A novel three-dimensional copper(I) cyanide coordination polymer constructed from various bridging ligands: synthesis, crystal structure and characterization

Abstract: The cyanide ligand can act as a strong σ-donor and an effective π-electron acceptor that exhibits versatile bridging abilities, such as terminal, μ2-C:N, μ3-C:C:N and μ4-C:C:N:N modes. These ligands play a key role in the formation of various copper(I) cyanide systems, including one-dimensional (1D) chains, two-dimensional (2D) layers and three-dimensional (3D) frameworks. According to the literature, numerous coordination polymers based on terminal, μ2-C:N and μ3-C,C,N bridging modes have been documented so f… Show more

“…Further, the bond angles between Cu and μ 2 -C:N: Cu2–C9–N5 and Cu1–N5–C9 are 174.5(6) and 177.4(6)° suggesting a linear arrangement. The C–N bond lengths of 1.153(9) and 1.161(8) Å for C8–N6 and C9–N5 are close to the reported C–N bond length in CuCN-MOF s. 60 The bond length of Cu1 1 –C8 is 2.281(8) whereas the Cu2–C9 bond length is 1.874(6) Å. The Cu–Cu distances between each rectangular face are shown in Fig.…”

“…The Cu1-Cu1 1 bond distance is 2.447(17) Å, shorter than the sum of van der Waals radii, and is close to the previously reported for Cu2-m 2 C:N units. 58,59 The bond lengths of Cu1-N4 and Cu1-N5 are 2.070(5) and 1.930 (5), and those of Cu2-N1 2 , Cu2-N3 2 , and Cu2-N6 3 60 The bond length of Cu1 1 -C8 is 2.281(8) whereas the Cu2-C9 bond length is 1.874(6) Å. The Cu-Cu distances between each rectangular face are shown in Fig.…”

A two-dimensional semiconducting Cu(i)-MOF for binder and conductive additive-free supercapattery

“…Further, the bond angles between Cu and μ 2 -C:N: Cu2–C9–N5 and Cu1–N5–C9 are 174.5(6) and 177.4(6)° suggesting a linear arrangement. The C–N bond lengths of 1.153(9) and 1.161(8) Å for C8–N6 and C9–N5 are close to the reported C–N bond length in CuCN-MOF s. 60 The bond length of Cu1 1 –C8 is 2.281(8) whereas the Cu2–C9 bond length is 1.874(6) Å. The Cu–Cu distances between each rectangular face are shown in Fig.…”

“…The Cu1-Cu1 1 bond distance is 2.447(17) Å, shorter than the sum of van der Waals radii, and is close to the previously reported for Cu2-m 2 C:N units. 58,59 The bond lengths of Cu1-N4 and Cu1-N5 are 2.070(5) and 1.930 (5), and those of Cu2-N1 2 , Cu2-N3 2 , and Cu2-N6 3 60 The bond length of Cu1 1 -C8 is 2.281(8) whereas the Cu2-C9 bond length is 1.874(6) Å. The Cu-Cu distances between each rectangular face are shown in Fig.…”

A two-dimensional semiconducting Cu(i)-MOF for binder and conductive additive-free supercapattery

“…A number of compounds were prepared in the same context by introducing rigid and flexible ligands such as the 1D chain [{Cu(CN)} 3 (phen)] n (18), [87] 2D layer 19), [88] [{Cu(CN)} 2 (4,4′-bipy)] n ( 19), [87] [{Cu(CN)} 4 (bpp) 2 n (20), [87] and a 3D [Cu 2 (CN) 2 (C 6 H 6 N 4 )] n (21). [5] Four ternary CN-CPs; 24), Hdptrz = 3,5-dipropyl-1H-1,2,4-triazole ( 25)) were reported by Ling et a. [89] The CN-groups are all in situ generated from C-C cleavage reaction of acetonitrile.…”

“…The cyanide anions can thus bridge between terminal and linker locations with a variety of methods (Scheme 1). [5] The functional characteristics of this class of materials are extremely intriguing in relation to their shape and composition, and include storage, [2b] supercapacitors, [6] switching, [7,8] catalysis, [9,10] biocompatibility, [11,12] electrochemistry, [13] adsorption, [14] separation, [2a] and magnetism, [15,16] and optical and calorimetric properties. [17] In addition to the successful preparation of their powders and solids in various forms, many researchers have successfully reported the controlled growth and deposition of thin films anchored on substrates through a variety of processes, such as the sequential deposition process, [18] epitaxial and oriented crystal growth, [19,20] step-by-step growth, [21,22] in situ crystallization, [23,24] multiple sequential adsorption, [25,26] electrochemical deposition, [27][28][29][30][31] spin coating, and grafting on surfaces or matrix.…”

“…Metal-cyanide complexes' cyanide bridging modes. [5] stituting M' by a metal ion with tetrahedral coordination (i.e., Cd, Hg). [39] One of the simple bridges that is essential to the physical and chemical characteristics of metal cyanometallate is the cyanide group.…”

Hofmann‐Type Cyanide Bridged Coordination Polymers for Advanced Functional Nanomaterials

Simple synthesis of novel magnetic silver polymer nanocomposites with a good separation capacity and intrinsic antibacterial activities with high performance