Crystal structure of poly[triaqua-(di(2,2′-bipyridine-κ2N,N′)-μ4-silanetetrayltetrakis(benzene-4,1-diyl)tetrakis (hydrogen phosphonato)-κ4O:O′:O′′:O′′′) dicadmium(II)], C44H42N4O15P4Cd2Si

Baogang Wang; Xiaxia Man

doi:10.1515/ncrs-2020-0316

Article Open Access

Crystal structure of poly[triaqua-(di(2,2′-bipyridine-κ²N,N′)-μ₄-silanetetrayltetrakis(benzene-4,1-diyl)tetrakis (hydrogen phosphonato)-κ⁴O:O′:O′′:O′′′) dicadmium(II)], C₄₄H₄₂N₄O₁₅P₄Cd₂Si

Baogang Wang and Xiaxia Man

Published/Copyright: September 12, 2020

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From the journal Zeitschrift für Kristallographie - New Crystal Structures Volume 235 Issue 6

Abstract

C₄₄H₄₂N₄O₁₅P₄Cd₂Si, triclinic, P1̄ (no. 2), a = 13.4778(9) Å, b = 14.2036(9) Å, c = 15.2206(10) Å, α = 69.637(1)°, β = 72.355(1)°, γ = 64.861(1)°, V = 2431.1(3) Å³, Z = 2, R_gt(F) = 0.0428, wR_ref(F²) = 0.0987, T = 120(2) K.

CCDC no.: 2024330

A part of the title crystal structure is shown in the figure. Tables 1 and 2 contain details of the measurement method and a list of the atoms including atomic coordinates and displacement parameters.

Table 1:

Data collection and handling.

Crystal:	Colorless block
Size:	0.50 × 0.40 × 0.30 mm
Wavelength:	Mo Kα radiation (0.71073 Å)
μ:	1.10 mm⁻¹
Diffractometer, scan mode:	Bruker D8 QUEST, φ and ω
θ_max, completeness:	26.1°, 99%
N(hkl)_measured, N(hkl)_unique, R_int:	15498, 9617, 0.034
Criterion for I_obs, N(hkl)_gt:	I_obs > 2 σ(I_obs), 7610
N(param)_refined:	643
Programs:	Bruker [1], SHELX [2], [3]

Table 2:

Fractional atomic coordinates and isotropic or equivalent isotropic displacement parameters (Å²).

Atom	x	y	z	U_iso*/U_eq
C1	0.4668(3)	−0.2011(3)	1.1643(3)	0.0144(9)
C2	0.5800(4)	−0.2208(4)	1.1481(3)	0.0261(11)
H2	0.6234	−0.2254	1.0865	0.031*
C3	0.6306(4)	−0.2340(4)	1.2205(3)	0.0251(11)
H3	0.7084	−0.2481	1.2080	0.030*
C4	0.5696(3)	−0.2270(3)	1.3108(3)	0.0148(9)
C5	0.4577(4)	−0.2108(4)	1.3286(3)	0.0238(10)
H5	0.4148	−0.2078	1.3905	0.029*
C6	0.4074(4)	−0.1990(4)	1.2557(3)	0.0219(10)
H6	0.3305	−0.1894	1.2693	0.026*
C7	0.8206(5)	0.0278(4)	1.2278(3)	0.0345(13)
H7	0.7902	−0.0160	1.2174	0.041*
C8	0.8642(5)	0.0930(5)	1.1503(4)	0.0435(16)
H8	0.8655	0.0933	1.0875	0.052*
C9	0.9061(5)	0.1581(5)	1.1651(4)	0.0391(14)
H9A	0.9363	0.2045	1.1127	0.047*
C10	0.9036(4)	0.1549(4)	1.2570(4)	0.0295(11)
H10	0.9320	0.1994	1.2687	0.035*
C11	0.8595(4)	0.0865(3)	1.3326(3)	0.0186(9)
C12	0.8542(3)	0.0794(3)	1.4341(3)	0.0183(9)
C13	0.9024(4)	0.1348(3)	1.4586(3)	0.0232(10)
H13A	0.9365	0.1814	1.4105	0.028*
C14	0.8994(4)	0.1205(4)	1.5539(4)	0.0269(11)
H14A	0.9309	0.1578	1.5722	0.032*
C15	0.8499(4)	0.0515(4)	1.6223(3)	0.0260(11)
H15A	0.8487	0.0389	1.6880	0.031*
C16	0.8024(4)	0.0015(4)	1.5930(3)	0.0232(10)
H16	0.7666	−0.0444	1.6400	0.028*
C17	0.3003(3)	−0.0155(3)	1.0484(3)	0.0164(9)
C18	0.3027(4)	0.0489(3)	1.0981(3)	0.0187(9)
H18	0.3519	0.0186	1.1423	0.022*
C19	0.2350(4)	0.1563(4)	1.0845(3)	0.0191(10)
H19	0.2382	0.1985	1.1194	0.023*
C20	0.1627(3)	0.2030(3)	1.0206(3)	0.0174(9)
C21	0.1609(4)	0.1401(4)	0.9687(3)	0.0230(10)
H21	0.1130	0.1709	0.9235	0.028*
C22	0.2288(4)	0.0332(4)	0.9831(3)	0.0220(10)
H22	0.2267	−0.0086	0.9471	0.026*
C23	0.2830(3)	−0.2358(3)	1.1210(3)	0.0156(9)
C24	0.3185(4)	−0.3464(4)	1.1536(3)	0.0250(11)
H24	0.3959	−0.3873	1.1425	0.030*
C25	0.2441(4)	−0.3993(4)	1.2022(3)	0.0253(11)
H25	0.2712	−0.4755	1.2241	0.030*
C26	0.1304(3)	−0.3417(3)	1.2191(3)	0.0155(9)
C27	0.0935(4)	−0.2311(4)	1.1869(4)	0.0276(11)
H27	0.0160	−0.1903	1.1982	0.033*
C28	0.1692(4)	−0.1790(4)	1.1379(3)	0.0258(11)
H28	0.1422	−0.1028	1.1156	0.031*
C29	0.4789(4)	−0.1921(3)	0.9552(3)	0.0162(9)
C30	0.5577(4)	−0.2933(3)	0.9488(3)	0.0211(10)
H30	0.5663	−0.3506	1.0050	0.025*
C31	0.6239(4)	−0.3128(4)	0.8630(3)	0.0218(10)
H31	0.6776	−0.3824	0.8610	0.026*
C32	0.6117(3)	−0.2301(3)	0.7794(3)	0.0156(9)
C33	0.5370(4)	−0.1287(4)	0.7847(3)	0.0220(10)
H33	0.5292	−0.0714	0.7285	0.026*
C34	0.4734(4)	−0.1098(4)	0.8711(3)	0.0223(10)
H34	0.4244	−0.0387	0.8735	0.027*
C35	0.2608(4)	0.5739(4)	0.8784(3)	0.0309(12)
H35	0.2143	0.5546	0.9371	0.037*
C36	0.3456(5)	0.6031(5)	0.8789(4)	0.0448(15)
H36	0.3581	0.6033	0.9370	0.054*
C37	0.4122(5)	0.6321(6)	0.7933(4)	0.0546(18)
H37	0.4697	0.6549	0.7917	0.065*
C38	0.3949(5)	0.6277(5)	0.7100(4)	0.0467(16)
H38	0.4417	0.6453	0.6509	0.056*
C39	0.3081(4)	0.5971(4)	0.7139(3)	0.0275(11)
C40	0.2825(4)	0.5908(4)	0.6288(3)	0.0241(10)
C41	0.1611(4)	0.5688(4)	0.5646(3)	0.0258(11)
H41	0.0940	0.5573	0.5730	0.031*
C42	0.2252(4)	0.5815(4)	0.4744(3)	0.0317(12)
H42	0.2027	0.5790	0.4221	0.038*
C43	0.3229(4)	0.5978(4)	0.4623(3)	0.0344(12)
H43	0.3702	0.6046	0.4016	0.041*
C44	0.3508(4)	0.6040(4)	0.5394(3)	0.0316(12)
H44	0.4168	0.6173	0.5317	0.038*
Cd1	0.73028(2)	−0.07422(2)	1.44706(2)	0.01366(8)
Cd2	0.08702(3)	0.53987(3)	0.79651(2)	0.01772(9)
H7A	−0.090(3)	0.705(4)	0.699(3)	0.032(15)*
H7B	−0.073(5)	0.722(5)	0.776(5)	0.07(2)*
N1	0.8045(3)	0.0146(3)	1.5012(2)	0.0165(8)
N2	0.8190(3)	0.0233(3)	1.3174(3)	0.0193(8)
N3	0.2413(3)	0.5717(3)	0.7983(3)	0.0261(9)
N4	0.1885(3)	0.5718(3)	0.6406(3)	0.0220(8)
O1	0.5709(2)	0.0764(3)	1.4316(2)	0.0250(7)
H1A	0.5482	0.1258	1.4620	0.038*
H1B	0.5101	0.0770	1.4222	0.038*
O2	0.8981(2)	−0.2259(2)	1.4616(2)	0.0213(7)
H2A	0.9110	−0.2599	1.4193	0.032*
H2B	0.8889	−0.2717	1.5161	0.032*
O3	0.6632(2)	−0.1350(2)	1.3723(2)	0.0186(7)
O4	0.5531(2)	−0.2500(2)	1.49598(19)	0.0182(6)
O5	0.0411(3)	0.3686(2)	1.0959(2)	0.0296(8)
O6	0.1418(2)	0.4047(2)	0.9214(2)	0.0227(7)
O7	−0.0447(3)	0.7146(3)	0.7212(3)	0.0255(8)
O8	0.6554(2)	−0.1430(2)	0.59366(19)	0.0175(6)
O9	0.6317(2)	−0.3243(2)	0.6481(2)	0.0182(6)
H9	0.6071	−0.2952	0.5969	0.027*
O10	0.8064(2)	−0.3139(2)	0.6611(2)	0.0214(7)
O11	0.0118(2)	−0.4517(2)	1.2162(2)	0.0205(7)
O12	−0.0712(3)	−0.3240(2)	1.3244(2)	0.0257(7)
O13	0.0822(2)	−0.4976(2)	1.3671(2)	0.0208(7)
H13	0.1163	−0.5551	1.3498	0.031*
O14	−0.0284(2)	0.3540(2)	0.9683(2)	0.0228(7)
H14	−0.0255	0.3847	0.9099	0.034*
O15	0.7389(2)	−0.3380(2)	1.4079(2)	0.0233(7)
H15	0.7955	−0.3222	1.3777	0.035*
P1	0.02951(9)	−0.40560(9)	1.28371(8)	0.0165(2)
P2	0.07746(10)	0.34409(9)	1.00062(8)	0.0192(3)
P3	0.68338(9)	−0.25233(9)	0.66279(7)	0.0144(2)
P4	0.63298(9)	−0.23372(9)	1.40194(8)	0.0153(2)
Si1	0.38576(10)	−0.16328(9)	1.06988(8)	0.0142(2)

Source of material

A mixture of silanetetrayltetrakis(benzene-4,1-diyl)tetrakis phosphonic acid (0.2 mmol), 2,2′-bipyridine (0.2 mmol), Cd(NO₃)₂ ⋅ 4(H₂O) (0.2 mmol), H₂O (8 mL) was stirred for ten minutes. The mixture was transferred in a 25 mL stainless steel reactor with a Teflon liner and heated from 298 to 453 K in 5 h and a constant temperature was maintained at 453 K for 72 h. After cooling to room temperature, colorless block crystals were collected in 55.3% yield based on the amounts of Cd.

Experimental details

Coordinates of hydrogen atoms were calculated. Their U_iso values were set to 1.2U_eq of the parent atoms.

Comment

Coordination polymers (CPs) composed of metal nodes and bridging linkers have attracted much attention over the past decades due to their enormous variety of intriguing structural topologies and great potential applications [4], [5]. Compared with carboxylates and pyrazolate counterparts, phosphonate groups have a stronger interaction with metal ions, and consequently higher chemical and thermal stability [6], [7], [8]. The excellent robustness of metal phosphonates represents remarkable added value and should promote their investigation, regardless of the challenges relating to their synthesis and characterization, in order to develop a new generation of robust CPs able to overcome the typical weaknesses of classical CPs.

The asymmetric unit of the title structure contains two crystallographically independent cadmium(II) ions, one silanetetrayltetrakis (benzene-4,1-diyl)tetrakis(hydrogen phosphonato) ligand, two 2,2′-bipyridine and three coordinated water molecules. Cd1 is six-coordinated by four O atoms from two silanetetrayltetrakis(benzene-4,1-diyl)tetrakis(hydrogen phosphonato) ligands and two water molecules, two N atoms from one 2,2′-bipyridine, forming a distorted octahedral geometry. Cd2 is also six-coordinated by four O atoms from three silanetetrayltetrakis(benzene-4,1-diyl)tetrakis(hydrogen phosphonato) ligands and one water molecule, two N atoms from one 2,2′-bipyridine, also forming a distorted octahedral geometry. The distances between Cd and the coordinated atoms are: d(Cd1⋯O1) = 2.302(3) Å, d(Cd1⋯O2) = 2.375(3) Å, d(Cd1⋯O3) = 2.199(3) Å, d(Cd1⋯O8) = 2.215(3) Å, d(Cd1⋯N1) = 2.360(3) Å, d(Cd1⋯N2) = 2.360(3) Å, d(Cd2⋯O5) = 2.284(3) Å, d(Cd2⋯O6) = 2.224(3) Å, d(Cd2⋯O7) = 2.477(3) Å, d(Cd2⋯O11) = 2.264(3) Å, d(Cd2⋯N3) = 2.317(4) Å, and d(Cd2⋯N4) = 2.349(4) Å, respectively. The Cd1 coordination angles are from 70.93(12)° to 178.12(10)°, and Cd2 coordination angles are from 66.81(12)° to 158.45(12)°. These above mentioned bond distances and angles are all in their normal ranges. They can be compared with those previously reported compounds [9]. The Cd1 ion links its symmetry-related atoms to form a dinuclear secondary building unit (SBU) bridged by two silanetetrayltetrakis(benzene-4,1-diyl)tetrakis (hydrogen phosphonato) ligands. Cd2 ion is mononuclear linked by two silanetetrayltetrakis (benzene-4,1-diyl)tetrakis(hydrogen phosphonato) ligands. The Cd1 dinuclear SBUs and Cd2 mononuclear are linked by silanetetrayltetrakis(benzene-4,1-diyl)tetrakis (hydrogen phosphonato) ligands to form two-dimensional (2D) layer framework parallel to the bc plane. These 2D layers are packed together to form 3D framework structures through the π-π interactions between neighboring benzene rings from parallel 2,2′-bipyridine. There are related structures that have been reported with the same ligand [10]. For example, three-dimensional compound Cd₄(H₄L)₂(phen)₂(H₂O)₄ which is characterized as a 3,4,6-connected network with the vertex symbol of {4⋅6⁴⋅8}²{4²⋅6⁴⋅8⁹}{6²⋅8}² and the compound Cu₂H₄STPPA⋅2H₂O with three dimensional porous framework were synthesized using hydrothermal reaction method [11], [12].

Acknowledgements

This work is supported by the project development plan of science and technology of Jilin Province.

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Received: 2020-06-28

Accepted: 2020-08-20

Published Online: 2020-09-12

Published in Print: 2020-10-27

This work is licensed under the Creative Commons Attribution 4.0 International License.

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Crystal structure of poly[triaqua-(di(2,2′-bipyridine-κ2N,N′)-μ4-silanetetrayltetrakis(benzene-4,1-diyl)tetrakis (hydrogen phosphonato)-κ4O:O′:O′′:O′′′) dicadmium(II)], C44H42N4O15P4Cd2Si

Article

Abstract

Source of material

Experimental details

Comment

Acknowledgements

References

Supplementary Material

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Articles in the same Issue

Crystal structure of poly[triaqua-(di(2,2′-bipyridine-κ²N,N′)-μ₄-silanetetrayltetrakis(benzene-4,1-diyl)tetrakis (hydrogen phosphonato)-κ⁴O:O′:O′′:O′′′) dicadmium(II)], C₄₄H₄₂N₄O₁₅P₄Cd₂Si