Bimetallic Coordination Polymers via Combination of Substitution-Inert Building Blocks and Labile Connectors

Kondracka, Małgorzata; Englert, Ulli

doi:10.1021/ic800748f

Cited by 53 publications

(52 citation statements)

References 25 publications

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“…PF 6 − counter anions and hydrate water molecules occupy the voids in the resulting cationic framework. PF 6 − counter anions and hydrate water molecules occupy the voids in the resulting cationic framework.…”

Section: Resultsmentioning

confidence: 99%

Interplay of ligand chirality and metal configuration in mononuclear complexes and in a coordination polymer of Cr(iii)

2015

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In order to investigate the influence of ligand chirality on the configuration of the coordinated metal, five pseudooctahedral CrĲIII) complexes with one or two chelating R,R-1,2-diaminocyclohexane ligands have been synthesized. The mononuclear complexes ĳCrĲR,R-chxn) 2 ClĲDMSO)]Cl 2 , ĳCrĲR,R-chxn) 2 Cl 2 ]Cl, ĳCrĲacacCN)ĲR,R-chxn) 2 ]ĲNO 3 ) 2 , ĳCrĲacacCN) 2 ĲR,R-chxn)]NO 3 , ĳCrĲacacCN) 2 ĲR,R-chxn)]PF 6 . (R,R-chxn = R,R-1,2-diaminocyclohexane; acacCN = deprotonated 3-cyanoacetylacetone and DMSO = dimethyl sulfoxide) have been obtained as crystalline solids, mostly solvates, and the potential chirality transfer from the enantiopure ligand to the configuration at the CrĲIII) center has been investigated. The cationic complex ĳCrĲacacCN) 2 ĲR,R-chxn)] + has been synthesized as exclusively Λ configured at the metal. In this complex, the dangling nitrile groups of the ditopic acacCN ligands may coordinate to AgĲI): the chiral-at-metal building block has thus been converted to the 2D network AgĳCrĲacacCN) 2 ĲR,R-chxn)] 2 ĲPF 6 ) 3 under retention of the stereochemistry at CrĲIII). With respect to topology, the polycations in this mixed-metal coordination polymer correspond to two interpenetrated {4,4} nets. CrystEngCommThis journal is † Electronic supplementary information (ESI) available: Crystallographic information in CIF format; details concerning crystallization, structure solution and refinement of 1-4 and 6-8; hydrogen bonds in 1, 2, 6 and 8; displacement ellipsoid plots of asymmetric unit for 1-4 and 6-8; powder patterns for 1, 2, 4, 5, 6, 7 and 8. CCDC 1047808-1047814. For ESI and crystallographic data in CIF or other electronic format see

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Section: Resultsmentioning

confidence: 99%

Interplay of ligand chirality and metal configuration in mononuclear complexes and in a coordination polymer of Cr(iii)

2015

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“…In the absence of alternative N donor atoms, this coordination is not surprising. In this and the following figures which summarize silver coordination, not only conventional bonds between metal cations and donor ligands have been included for good reason: In recent contributions by our own [16,28] and other groups [18,19,21,22,45], AgÁÁÁAg distances of ca 3 Å have been discussed; it is obviously not acceptable to emphasize interactions of this [46,47]. When compared to other salts with organic anions, the calculated density of 1 is remarkably high: Our silver squarate ranks ninth amongst 3755 carbon-containing entries for which silver is the heaviest element documented in the CSD; four of the eight entries associated with a higher density refer to the same compound, namely silver oxalate.…”

Section: Resultsmentioning

confidence: 99%

“…In addition to coordination networks based on one type of cations, more complex bimetallic systems have also been described [12][13][14][15][16]. Polymers based on silver cations are particularly attractive: Their lability facilitates crystallization and dissolution processes [17], and closed-shell interactions between Ag(I) cations have recently emerged as candidates for crystal engineering [18][19][20].…”

Section: Introductionmentioning

confidence: 99%

Silver coordination polymers with remarkably high packing coefficients

2009

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Silver meso-and rac-tartrate and silver squarate have been synthesized, and the crystal structure of a new polymorph of the latter is reported. Three reaction products of these silver salts with pyrazine have been obtained and structurally characterized: From silver squarate, a chain polymer with linear coordination of Ag(I) by two pyrazine ligands is formed, whereas the silver tartrates yield solids in which the inner coordination sites around the metal are only partially occupied by N donors; in contrast to expectation, oxygen coordination prevails. All the four new Ag(I) coordination compounds reported show high packing coefficients in the range between 0.789 and 0.885. In order to put these results into a meaningful context, packing coefficients for the crystal structures of almost 30,000 compounds retrieved from the Cambridge Structural Database have been determined. Tartrates pack significantly closer than pyrazine complexes or metalcontaining compounds in general. The exceptionally high packing coefficient of the new polymorph of silver squarate is due to stacking of anions and concomitant AgÁÁÁAg contacts, both along the shortest lattice parameter which amounts to only 3.3990(9) Å .

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“…In addition, the pyridine derivatives in Scheme 1 (ligands a-c) behave as good N nucleophiles to metal cations. Earlier work with this ligand has covered the O, O′ coordination chemistry of Cu, Fe, 19 Cr, 20 Al, 21 and rare earth cations. 18 In contrast, the N donor capabilities of the nitrile-substituted 3-cyanoacetylacetone HacacCN (Scheme 1, d) are much less pronounced.…”

Section: Introductionmentioning

confidence: 99%

Crosslinking of the Pd(acacCN)₂ building unit with Ag(i) salts: dynamic 1D polymers and an extended 3D network

Guo

Merkens

et al. 2015

CrystEngComm

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After deprotonation, the acetylacetonate moiety of the ditopic ligand 3-cyanoacetylacetone (HacacCN) acts as a chelating ligand towards PdĲII). The resulting square-planar complex PdĲacacCN) 2 represents a suitable building unit for extended structures via coordination of AgĲI) cations to the peripheral nitrile groups. These target compounds have been structurally characterized: with silver salts of the anions BF 4 − , ClO 4 − , PF 6 − and CF 3 SO 3 − , chain polymers with an alternating sequence of PdĲII) and AgĲI) are obtained. Solvent molecules and counter anions fill voids close to the silver cations; more weakly coordinating anions are engaged in longer, the triflate anion in a shorter interaction to AgĲI). In contrast to powder samples, larger crystals of these one-dimensional polymers are rather stable with respect to desolvation. Two isomorphous 1D structures undergo a fully reversible k 2 phase transition which can be monitored by single crystal diffraction. The phase transition temperature depends on the nature of the counter anion and may therefore be tuned as a function of chemical composition. The formation of chain polymers by linking PdĲacacCN) 2 building blocks with AgĲI) salts of BF 4 − , ClO 4 − , PF 6 − and CF 3 SO 3 − follows chemical intuition whereas its reaction with silver nitrate leads to an unexpected and close-packed 3D structure in which layers of composition AgĲNO 3 ) are connected by PdĲacacCN) 2 linkers. CrystEngComm This journal is ; Tel: +1 612 8021080† Electronic supplementary information (ESI) available: Crystallographic information in CIF format, displacement ellipsoid plots for 1-7, powder patterns for 2, 3, 5 and 7, intensity ratio IĲ f/t) for 2 and 3 over larger temperature ranges, intensity of single reflections in 2, 3 and 4, 19 F NMR result of 4 and sequence of slides visualizing the phase transition in 2.

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Bimetallic Coordination Polymers via Combination of Substitution-Inert Building Blocks and Labile Connectors

Cited by 53 publications

References 25 publications

Interplay of ligand chirality and metal configuration in mononuclear complexes and in a coordination polymer of Cr(iii)

Interplay of ligand chirality and metal configuration in mononuclear complexes and in a coordination polymer of Cr(iii)

Silver coordination polymers with remarkably high packing coefficients

Crosslinking of the Pd(acacCN)₂ building unit with Ag(i) salts: dynamic 1D polymers and an extended 3D network

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Bimetallic Coordination Polymers via Combination of Substitution-Inert Building Blocks and Labile Connectors

Cited by 53 publications

References 25 publications

Interplay of ligand chirality and metal configuration in mononuclear complexes and in a coordination polymer of Cr(iii)

Interplay of ligand chirality and metal configuration in mononuclear complexes and in a coordination polymer of Cr(iii)

Silver coordination polymers with remarkably high packing coefficients

Crosslinking of the Pd(acacCN)2 building unit with Ag(i) salts: dynamic 1D polymers and an extended 3D network

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Crosslinking of the Pd(acacCN)₂ building unit with Ag(i) salts: dynamic 1D polymers and an extended 3D network