Architecture Dependence on the Steric Constrains of the Ligand in Cyano-Bridged Copper(I) and Copper(II)−Copper(I) Mixed-Valence Polymer Compounds Containing Diamines:  Crystal Structures and Spectroscopic and Magnetic Properties

Colacio, Enrique; Kivekäs, Raikko; Lloret, Francesc; Sunberg, Markku; Suárez‐Varela, José; Bardajı́, Manuel; Laguna, Antonio

doi:10.1021/ic025743v

Cited by 112 publications

(68 citation statements)

References 31 publications

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“…As the reaction was carried out under hydrothermal conditions, it is not surprising that the Cu II and Fe III ions have been reduced to Cu I and Fe II ions by cyanide or N-heterocyclic ligands, such as 1,10-phen or pyridine derivatives. [17][18][19] The cyanide in 1 is provided by the ferricyanide anions. A view of the metal coordination environment is presented in Figure 1.…”

Section: Resultsmentioning

confidence: 99%

Synthesis and Crystal Structures of Four Cyanide‐Bridged Coordination Polymers

Yuan

et al. 2005

Eur J Inorg Chem

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The hydrothermal reaction of Cu(NO3)2·3 H2O, K3Fe(CN)6, and 1,10‐phenanthroline (1,10‐phen) or 2,2'‐bipyridine (2,2'‐bpy) gives rise to the three one‐dimensional helical‐chain complexes [Cu2Fe(CN)4(1,10‐phen)3]n·0.5n H2O (1), [Cu3(CN)3(1,10‐phen)3]n (2), and [Cu3(CN)3(2,2'‐bpy)3]n (3), and the two‐dimensional layer complex [Cu3Fe(CN)5(2,2'‐bpy)2]n (4). The structure of 1 contains a cyanide‐bridged CuI···FeII···CuI chain in which the two copper and one iron centers exhibit different coordination environments. The structures of 2 and 3 are both monometallic. Complex 4 is constructed alternately from fused 6‐ and 14‐metal‐membered nonplanar centrosymmetric rings that form a 2D layer architecture. (© Wiley‐VCH Verlag GmbH & Co. KGaA, 69451 Weinheim, Germany, 2005)

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Section: Resultsmentioning

confidence: 99%

Synthesis and Crystal Structures of Four Cyanide‐Bridged Coordination Polymers

Yuan

et al. 2005

Eur J Inorg Chem

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“…Several polymeric mixed-valence copper(i/ii) compounds crystallise with one-dimensional, [18][19][20] two-dimensional [21][22][23][24] and three-dimensional arrays, [21][22][23][24][25][26][27] but there seem to be few examples of interpenetration [24,25] and few in which the network is built up primarily from covalent bonds [21,[24][25][26] rather than weak interactions. Even examples of covalent interpenetrating (10,3)-a networks with other transition metals appear to be somewhat scarce.…”

Section: Resultsmentioning

confidence: 99%

Total Spontaneous Resolution of Chiral Covalent Networks from Stereochemically Labile Metal Complexes

Johansson

Håkansson

Jagner

2005

Chemistry A European J

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Stereochemically labile copper and zinc complexes with the N,N'-dimethylethylenediamine ligand (dmeda) have been shown to be promising precursors for the total spontaneous resolution of chiral covalent networks. (N,N')-[Cu(NO3)2(dmeda)]infinity crystallises as a conglomerate and yields either enantiopure (R,R)-1 or enantiopure (S,S)-1. A mixed-valence copper(I/II) complex, [{Cu(II)Br2(dmeda)}3(Cu(I)Br)2]infinity (2), which crystallises as a pair of interpenetrating chiral (10,3)-a nets, is formed from CuBr, CuBr2 and dmeda. One net contains ligands with solely (R,R) configuration and exhibits helices with (P) configuration while the other has solely (S,S)-dmeda ligands and gives rise to a net in which the helices have (M) configuration. The whole crystalline arrangement is racemic, because the interpenetrating chiral nets are of opposite handedness. With zinc chloride (R,S)-[ZnCl(dmeda)2]2[ZnCl4] (3) is obtained, which is a network structure, although not chiral. Total spontaneous resolution of stereochemically labile metal complexes formed from achiral or racemic building blocks is suggested as a viable route for the preparation of covalent chiral networks. Once the absolute structure of the compound has been determined by X-ray crystallography, a quantitative determination of the enantiomeric excess of the bulk product can be undertaken by means of solid-state CD spectroscopy.

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“…A part of a single layer of the two-dimensional network is shown in the top of the figure, the interlocking of this layers by the acetonitrile molecules at the bottom. Plane [3,4] and undulated layers [5,6] of (CuCN) 6 rings or (CuCN) 8 rings [7] are already known. Layers built of (CuCN)4 rings are less common [8].…”

Section: Discussionmentioning

confidence: 99%

Crystal structure of (acetonitrile-N)copper(I) cyanide, [Cu(CH3CN)][CN]

H.-L.

Oldag

2006

Zeitschrift Für Kristallographie - New Crystal Structures

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C 3 H 3 CuN 2 , monoclinic, P12 1 /c1 (no. 14), a = 8.399(2) Å, b = 8.144(2) Å, c = 7.836(2) Å, b = 116.56(3)°, V = 479.4 Å 3 , Z = 4, R gt(F) = 0.024, wRref(F 2 ) = 0.059, T = 120 K. Source of materialCopper(I) cyanide (0.2 g) prepared according [1] and acetonitrile (HPLC-grade, 1 mL) were mixed together. This mixture was filled in a glass ampule (Duran, interior diameter 10 mm, length 80 mm) which was evacuated and sealed. Following annealing was performed in an electric resistance oven at a temperature of 423 K. After three weeks the ampule was taken out, rapidly cooled down to room temperature and the solids were separated from the solvent. By this procedure the title compound can by obtained as single phase. DiscussionHibble et al. have described the rather complex structural chemistry of CuCN, AgCN and AuCN [2]. They were able to refine C and N occupancies of CuCN. The results indicate a ¢head-to-tail¢ disorder of the cyanide groups. We tried to crystallize CuCN with ordered cyanide groups by solvothermal syntheses with acetonitrile as solvent. Single crystal X-ray structure analysis of the title compound in combination with X-ray powder phase analysis of the bulk material shows that only a solvate of copper(I) cyanide and acetonitrile could be obtained as single phase by the described synthesis. The refinement with the occupancies of C and N indicates ordered cyanide groups. Two of the three cyanide groups in the coordination sphere of copper are carbon linked to the copper atom, the third one is linked via the nitrogen atom.[Cu(CH 3CN)][CN] could be described as a two-dimensional network (Schläfli symbol 8 2 ·4; for Cu and C) of condensed (CuCN)4 rings perpendicular to [100]. The layers are undulated. Additionally, the copper atom is coordinated by the nitrogen atom of the acetonitrile molecule along [100]. A part of a single layer of the two-dimensional network is shown in the top of the figure, the interlocking of this layers by the acetonitrile molecules at the bottom. Plane [3,4] and undulated layers [5,6] of (CuCN) 6 rings or (CuCN) 8 rings [7] are already known. Layers built of (CuCN)4 rings are less common [8].

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Architecture Dependence on the Steric Constrains of the Ligand in Cyano-Bridged Copper(I) and Copper(II)−Copper(I) Mixed-Valence Polymer Compounds Containing Diamines: Crystal Structures and Spectroscopic and Magnetic Properties

Cited by 112 publications

References 31 publications

Synthesis and Crystal Structures of Four Cyanide‐Bridged Coordination Polymers

Synthesis and Crystal Structures of Four Cyanide‐Bridged Coordination Polymers

Total Spontaneous Resolution of Chiral Covalent Networks from Stereochemically Labile Metal Complexes

Crystal structure of (acetonitrile-N)copper(I) cyanide, [Cu(CH3CN)][CN]

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