H, 3.8; N, 16.6. Found: C, 35.3; H, 3.3; N, 16.7%. IR (KBr,cm-1): 3124 (m) and
96
2917 (m) (-CH2- of spacer), 2100 (s) ( CN of SeCN), 1636 (m), 1558 (s)(C=N of tdmpp),
97
1460(s), 1417 (s), 1387 (m), 1316 (m), 1300 (m), 1032 (s), 789 (s), 680 (m), 565 (m).
98 99
2.2.4. Preparation of[Ag (tdmpp)]PF6 (3)
100
NH4PF6 (0.163 g, 1 mmol) and AgNO3 (0.170 g, 1 mmol) were added to an acetonitrile
101
solution (20 mL) and the mixture was stirred at room temperature for 30 min. To this
102
solution, tdmpp (0.420 g, 1 mmol) was added and the mixture was stirred for another 4 h.
103
The reaction mixture was filtered off and the colorless supernatant was decanted. The
104
precipitate was washed with ethanol (2×2 mL) and diethyl ether (2×3 mL) and dried in
105
vacuo to give the required product as a white powder(437 mg,yield:65% based on
106
Ag).Anal. Calc. for AgC23H32N8PF6: C, 41.0; H, 4.7; N, 16.6. Found: C, 40.8; H, 4.0; N,
107
17.3%. IR data (cm-1): 3129 (m) and 2918 (m) (-CH2- of spacer), 1558 (s) (C=N of tdmpp),
108
1458 (s), 1420 (s), 1387 (m), 1319 (m), 1297 (m), 1034 (s), 843(vs) (P-F of PF6), 791 (s),
109
680 (m), 557(s) (P-F of PF6).
110 111
2.2.5. Preparation of [WS4Ag3Cl (tdmpp)1.5].2CH3CN (4)
112
(NH4)2WS4 (0.348 g, 1 mmol) and AgCl (0.429 g, 3 mmol) were added to anacetonitrile
113
solution (30 mL). After stirring for 30 min at room temperature, tdmpp (0.630 g, 1.5 mmol)
114
was added to this solution. The mixture was stirred for another 3 h and then filtered. The
115
yellow precipitate was washed with ethanol (2×2 mL) and diethyl ether (2×3 mL) and
116
dried in vacuo to give the required product as a yellow-orang powder (595 mg, yield: 43%
117
based on W). Anal. Calc. for Ag6C77H108N28Cl2W2S8: C, 33.4; H, 3.9; N, 14.2. Found: C,
118
32.8; H, 3.3; N, 14.5%. IR data (cm-1): 3132(m) and 2918 (m) (-CH2-of spacer), 2253 (m)
119
(CN of acetonitrile), 1559(s) (C=N of tdmpp), 1460 (s), 1377 (m), 1319 (m), 1278 (m),
120
1034 (s), 448 (s) (W-µ 2-S), 439 (s) (W-µ 3-S).
121 122
2.2.6. Preparation of [WS4Ag4I2 (tdmpp)] 1.5CH3CN (5)
123
(NH4)2WS4 (0.348 g, 1 mmol) and AgI (0.936 g, 4 mmol) were added to an acetonitrile
124
solution (30 mL). After stirring at room temperature for 30 min, tdmpp (0.420 g, 1 mmol)
125
was added to this solution. The mixture was stirred for another 3 h and filtered. The yellow
126
precipitate was washed with ethanol (2×2 mL) and diethyl ether (2×3 mL) and dried in
127
vacuo to give the required product as a yellow powder (562 mg, yield: 38% based on W).
128
Anal. Calc. for Ag8C52H73N19I4W2S8: C, 21.1; H, 2.5; N, 9.0. Found: C, 21.3; H, 2.4; N,
5 129
8.5%. IR data (cm-1): 3127(m) and 2920 (m) (-CH2-of spacer), 2250 (m) (CN of
130
acetonitrile), 1559(s) (C=N of tdmpp) , 1460 (s), 1377 (m), 1320 (m), 1281 (m), 1038 (s),
131
439 (s) (W-µ 3-S).
132 133
2.3. X-ray crystallography
134
The crystallographic data for compounds 1 and 2 were collected at room temperature with
135
a Bruker APEX II CCD area-detector diffractometer using MoKα radiation (λ=
136
0.71073Å). Data collection, cell refinement, data reduction and absorption correction were
137
performed using multi scan methods with BRUKER software [38]. The structures were
138
solved by direct methods using SIR2004 [39]. The non-hydrogen atoms were refined
139
anisotropically by the full matrix least squares method on F2 using SHELXL [40]. All the
140
hydrogen (H) atoms were placed at the calculated positions and constrained to ride on their
141
parent atoms. Details concerning collection and analysis are reported in Table 1.
142 143
3. Results and discussion
144
3.1. Synthesis and spectroscopic characterization
145
The title compounds were prepared by the reactions of 1 to 5 in DMSO for 2 and in
146
acetonitrile for the rest of compounds.
147
AgNO3 + tdmpp → [Ag(tdmpp)(NO3)]n
(1)
148
2KSeCN + 2AgNO3 + tdmpp → [Ag2(SeCN)2(tdmpp)]n+ 2KNO3
(2)
149
NH4PF6+ AgNO3 +tdmmp→ [Ag(tdmpp)]PF6+ NH4NO3
(3)
150
2[NH4]2WS4 + 6AgCl + 3tdmpp → 2[WS4Ag3Cl(tdmpp)1.5].2CH3CN + 4NH4Cl
(4)
151
[NH4]2WS4 + 4AgI + tdmpp→ [WS4Ag4I2(tdmpp)]1.5CH3CN + 2NH4I
(5)
152 153
All the synthesized compounds are relatively stable and can be stored in a desiccator for
154
two months. These compounds were identified by IR spectroscopy, elemental analysis and
155
X-ray powder diffraction. Structures of compounds 1 and 2 were determined by X-ray
156
crystallography. The electronic absorption spectra of compounds 4 and 5 were also
157
recorded in acetonitrile solution. Crystals of compounds 3-5 were not suitable for X-ray
158
diffraction studies and therefore their structures could only be investigated in solid state by
159
infrared spectroscopy and elemental analysis.
160
IR spectra of all complexes show medium bands in the range of 2916-3132 cm-1 assigned to
161
the symmetric and asymmetric stretching vibrations of the methylene (-CH2-) groups of the
6 162
linker ligand and a strong band corresponding to the stretching vibration of the C=N bonds
163
of the pyrazole rings of the tdmpp ligands at 1558 or 1559 cm-1. This band is shifted to
164
lower frequency with respect to the spectrum of the uncoordinated 3,5-dimethyl-1-pyrazole
165
ligand (1595 cm-1) [41]. The IR spectrum of 1 exhibits two absorption bands with medium
166
intensity at 1415 cm-1 and strong broad band at 1320 cm-1, characteristic of monodentate
167
coordination of nitrate ion to the Ag(I) cation. The infrared spectrum of 2 shows an intense
168
absorption bands at 2100 cm-1 assigned to the CN stretching vibration of the N-coordinated
169
selenocyanate ligand. This band appears at a higher frequency relative to KSeCN (2070 cm-
170
1
) [42]. Two sharp bands at 843 and 557cm-1 in the infrared spectrum of 3 are attributed to
171
the vibration bands of PF6- counter anion. The infrared spectra of 4 and 5 display typical
172
absorption bands for the W–S stretching vibrations of the WS4 moiety in the range of 400–
173
500 cm-1 [43]. Consequently, the absorption bands in the spectrum of 4 at 448 and 438 cm-1
174
are assignable to the bridging W-µ 2-S and W-µ 3-S stretching vibrations, respectively [44].
175
These bands are shifted to lower frequencies relative to that of the parent [WS4]2- anion
176
(463 cm-1). This indicates that the [WS4]2- metalloligand is coordinated to the soft Ag(I)
177
centre through the sulfur atoms. In contrast to 4, in the spectrum of 5 only one band is
178
observed at 439 cm-1 for the W-µ 3-S bonds, showing that the coordination of silver(I) to the
179
[WS4]2- does not lower the effective symmetry of this anion. The electronic absorption
180
spectra of compounds 4 and 5 in acetonitrile solution are relatively simple and are
181
dominated by the internal transitions of the [WS4]2- ion. The main band at 445 nm in the
182
spectrum of 4 and 455 nm in the spectrum of 5 is assigned to the S(π)→W(d) charge
183
transfer transitions. This bands are red shifted with respect to the corresponding transitions
184
observed for the [WS4]2- (394 nm) anion. In order to confirm the phase purity of the
185
synthesized polymers, X-ray powder diffraction (XRPD) experiments were carried out for
186
compounds 1-5. In the case of polymer 1 (Fig. 1) and polymer 2 (Fig. 2) the experimental
187
spectra were consistent with their simulated spectra. The XRPD spectra of compounds 3-5
188
were shown in the supplementary materials (S1-S3). Experimental and calculated data were
189
extracted by Xpert and Mercury softwares, respectively.
190 191
3.2. Structural Characterization
192
3.2.1. Crystal structure of 1
193
The asymmetric unit of 1 consists of one Ag, one NO3- anion and one tdmpp ligand which
194
has the central atom of the propylene bridge located on a 2-fold axis (Fig.3). The Ag(I) ion
195
is in a five coordinate N4O coordination environment with a highly distorted, square-
7 196
pyramidal geometry (τ= 0.32) based on the Addison analysis where τ= 0.00 describes a
197
perfect square pyramid and τ= 1.00 a trigonal bipyramidal [45]. Each tdmpp ligand bridges
198
a pair of crystallographically related Ag(I) centers to generate a zigzag-chain structure
199
running along the b-axis. These chains are inter-connected by C-H...O hydrogen bonds with
200
H…O distance of 2.71 Å to form a two-dimensional structure in the ab-plane (Fig. 4). In
201
this structure, each Ag(I) cation is chelated by two bis(3,5-dimethylpyrazolyl)methane units
202
of two distinct tdmpp ligands with an average bite angle of 81.50º to form a six-membered
203
metallocyclic
204
dimethylpyrazolyl)methane units. In the equatorial plane, the smallest angle is the bite
205
angle, N2-Ag-N3, and the largest angle is the N3-Ag-N4 angle (Table 2). The Ag—N bond
206
lengths lie within the range of 2.393(2)- 2.464(2) Å with the Ag1—N2 and Ag1—N4 bond
207
distances slightly shorter than the Ag1—N1 and Ag1—N3 values (Table 2). These
208
distances are comparable with those found in [Ag(NO3)(C10H6N4)2] [C10H6N4= 5-(pyridin-
209
2-yl)pyrazine-2-carbonitrile] [2.301(2)- 2.579(3) Å] [46]. The nitrate ion binds to the silver
210
atom as a monodentate, terminal ligand with the Ag1—O2 distance of 2.615(8) Å. This
211
bond is longer than the Ag1—O1 = 2.547(3) Å bond reported for the [Ag(NO3)(C10H6N4)2]
212
with a distorted AgN4O square-pyramidal structure, but is consistent with other examples
213
reported in the literature [47]. In compound 1 a second O atom of the nitrate interacts with
214
the Ag(I) with the long, but significant Ag1—O1 distance of 2.784 Å.
ring
with
a
boat
conformation
for
each
of
the
bis(3,5-
215 216
3.2.2. Crystal structure of 2
217
The X-ray single-crystal structural analysis of the neutral polymeric structure of
218
[Ag2(SeCN)2 (tdmpp)]n (2) reveals that the compound crystallizes in the monoclinic space
219
group C2/c with Z = 4 (Table 1). The asymmetric unit of 2 consists of a half-molecule of
220
the [Ag2(SeCN)2(tdmmp)], the other half being generated by an inversion center lying at
221
the mid-point of between two adjacent silver atoms (Fig.5). Here, the tdmpp ligand acts as
222
a two-connector to link a pair of crystallographically equivalent silver (I) ions with an
223
Ag...Ag separation of 7.00 Å by its two arms. In the polymeric structure of 2, each of the
224
silver atoms adopts a distorted AgN3Se tetrahedral coordination geometry, coordinated by
225
two N atoms from one bis(3,5-dimethylpyrazol-1-yl)methane unit of a tdmpp ligand with
226
an average Ag-N distance of 2.351Å, one selenium atom with Ag-/Se distance of 2.5571 Å
227
and one
228
centrosymmetrically related selenocyanate anions that act as a double bridge between the
nitrogen with Ag-N distance of 2.336 Å belonging to a pair of
8 229
two adjacent Ag(I) centers. The bond angles around the silver atom are in the range of
230
80.11 to 127.9° (Table 2). The smallest angle is associated with the N2-Ag1-N4 angle of a
231
six-membered metallocycle made by four nitrogens, one silver and one carbon atom. These
232
metallocycles adopt a boat conformation with the silver and carbon atoms off the plane
233
defined by the four imine nitrogen atoms. The largest angle within the AgN3Se core occurs
234
within the N4-Ag1-Se1 angle and this is likely to be due to the large steric hindrance of the
235
pyrazole rings .Two silver and two distinguished µ 2-NCSe with a classical µ-N,Se
236
coordination mode form a building unit which is a centrosymmetric, nearly planar eight-
237
membered macrocycle (AgSeCN)2 similar to the chair conformation of the cyclohexane
238
with the adjacent Ag…Ag separation of 5.714Å. Complex 2 exhibits a one-dimensional
239
(1D) sinusoidal-like chain extending along the a-axis with Ag(I) centers linked alternately
240
by the organic tdmpp ligands and inorganic (AgSeCN)2 dimers. The parallel adjacent
241
chains are linked together by means of non-covalent C-H···π (arene), C-H···Se and C-
242
H···N interactions (Fig.4a) with H···π, H···Se and H···N distances of 2.937, 2.971 and
243
2.747Å (Fig.6a), respectively to generate a two-dimensional structure (Fig.6b).
244
4. Conclusion
245
In compounds 1 and 2 the crystallographic results clearly indicate that the tdmpp ligand
246
exhibits a strong tendency to chelate Ag(I) and promote coordination numbers that are
247
higher than the linear two-coordinate complexes commonly seen when simple
248
monodentate amines bind to Ag(I). In the case of 1 it is interesting to note that the nitrate
249
anion is able to coordinate to the Ag centre (although rather weakly) despite the fact that
250
the Ag centre is already coordinated by a pair of chelating ligands each with relatively
251
large bite angles. In the case of 2 the more strongly coordinating selenocyanate binds
252
through both sulphur and nitrogen atoms to generate a linear polymer. In compound 3, the
253
PF6- serves as the counter-ion. In complexes 4 and 5, the [WS4]2- acts as a co-ligand, and
254
coordinates to three and four Ag(I) atoms, respectively through the sulfur atoms.
255 256
Acknowledgement
257
We thank Shahid Chamran University of Ahvaz for the financial support (grant number:
258
854532).
259
9 260
Appendix A. Supplementary material
261
CCDC reference numbers 1035600-1 contains the supplementary crystallographic data for
262
the structures 1 and 2, respectively. Crystallographic data can be obtained free of charge
263
from
264
http://www.ccdc.cam.ac.uk/datarequest/cif. Or from the Cambridge Crystallographic Data
265
Centre, 12 Union Road, Cambridge CB2 1EZ, UK; fax: (+44) 1223-336-033; or e-mail:
266
[email protected]. Supplementary material associated with this article can be
267
found, in the online version, at http://dx.doi.org/10.1016/j.molstruc.2014.11.008.
268
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11 324 325
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326
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327
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328 329 330
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331
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332
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337
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338
Figure captions
339
Fig. 1. Observed (blue) and calculated (red) X-ray powder diffraction spectrum of
340
compound 1.
341
Fig. 2. Observed (brown) and calculated (violet) X-ray powder diffraction spectrum of
342
compound 2.
343
Fig. 3. An ORTEP view of 1, showing the atomic numbering scheme. H atoms are omitted
344
for clarity.
345
Fig. 4.View of 2D structure of 1 formed by the non-classic C-H···O hydrogen bonds.
346
Fig. 5. An ORTEP view of 2, showing the atomic numbering scheme. H atoms are omitted
347
for clarity.
348
Fig. 6. 2-D structure of 2 formed by the non-classic C-H···π (arene), C-H···N and C-H···Se
349
interactions. All interaction are shown by dashed lines.
350 compound
Table 1. Crystal data for compounds 1 and 2. 1 2
Chemical formula
AgC23H32N9O3
Ag2C25 H32N10Se2
12 Crystal system
monoclinic
monoclinic
Space group
P 21/n
C 2/c
a (Å)
9.8422(5)
22.4987(10)
b (Å)
13.7187(6)
7.9464(2)
c (Å)
19.3258(9)
20.5755(8)
α (°)
90.00
90.00
β(°)
96.488(2)
126.699(8)
γ(°)
90.00
90.00
z
4
4
2.89
2.37
2592.7
2950.57
R-factor (%) 3
V (Å ) 351 352
Table 2. Selected bond distances (Å) and angles (º) for compounds 1 and 2. Compound 1 Ag1- N2
2.406(2)
N1- C4
1.331(3)
Ag1- O2
2.615(8)
N1- N5
1.365(2)
Ag1- N3
2.436(2)
N8- C19
1.363(3)
Ag1- N1
2.464(2)
N8- C21
1.455(3)
Ag1 -N4
2.393(2)
O2- N9
1.233(7)
N2-Ag1-O2
87.1(2)
N2-Ag1-N3
82.40(6)
N2-Ag1-N1
99.43(6)
N2-Ag1-N4
170.43(6)
O2-Ag1-N1
112.3(2)
N3-Ag1-N1
96.05(6)
O2-Ag1-N3
151.1(2)
O2-Ag1-N4
84.1(2)
N4-Ag1-N3
107.14(6)
13 Compound 2
353 354 355
N2- Ag1
2.366(2)
N1- N2
1.371(3)
Ag1- N4
2.382(2)
Se1- C13
1.822(3)
Ag1- N5
2.336(3)
C11- C12
1.526(4)
Se1- Ag1
2.5571(4)
H12A- C12
0.990(2)
C13- Se1
1.822(3)
C13 -N5
1.145(4)
Se1-Ag1-N4
124.19(6)
N4-Ag1-N2
80.11(8)
N4-Ag1-N5
106.54(8)
N2-Ag1-N5
111.44(8)
Se1-Ag1-N2
124.19(6)
Se1-Ag1-N5
104.62(6)
14
356 357 358 359 360
Fig. 1
15
361 362 363 364 365
Fig. 2
16
366 367 368 369
Fig. 3
17
370 371 372 373 374
Fig. 4
18
375 376 377 378 379
Fig. 5
19
380 381
a
382 383
b
384 385 386 387
Fig. 6
20 388
389 390 391 392 393
Graphical abstract
21 394 395
Five silver – based complexes
396
structurally characterized.
397
Non-classical interactions play a major role in determining the final structure of these
398
compounds.
399 400 401 402 403 404
Graphical Abstract with pyrazole based ligand were synthesized and
22 405
Highlights
406
Non- covalent interactions CH…π and CH…O lead to formation of 2D structures.
407
Nitrate anion acting as a monodentate terminal ligand.
408 409 410 411
The W-S bands shifted to lower frequencies in WS4 complexes with the silver(I) ion.
S0020-1693(15)00444-2 http://dx.doi.org/10.1016/j.ica.2015.09.006 ICA 16681
To appear in:
Inorganica Chimica Acta
Received Date: Revised Date: Accepted Date:
17 December 2014 5 September 2015 7 September 2015
Please cite this article as: A. Beheshti, H.R. Zafarian, C.T. Abrahams, G. Bruno, H.A. Rudbari, Investigating the effect of anion substitutions on the structure of silver-based coordination polymers, Inorganica Chimica Acta (2015), doi: http://dx.doi.org/10.1016/j.ica.2015.09.006
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1
Investigating the effect of anion substitutions on the structure of silver-based coordination polymers
1 2
Azizolla Beheshtia, Hamid Reza Zafariana, Carmel T. Abrahamsb, Giuseppe Brunoc and Hadi Amiri Rudbarid
3 4 5
a
6
Ahvaz, Iran b Department of Chemistry, Latrobe University, Bundoora 3086, Victoria,
7
Australiac Dipartimento di Chimica Inorganica, Vill. S. Agata, Salita Sperone 31,
8
Università di Messina, 98166 Messina, Italy
Department of Chemistry, Faculty of Sciences, Shahid Chamran University of Ahvaz,
d
9 10 11
Faculty of Chemistry, University of Isfahan, Isfahan 81746-73441, Iran.
*
E-mail: [email protected].: +98 611 33331042; Fax: +98 611 33331042
12 13
Abstract
14
Five silver(I) compounds namely, [Ag(tdmpp)(NO3)]n (1), [Ag2(SeCN)2(tdmpp)]n (2),
15
[Ag(tdmpp)]PF6
16
[WS4Ag4I2(tdmpp)]1.5CH3CN (5) were prepared by the reactions of 1,1,3,3-tetrakis(3,5-
17
dimethyl-1-pyrazolyl)propane (tdmpp) with various silver(I) salts in order to investigate the
18
impact of the variation of the inorganic anions on the structure of these complexes. In the
19
chain structures of 1 and 2, each tdmpp ligand acts as a bridge between a pair of adjacent
20
silver(I) centers. In the structure of 1, the nitrate ion act as a terminal, monodentate ligand,
21
while in compound 2 the SeCN anion functions as bidentate-bridging ligand between two
22
neighboring Ag(I) centers. The parallel adjacent chains in 1 and 2 are linked together by
23
means of non-covalent interactions to generate two-dimensional structures. In contrast to
24
the distorted AgN4O square–pyramidal structure of 1, in the structure of 2 each of the silver
25
ions possesses a distorted tetrahedral with an AgN3Se coordination geometry. Crystals of
26
compounds 3-5 were not suitable for X-ray diffraction studies.
(3),
[WS4Ag3Cl
(tdmpp)1.5].2CH3CN
(4)
and
27 Silver
coordination
polymers;
Tetradentate
28
Keywords:
29
Heterothiometallic cluster compounds; Chelating ligands.
30 31
1. Introduction
pyrazolyl-based
ligands;
2 32
The rational design and synthesis of silver (I) coordination polymers have been widely
33
studied. This study was motivated not only by the possibility of their application as
34
functional materials i.e. fluorescent materials, but also by the prospect of obtaining
35
fascinating structures that can be accessed by the variable coordination numbers from 2 to 6
36
and different conformations adopted by the silver ions [1-19]. The study of the coordination
37
chemistry with the pyrazole-based ligands began in 1889 with a report of the polymeric
38
[Ag(pz)]n complex [20]. Much later, Trofimenko et al. stimulated further research with the
39
introduction of poly(pyrazol-1-yl)borate chelating ligands in coordination chemistry [21-
40
24]. Following the discovery that chelating poly(pyrazol-1-yl)borate ligands formed strong
41
interactions with metal centres, the coordination chemistry of these ligands became the
42
focus of considerable attention [25-27]. These ligands may be used as synthetic analogs of
43
imidazole and mimic the coordinating sites found in metal enzymes or metalloproteins [28].
44
Unlike monodentate pyrazole and the rigid poly(pyrazol-1-yl)borate chelating ligands [29-
45
32], flexible pyrazole-based ligands, offer the prospect of conformtaions that will lead to
46
variation in coordination geometries, influenced by the spacer length and the orientations of
47
the donor atoms of the organic bridging ligands. The flexibility of these ligands can lead to
48
the generation of structures with interesting properties. Architectures with specific
49
structural motifs can be achieved by careful selection of organic ligands with the suitable
50
coordinating groups, metal centers with preferred coordination geometries and variation of
51
reaction conditions [33-36]. As a part of our research devoted to the synthesis, structural
52
and spectroscopic characterization of the coordination chemistry of pyrazole ligands, here
53
we report the synthesis and structural characterization of five new silver (I) coordination
54
polymers formed by the reaction of tdmpp ligand (Scheme 1) with appropriate silver(I)
55
salts. It is anticipated that this investigation will provide insights into the effect of different
56
inorganic anions on the structures of the silver(I) coordination polymers.
57
N N
N N
N N
N N
58 59
Scheme 1: Structure of the tdmpp ligand used in this work.
60 61
2. Experimental
3 62
2.1. Materials and physical measurements
63
All synthetic procedures were performed without precautions to exclude air. Starting
64
materials were purchased from commercial sources and used without further purification.
65
The tdmpp [36] and (NH4)2WS4 [37] were prepared from them by published methods. The
66
infrared spectra (4000–400 cm-1) were recorded on KBr disks with an FT-IR model
67
BOMEN MB102 spectrometer. The UV-Vis. spectra (700–270 nm) of [WS4]2- anion and
68
complexes 4 and 5 were recorded on a GBC Cintral 101 spectrophotometer from freshly
69
made samples in acetonitrile solution. X-ray powder diffraction patterns were recorded on a
70
Philips X’PertPro diffractometer (Cu Kα radiation, λ = 1.54184 Å) in the 2θ range 5-50°.
71
The elemental analyses for C, H and N were performed on a Costech-ECS 4010 CHNSO
72
analyzer.
73 74
2.2.Preparation of coordination polymers
75
2.2.1.Synthesis of [Ag(tdmpp)(NO3)] n (1)
76
A mixture of AgNO3 (0.190 g, 1 mmol) and tdmpp (0.420 g, 1 mmol) in acetonitrile (20
77
mL) was stirred at room temperature for 2 h. The precipitate was centrifuged and filtered
78
off. The residue was washed with ethanol (2×2 mL) and diethyl ether (2×3 mL) and dried
79
in vacuum to give a white powder of the product (439 mg, yield: 74% based on Ag).
80
Colorless needle-shaped single crystals suitable for X-ray diffraction studies were obtained
81
after 2 days by diffusion of diethyl ether into an acetonitrile solution of 1. Anal. Calc. for
82
AgC23 H32N9O3: C, 46.8; H, 5.5; N, 21.3. Found: C, 46.3; H, 5.1; N, 21.1%. IR (KBr,cm-1 ):
83
3126 (m) and 2918 (m) (-CH2- of spacer), 1635 (m), 1559 (s) (C=N of tdmpp), 1450(m),
84
1415 (m) and 1320 (s) (ʋ3 of NO3), 1030 (m), 781 (m), 572 (m).
85 86
2.2.2. Synthesis of [Ag2(SeCN)2(tdmpp)]n (2)
87
KSeCN (0.228 g, 2 mmol) and AgNO3 (0.340 g, 2 mmol) were added to DMSO (20 mL)
88
and the mixture was stirred and heated under reflux conditions at 80 ºC for 1h. To this
89
solution, tdmpp (0.420 g, 1 mmol) was added and the mixture was stirred for another 4 h.
90
The reaction mixture was filtered and colorless supernatant was decanted off. The
91
precipitate was washed with ethanol (2×2 mL) and diethyl ether (2×3 mL) and dried in
92
vacuo to give the required product as a white powder (526 mg, yield: 70% based on Ag).
93
Colorless hexagonal-shaped single crystals suitable for X-ray crystallography were
94
obtained by slow evaporation of the filtrate after 5 days. Anal. Calc. for Ag2C25 H32N10Se2:
4 95
C, 35.5; H, 3.8; N, 16.6. Found: C, 35.3; H, 3.3; N, 16.7%. IR (KBr,cm-1): 3124 (m) and
96
2917 (m) (-CH2- of spacer), 2100 (s) ( CN of SeCN), 1636 (m), 1558 (s)(C=N of tdmpp),
97
1460(s), 1417 (s), 1387 (m), 1316 (m), 1300 (m), 1032 (s), 789 (s), 680 (m), 565 (m).
98 99
2.2.4. Preparation of[Ag (tdmpp)]PF6 (3)
100
NH4PF6 (0.163 g, 1 mmol) and AgNO3 (0.170 g, 1 mmol) were added to an acetonitrile
101
solution (20 mL) and the mixture was stirred at room temperature for 30 min. To this
102
solution, tdmpp (0.420 g, 1 mmol) was added and the mixture was stirred for another 4 h.
103
The reaction mixture was filtered off and the colorless supernatant was decanted. The
104
precipitate was washed with ethanol (2×2 mL) and diethyl ether (2×3 mL) and dried in
105
vacuo to give the required product as a white powder(437 mg,yield:65% based on
106
Ag).Anal. Calc. for AgC23H32N8PF6: C, 41.0; H, 4.7; N, 16.6. Found: C, 40.8; H, 4.0; N,
107
17.3%. IR data (cm-1): 3129 (m) and 2918 (m) (-CH2- of spacer), 1558 (s) (C=N of tdmpp),
108
1458 (s), 1420 (s), 1387 (m), 1319 (m), 1297 (m), 1034 (s), 843(vs) (P-F of PF6), 791 (s),
109
680 (m), 557(s) (P-F of PF6).
110 111
2.2.5. Preparation of [WS4Ag3Cl (tdmpp)1.5].2CH3CN (4)
112
(NH4)2WS4 (0.348 g, 1 mmol) and AgCl (0.429 g, 3 mmol) were added to anacetonitrile
113
solution (30 mL). After stirring for 30 min at room temperature, tdmpp (0.630 g, 1.5 mmol)
114
was added to this solution. The mixture was stirred for another 3 h and then filtered. The
115
yellow precipitate was washed with ethanol (2×2 mL) and diethyl ether (2×3 mL) and
116
dried in vacuo to give the required product as a yellow-orang powder (595 mg, yield: 43%
117
based on W). Anal. Calc. for Ag6C77H108N28Cl2W2S8: C, 33.4; H, 3.9; N, 14.2. Found: C,
118
32.8; H, 3.3; N, 14.5%. IR data (cm-1): 3132(m) and 2918 (m) (-CH2-of spacer), 2253 (m)
119
(CN of acetonitrile), 1559(s) (C=N of tdmpp), 1460 (s), 1377 (m), 1319 (m), 1278 (m),
120
1034 (s), 448 (s) (W-µ 2-S), 439 (s) (W-µ 3-S).
121 122
2.2.6. Preparation of [WS4Ag4I2 (tdmpp)] 1.5CH3CN (5)
123
(NH4)2WS4 (0.348 g, 1 mmol) and AgI (0.936 g, 4 mmol) were added to an acetonitrile
124
solution (30 mL). After stirring at room temperature for 30 min, tdmpp (0.420 g, 1 mmol)
125
was added to this solution. The mixture was stirred for another 3 h and filtered. The yellow
126
precipitate was washed with ethanol (2×2 mL) and diethyl ether (2×3 mL) and dried in
127
vacuo to give the required product as a yellow powder (562 mg, yield: 38% based on W).
128
Anal. Calc. for Ag8C52H73N19I4W2S8: C, 21.1; H, 2.5; N, 9.0. Found: C, 21.3; H, 2.4; N,
5 129
8.5%. IR data (cm-1): 3127(m) and 2920 (m) (-CH2-of spacer), 2250 (m) (CN of
130
acetonitrile), 1559(s) (C=N of tdmpp) , 1460 (s), 1377 (m), 1320 (m), 1281 (m), 1038 (s),
131
439 (s) (W-µ 3-S).
132 133
2.3. X-ray crystallography
134
The crystallographic data for compounds 1 and 2 were collected at room temperature with
135
a Bruker APEX II CCD area-detector diffractometer using MoKα radiation (λ=
136
0.71073Å). Data collection, cell refinement, data reduction and absorption correction were
137
performed using multi scan methods with BRUKER software [38]. The structures were
138
solved by direct methods using SIR2004 [39]. The non-hydrogen atoms were refined
139
anisotropically by the full matrix least squares method on F2 using SHELXL [40]. All the
140
hydrogen (H) atoms were placed at the calculated positions and constrained to ride on their
141
parent atoms. Details concerning collection and analysis are reported in Table 1.
142 143
3. Results and discussion
144
3.1. Synthesis and spectroscopic characterization
145
The title compounds were prepared by the reactions of 1 to 5 in DMSO for 2 and in
146
acetonitrile for the rest of compounds.
147
AgNO3 + tdmpp → [Ag(tdmpp)(NO3)]n
(1)
148
2KSeCN + 2AgNO3 + tdmpp → [Ag2(SeCN)2(tdmpp)]n+ 2KNO3
(2)
149
NH4PF6+ AgNO3 +tdmmp→ [Ag(tdmpp)]PF6+ NH4NO3
(3)
150
2[NH4]2WS4 + 6AgCl + 3tdmpp → 2[WS4Ag3Cl(tdmpp)1.5].2CH3CN + 4NH4Cl
(4)
151
[NH4]2WS4 + 4AgI + tdmpp→ [WS4Ag4I2(tdmpp)]1.5CH3CN + 2NH4I
(5)
152 153
All the synthesized compounds are relatively stable and can be stored in a desiccator for
154
two months. These compounds were identified by IR spectroscopy, elemental analysis and
155
X-ray powder diffraction. Structures of compounds 1 and 2 were determined by X-ray
156
crystallography. The electronic absorption spectra of compounds 4 and 5 were also
157
recorded in acetonitrile solution. Crystals of compounds 3-5 were not suitable for X-ray
158
diffraction studies and therefore their structures could only be investigated in solid state by
159
infrared spectroscopy and elemental analysis.
160
IR spectra of all complexes show medium bands in the range of 2916-3132 cm-1 assigned to
161
the symmetric and asymmetric stretching vibrations of the methylene (-CH2-) groups of the
6 162
linker ligand and a strong band corresponding to the stretching vibration of the C=N bonds
163
of the pyrazole rings of the tdmpp ligands at 1558 or 1559 cm-1. This band is shifted to
164
lower frequency with respect to the spectrum of the uncoordinated 3,5-dimethyl-1-pyrazole
165
ligand (1595 cm-1) [41]. The IR spectrum of 1 exhibits two absorption bands with medium
166
intensity at 1415 cm-1 and strong broad band at 1320 cm-1, characteristic of monodentate
167
coordination of nitrate ion to the Ag(I) cation. The infrared spectrum of 2 shows an intense
168
absorption bands at 2100 cm-1 assigned to the CN stretching vibration of the N-coordinated
169
selenocyanate ligand. This band appears at a higher frequency relative to KSeCN (2070 cm-
170
1
) [42]. Two sharp bands at 843 and 557cm-1 in the infrared spectrum of 3 are attributed to
171
the vibration bands of PF6- counter anion. The infrared spectra of 4 and 5 display typical
172
absorption bands for the W–S stretching vibrations of the WS4 moiety in the range of 400–
173
500 cm-1 [43]. Consequently, the absorption bands in the spectrum of 4 at 448 and 438 cm-1
174
are assignable to the bridging W-µ 2-S and W-µ 3-S stretching vibrations, respectively [44].
175
These bands are shifted to lower frequencies relative to that of the parent [WS4]2- anion
176
(463 cm-1). This indicates that the [WS4]2- metalloligand is coordinated to the soft Ag(I)
177
centre through the sulfur atoms. In contrast to 4, in the spectrum of 5 only one band is
178
observed at 439 cm-1 for the W-µ 3-S bonds, showing that the coordination of silver(I) to the
179
[WS4]2- does not lower the effective symmetry of this anion. The electronic absorption
180
spectra of compounds 4 and 5 in acetonitrile solution are relatively simple and are
181
dominated by the internal transitions of the [WS4]2- ion. The main band at 445 nm in the
182
spectrum of 4 and 455 nm in the spectrum of 5 is assigned to the S(π)→W(d) charge
183
transfer transitions. This bands are red shifted with respect to the corresponding transitions
184
observed for the [WS4]2- (394 nm) anion. In order to confirm the phase purity of the
185
synthesized polymers, X-ray powder diffraction (XRPD) experiments were carried out for
186
compounds 1-5. In the case of polymer 1 (Fig. 1) and polymer 2 (Fig. 2) the experimental
187
spectra were consistent with their simulated spectra. The XRPD spectra of compounds 3-5
188
were shown in the supplementary materials (S1-S3). Experimental and calculated data were
189
extracted by Xpert and Mercury softwares, respectively.
190 191
3.2. Structural Characterization
192
3.2.1. Crystal structure of 1
193
The asymmetric unit of 1 consists of one Ag, one NO3- anion and one tdmpp ligand which
194
has the central atom of the propylene bridge located on a 2-fold axis (Fig.3). The Ag(I) ion
195
is in a five coordinate N4O coordination environment with a highly distorted, square-
7 196
pyramidal geometry (τ= 0.32) based on the Addison analysis where τ= 0.00 describes a
197
perfect square pyramid and τ= 1.00 a trigonal bipyramidal [45]. Each tdmpp ligand bridges
198
a pair of crystallographically related Ag(I) centers to generate a zigzag-chain structure
199
running along the b-axis. These chains are inter-connected by C-H...O hydrogen bonds with
200
H…O distance of 2.71 Å to form a two-dimensional structure in the ab-plane (Fig. 4). In
201
this structure, each Ag(I) cation is chelated by two bis(3,5-dimethylpyrazolyl)methane units
202
of two distinct tdmpp ligands with an average bite angle of 81.50º to form a six-membered
203
metallocyclic
204
dimethylpyrazolyl)methane units. In the equatorial plane, the smallest angle is the bite
205
angle, N2-Ag-N3, and the largest angle is the N3-Ag-N4 angle (Table 2). The Ag—N bond
206
lengths lie within the range of 2.393(2)- 2.464(2) Å with the Ag1—N2 and Ag1—N4 bond
207
distances slightly shorter than the Ag1—N1 and Ag1—N3 values (Table 2). These
208
distances are comparable with those found in [Ag(NO3)(C10H6N4)2] [C10H6N4= 5-(pyridin-
209
2-yl)pyrazine-2-carbonitrile] [2.301(2)- 2.579(3) Å] [46]. The nitrate ion binds to the silver
210
atom as a monodentate, terminal ligand with the Ag1—O2 distance of 2.615(8) Å. This
211
bond is longer than the Ag1—O1 = 2.547(3) Å bond reported for the [Ag(NO3)(C10H6N4)2]
212
with a distorted AgN4O square-pyramidal structure, but is consistent with other examples
213
reported in the literature [47]. In compound 1 a second O atom of the nitrate interacts with
214
the Ag(I) with the long, but significant Ag1—O1 distance of 2.784 Å.
ring
with
a
boat
conformation
for
each
of
the
bis(3,5-
215 216
3.2.2. Crystal structure of 2
217
The X-ray single-crystal structural analysis of the neutral polymeric structure of
218
[Ag2(SeCN)2 (tdmpp)]n (2) reveals that the compound crystallizes in the monoclinic space
219
group C2/c with Z = 4 (Table 1). The asymmetric unit of 2 consists of a half-molecule of
220
the [Ag2(SeCN)2(tdmmp)], the other half being generated by an inversion center lying at
221
the mid-point of between two adjacent silver atoms (Fig.5). Here, the tdmpp ligand acts as
222
a two-connector to link a pair of crystallographically equivalent silver (I) ions with an
223
Ag...Ag separation of 7.00 Å by its two arms. In the polymeric structure of 2, each of the
224
silver atoms adopts a distorted AgN3Se tetrahedral coordination geometry, coordinated by
225
two N atoms from one bis(3,5-dimethylpyrazol-1-yl)methane unit of a tdmpp ligand with
226
an average Ag-N distance of 2.351Å, one selenium atom with Ag-/Se distance of 2.5571 Å
227
and one
228
centrosymmetrically related selenocyanate anions that act as a double bridge between the
nitrogen with Ag-N distance of 2.336 Å belonging to a pair of
8 229
two adjacent Ag(I) centers. The bond angles around the silver atom are in the range of
230
80.11 to 127.9° (Table 2). The smallest angle is associated with the N2-Ag1-N4 angle of a
231
six-membered metallocycle made by four nitrogens, one silver and one carbon atom. These
232
metallocycles adopt a boat conformation with the silver and carbon atoms off the plane
233
defined by the four imine nitrogen atoms. The largest angle within the AgN3Se core occurs
234
within the N4-Ag1-Se1 angle and this is likely to be due to the large steric hindrance of the
235
pyrazole rings .Two silver and two distinguished µ 2-NCSe with a classical µ-N,Se
236
coordination mode form a building unit which is a centrosymmetric, nearly planar eight-
237
membered macrocycle (AgSeCN)2 similar to the chair conformation of the cyclohexane
238
with the adjacent Ag…Ag separation of 5.714Å. Complex 2 exhibits a one-dimensional
239
(1D) sinusoidal-like chain extending along the a-axis with Ag(I) centers linked alternately
240
by the organic tdmpp ligands and inorganic (AgSeCN)2 dimers. The parallel adjacent
241
chains are linked together by means of non-covalent C-H···π (arene), C-H···Se and C-
242
H···N interactions (Fig.4a) with H···π, H···Se and H···N distances of 2.937, 2.971 and
243
2.747Å (Fig.6a), respectively to generate a two-dimensional structure (Fig.6b).
244
4. Conclusion
245
In compounds 1 and 2 the crystallographic results clearly indicate that the tdmpp ligand
246
exhibits a strong tendency to chelate Ag(I) and promote coordination numbers that are
247
higher than the linear two-coordinate complexes commonly seen when simple
248
monodentate amines bind to Ag(I). In the case of 1 it is interesting to note that the nitrate
249
anion is able to coordinate to the Ag centre (although rather weakly) despite the fact that
250
the Ag centre is already coordinated by a pair of chelating ligands each with relatively
251
large bite angles. In the case of 2 the more strongly coordinating selenocyanate binds
252
through both sulphur and nitrogen atoms to generate a linear polymer. In compound 3, the
253
PF6- serves as the counter-ion. In complexes 4 and 5, the [WS4]2- acts as a co-ligand, and
254
coordinates to three and four Ag(I) atoms, respectively through the sulfur atoms.
255 256
Acknowledgement
257
We thank Shahid Chamran University of Ahvaz for the financial support (grant number:
258
854532).
259
9 260
Appendix A. Supplementary material
261
CCDC reference numbers 1035600-1 contains the supplementary crystallographic data for
262
the structures 1 and 2, respectively. Crystallographic data can be obtained free of charge
263
from
264
http://www.ccdc.cam.ac.uk/datarequest/cif. Or from the Cambridge Crystallographic Data
265
Centre, 12 Union Road, Cambridge CB2 1EZ, UK; fax: (+44) 1223-336-033; or e-mail:
266
[email protected]. Supplementary material associated with this article can be
267
found, in the online version, at http://dx.doi.org/10.1016/j.molstruc.2014.11.008.
268
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338
Figure captions
339
Fig. 1. Observed (blue) and calculated (red) X-ray powder diffraction spectrum of
340
compound 1.
341
Fig. 2. Observed (brown) and calculated (violet) X-ray powder diffraction spectrum of
342
compound 2.
343
Fig. 3. An ORTEP view of 1, showing the atomic numbering scheme. H atoms are omitted
344
for clarity.
345
Fig. 4.View of 2D structure of 1 formed by the non-classic C-H···O hydrogen bonds.
346
Fig. 5. An ORTEP view of 2, showing the atomic numbering scheme. H atoms are omitted
347
for clarity.
348
Fig. 6. 2-D structure of 2 formed by the non-classic C-H···π (arene), C-H···N and C-H···Se
349
interactions. All interaction are shown by dashed lines.
350 compound
Table 1. Crystal data for compounds 1 and 2. 1 2
Chemical formula
AgC23H32N9O3
Ag2C25 H32N10Se2
12 Crystal system
monoclinic
monoclinic
Space group
P 21/n
C 2/c
a (Å)
9.8422(5)
22.4987(10)
b (Å)
13.7187(6)
7.9464(2)
c (Å)
19.3258(9)
20.5755(8)
α (°)
90.00
90.00
β(°)
96.488(2)
126.699(8)
γ(°)
90.00
90.00
z
4
4
2.89
2.37
2592.7
2950.57
R-factor (%) 3
V (Å ) 351 352
Table 2. Selected bond distances (Å) and angles (º) for compounds 1 and 2. Compound 1 Ag1- N2
2.406(2)
N1- C4
1.331(3)
Ag1- O2
2.615(8)
N1- N5
1.365(2)
Ag1- N3
2.436(2)
N8- C19
1.363(3)
Ag1- N1
2.464(2)
N8- C21
1.455(3)
Ag1 -N4
2.393(2)
O2- N9
1.233(7)
N2-Ag1-O2
87.1(2)
N2-Ag1-N3
82.40(6)
N2-Ag1-N1
99.43(6)
N2-Ag1-N4
170.43(6)
O2-Ag1-N1
112.3(2)
N3-Ag1-N1
96.05(6)
O2-Ag1-N3
151.1(2)
O2-Ag1-N4
84.1(2)
N4-Ag1-N3
107.14(6)
13 Compound 2
353 354 355
N2- Ag1
2.366(2)
N1- N2
1.371(3)
Ag1- N4
2.382(2)
Se1- C13
1.822(3)
Ag1- N5
2.336(3)
C11- C12
1.526(4)
Se1- Ag1
2.5571(4)
H12A- C12
0.990(2)
C13- Se1
1.822(3)
C13 -N5
1.145(4)
Se1-Ag1-N4
124.19(6)
N4-Ag1-N2
80.11(8)
N4-Ag1-N5
106.54(8)
N2-Ag1-N5
111.44(8)
Se1-Ag1-N2
124.19(6)
Se1-Ag1-N5
104.62(6)
14
356 357 358 359 360
Fig. 1
15
361 362 363 364 365
Fig. 2
16
366 367 368 369
Fig. 3
17
370 371 372 373 374
Fig. 4
18
375 376 377 378 379
Fig. 5
19
380 381
a
382 383
b
384 385 386 387
Fig. 6
20 388
389 390 391 392 393
Graphical abstract
21 394 395
Five silver – based complexes
396
structurally characterized.
397
Non-classical interactions play a major role in determining the final structure of these
398
compounds.
399 400 401 402 403 404
Graphical Abstract with pyrazole based ligand were synthesized and
22 405
Highlights
406
Non- covalent interactions CH…π and CH…O lead to formation of 2D structures.
407
Nitrate anion acting as a monodentate terminal ligand.
408 409 410 411
The W-S bands shifted to lower frequencies in WS4 complexes with the silver(I) ion.