Solid-Phase “Self-Hydrolysis” of [Zn(NH3)4MoO4@2H2O] Involving Enclathrated Water—An Easy Route to a Layered Basic Ammonium Zinc Molybdate Coordination Polymer

Abstract: An aerial humidity-induced solid-phase hydrolytic transformation of the [Zn(NH3)4]MoO4@2H2O (compound 1@2H2O) with the formation of [(NH4)xH(1−x)Zn(OH)(MoO4)]n (x = 0.92–0.94) coordination polymer (formally NH4Zn(OH)MoO4, compound 2) is described. Based on the isostructural relationship, the powder XRD indicates that the crystal lattice of compound 1@2H2O contains a hydrogen-bonded network of tetraamminezinc (2+) and molybdate (2−) ions, and there are cavities (O4N4(μ-H12) cube) occupied by the two water molec… Show more

“…The heat-induced quasi-intramolecular redox reactions of [ML n ]­(XO 4 ) m complexes containing reducing ligands and oxidizing anions (where M = Cu, Zn, Cd, Co; L = NH 3 or pyridine, n = 2–6, and m = 0.5–3, and X = Mn, Cl, S, or Mo) in a solid phase ensure a convenient way to prepare simple or mixed-transition metal oxides with nanometer-sized particles. − These oxides, including nanosized iron oxide composites, − are active catalysts in various industrially important processes as their structures contain defects and their metallic components have variable valence states. − …”

Thermally Induced Solid-Phase Quasi-Intramolecular Redox Reactions of [Hexakis(urea-O)iron(III)] Permanganate: An Easy Reaction Route to Prepare Potential (Fe,Mn)O_x Catalysts for CO₂ Hydrogenation

“…The heat-induced quasi-intramolecular redox reactions of [ML n ]­(XO 4 ) m complexes containing reducing ligands and oxidizing anions (where M = Cu, Zn, Cd, Co; L = NH 3 or pyridine, n = 2–6, and m = 0.5–3, and X = Mn, Cl, S, or Mo) in a solid phase ensure a convenient way to prepare simple or mixed-transition metal oxides with nanometer-sized particles. − These oxides, including nanosized iron oxide composites, − are active catalysts in various industrially important processes as their structures contain defects and their metallic components have variable valence states. − …”

Thermally Induced Solid-Phase Quasi-Intramolecular Redox Reactions of [Hexakis(urea-O)iron(III)] Permanganate: An Easy Reaction Route to Prepare Potential (Fe,Mn)O_x Catalysts for CO₂ Hydrogenation

“…Based on the theoretical group analysis, the total number of factor group modes due to the regular molybdate MoO 4 tetrahedron is 4 and corresponds to 9 vibrations modes possible in the molybdate compounds. We note that all four modes are Raman active, but only the antisymmetric (T d ) modes are IR active [30,31].…”

“…The Zn-O-Mo mode is designated as a wideband system around 650 cm -1 [31]. The bands observed at 433 and 435 cm -1 are specific to the bending vibration of the Co-O-Mo bands [39].…”

“…Recently, in 2017, Ghiyasiyan-Arani et al [20] investigated the effect of different parameters on the sonochemical synthesis of FeVO 4 nanocomposite. The diversity of the synthesis processes (hydrothermal [21][22][23], microwave irradiation [24,25], Pechini [26,27], sonochemical route [28], solid-solid [29,30], molybdate complexes: ligand loss [31,32] and co-precipitation [33,34]), and preparation conditions (pH, temperature, time...) have a huge influence on the microstructure and morphology of the obtained powders.…”

Electronic, magnetic, optical properties, and morphological characteristics of nanocrystalline based on zinc–cobalt molybdate prepared by soft chemistry route

“…An easy way to prepare catalytically active simple or mixed transition metal oxides is a lowtemperature thermal treatment of transition metal tetraoxometallate (ClO4 -, MnO4 -, SO4 2-, MoO4 2-) complexes with reducing ligands like ammonia [1][2][3][4][5] or pyridine. [6][7][8][9][10] The key factor in the occurrence of the solid-phase quasi-intramolecular redox reactions resulting in these oxide materials is the presence of a hydrogen bond between the N-H or C-H functional groups of the ligand and the M-O moiety of the anion.…”

Structural and Raman spectroscopic characterization of tetrapyridinesilver(I) perrhenate, [Agpy4]ReO4