Gelled Na<Subscript>2</Subscript>HPO<Subscript>4</Subscript> · 12H<Subscript>2</Subscript>O with amylose-g-sodium acrylate: heat storage performance,heat capacity and heat of fusion

A novel gelling method was studied to stabilize phase change material Na₂HPO₄ · 12H₂O with amylose grafted sodium acrylate. Gelled Na₂HPO₄ · 12H₂O shows stable heat storage performance prepared at optimized conditions: 2.7mass/mass% sodium acrylate, 0.4 mass/mass% amylose, 0.05–0.09 mass/mass% N, N′-methylenebisacrylamide, 0.05–0.09 mass/mass% K₂S₂O₈ and Na₂SO₃ (mass ratio 1:1), at 50 °C. Na₂HPO₄ · 12H₂O was dispersed in gel network as tiny crystals less than 0.1 mm. Melting points were in the range 35.4 ± 2 °C. Short-term thermal cycling proves the effectiveness of the novel method for eliminating phase separation in the gelled salt. Adiabatic calorimetric measurement of heat capacities shows two phase transitions, which correspond to melting of Na₂HPO₄ · 12H₂O and freezable bond water in gel, respectively. Heat of fusion of pure Na₂HPO₄ · 12H₂O was determined as 260.9 J g⁻¹. Distribution of extra water is: free water:freezable water:nonfreezing water = 0:0.85:0.15.     

Heat Storage Performance of Disodium Hydrogen Phosphate Dodecahydrate： Prevention of Phase Separation by Thickening and Gelling Methods

Disodium hydrogen phosphate dodecahydrate （Na2HPO4·12H2O） is an attractive candidate for phase change materials. The main problem for its practical use comes from incongruent melting character during thermal cycling. Experimentally, heat of fusion of the pure salt decreased from 200 to 25 jog 1 in a four-run freeze-thaw cycling. Additives such as thickening agent or in-situ synthesized polyacrylate sodium in the molten salt can prevent its phase separation to some extent. In the test, sodium alginate 3.0%-5.0% （w/w） thickened mixture containing Na2HPOn·12H2O and some water showed constant heat storage capacities. Polyacrylate sodium gelled salt was synthesized through polymerizing sodium acrylate in the melt of Na2HPOn·12H2O and some extra water at 50 ℃. Optimum conditions composed of sodium acrylate 3.0%-5.0% （w/w）, cross-linking agent N,N-methylenebis-acrylamide 0.10%-0.20% （w/w）, K2S208 and Na2SO3 （mass ratio 1 ; 1） 0.06%-0.12% （w/w）. As opposed to normal large crystals of pure Na2HPOn·12H2O in solid state, the gelled salt existed in a large number of tiny particles dispersed in the gel network at room temperature, commonly less than 2 mm. But only those sample particles with sizes less than 0.2 mm may have relatively stable thermal storage property. A problem encountered was the poor reproducibility of the synthesis method： heat storage capacity of the product was often very different even though the synthesis was carried out in the same conditions. An alternative gelling method by sodium alginate grafted sodium acrylate was tried and it showed a fairly good effect. Heat capacities and heat of fusion of Na2HPO4·12H2O were measured by an adiabatic calorimeter.     

ChemInform Abstract: Polymorphism of New Rubidium Magnesium Monophosphate.

RbMgPO₄ is synthesized by solid state reaction of stoichiometric mixtures of Rb₂CO₃, 4MgCO₃·Mg(OH)₂·5H₂O, and (NH₄)₂HPO₄ (900 °C, 12 h).     

Studies on ion association. Calorimetric study of the formation of monoazido complexes of Ni(II), Zn(II) and Cd(II)

From rehydration experiments the hydrates Ba(OH)₂ · 8 H₂O, Ba(OH)₂ · 3 H₂O β-Ba(OH)₂, · 1 H₂O, and γ-Ba(OH)₂ · 1 H₂O have been found in the system Ba(OH)₂-H₂O. Thermoanalytical measurements (DTA, TG, DTG, high temperature X-ray diffraction, high temperature Raman scattering) on these hydrates are reported. Thermal decomposition of Ba(OH)₂ · 8 H₂O and Ba(OH)₂ · 3 H₂O always results in the formation of β-Ba(OH)₂ · 1 H₂O, the stable form of the monohydrates at ambient temperature. Dehydration of β- and γ-Ba(OH)₂ · 1 H₂O, both of which form anhydrous β-Ba(OH)₂ as the first product of decomposition, starts at 105 and 115°C, respectively. Single crystals of Ba(OH)₂ · 3 H₂O and γ-Ba(OH)₂ · 1 H₂O were prepared from Ba(OH)₂ · 8 H₂O meltings and from ethanolic solutions of Ba(OH)₂ , respectively. The crystal data are: Ba(OH)₂ · 3 H₂O (orthorhombic, Pnma): a = 764.0(2), b = 1140,3(5), c = 596.5(1) pm, Z = 4; γ-Ba(OH)₂ · 1 H₂O (monoclinic, P2₁/m or P2₁): a = 704.9(2), b = 418.4(1), c = 633.3(1) pm, β = 111.45(2)°, Z = 2.     

Kristallstrukturen des Sr(OH)2 · H2O,Ba(OH)2 · H2O (o.-rh. und mon.) und Ba(OH)2 · 3 H2O

Crystal Structures of Sr(OH)₂ · H₂O, Ba(OH)₂ · H₂O (o.-rh. and mon.), and Ba(OH)₂ · 3 H₂O The crystal structures of Ba(OH)₂ · 3 H₂O (Pnma, Z = 4), γ-Ba(OH)₂ · H₂O (P2₁/m, Z = 2) and the isotypic Sr(OH)₂ · H₂O and β-Ba(OH)₂ · H₂O (Pmc2₁, Z = 2) were determined using X-ray single crystal data. Ba(OH)₂ · 3 H₂O and Ba(OH)₂ · H₂O mon. crystallize in hitherto unknown structure types. The structure of Ba(OH)₂ · H₂O mon. is strongly related to that of rare earth hydroxides M(OH)₃ with space group P6₃/m (super group of P2₁/m). The metal-oxygen distances are significantly shorter for OH^? ions (mean Ba—O bond lengths of all hydroxides under investigation 278.1 pm) than for H₂O molecules (289.9 pm). Corresponding to other hydrates of ionic hydroxides, the water molecules form strong hydrogen bonds to adjacent OH^? ions whereas the hydroxide are not H-bonded.     

Thermoanalytical investigation of some alkaline earth hydroxide hydrates on application as latent heat storage materials

Owing to their high specific melting enthalpy and the range of the melting temperatures the alkaline-earth hydroxide hydrates Ba(OH)₂·8H₂O and Sr(OH)₂·8H₂O are promising latent heat storage materials. The investigations of the melting and solidification behaviour of Sr(OH)₂·8H₂O and its mixtures with Ba(OH)₂·8H₂O, which had been performed by means of DTA and DSC methods in the closed system with a constant gross composition lead to statements on the melting temperature and specific melting enthalpyvs. concentration. Theoretical storage densities of 532 MJ/m³ are obtained for the mixture of Ba(OH)₂·8H₂O and Sr(OH)₂·8H₂O (80/20) and a value of 655 MJ/m³ can be achieved for Sr(OH)₂·8H₂O. The kinetics of rehydration to the octahydrates has a great influence on the storage temperature and storage density.     

Standard enthalpy of formation of disodium hydrogen phosphate hexahydrate and sodium diphosphate

Commercial disodium hydrogen phosphate dodecahydrate (Na₂HPO₄·12H₂O) was used as a precursor for synthesizing disodium hydrogen phosphate hexahydrate (Na₂HPO₄·6H₂O) and sodium diphosphate (Na₄P₂O₇). The purity of the synthesized products was checked up by IR spectroscopy and X-ray diffraction. The heat of dissolution of these compounds, in acid solutions of several concentrations (w/w) of H₃PO₄ was measured in a C-80 SETARAM calorimeter. Many dilution and mixing processes were also realized in the calorimeter in order to get the standard enthalpy of formation of these products. The values obtained for the enthalpies of formation are: (?3210.5) and (?3516.5) kJ · mol^?1 for sodium diphosphate (Na₄P₂O₇) and disodium hydrogen phosphate hexahydrate (Na₂HPO₄·6H₂O), respectively.     

A System for Tracking Down Hydrogen Positions in Crystal Structures

Hydrogen conformations in [Ta₆Br₁₂(H₂O)₆]X₂ · trans — [Ta₆Br₁₂(OH)₄(H₂O)₂] · 18H₂O (X = Cl or Br), [Ta₆Br₁₂(H₂O)₆]₈ · (ZnBr₄)₈ · 96H₂O, Na₆[RuO₂{TeO₄(OH)₂}₂] · 16H₂O, and Na₅[Ag{TeO₄(OH)₂}₂] · 16H₂O were modeled from a set of simple rules. The systems are quite complex, but subsequent energy optimizations show that it is possible to make quite good predictions of where the hydrogen atoms are situated.     

Three 1-D molybdenum(V) phosphates with copper/nickel coordination cations

Three 1-D reduced molybdenum(V) phosphates, [Ni(OH)₂][Na₂(H₂O)₃]₂{Ni[(MoO₂)₆(OH)₃(HPO₄)₃(PO₄)]₂}?·?2C₆H₁₄N₂?·?2H₃O?·?5H₂O (1), [Ni(H₂O)₂][K(H₂O)₅]₂{Ni[(MoO₂)₆(OH)₃(HPO₄)₃(PO₄)]₂}?·?2C₆H₁₄N₂?·?2H₃O?·?4H₂O (2), and [Cu(H₂O)₂][Na(H₂O)₅]₂{Cu[(MoO₂)₆(OH)₃(HPO₄)₃(PO₄)]₂}?·?2C₆H₁₄N₂?·?2H₃O?·?4H₂O (3), have been hydrothermally synthesized and structurally characterized by single-crystal X-ray diffraction. The crystallographic analysis reveals that 1 is based on {Ni[Mo₆O₁₂(OH)₃(HPO₄)₃(PO₄)]₂} clusters connected through {[Ni(OH)₂][Na₂(H₂O)₃]₂} pentanuclear mixed-metal cluster units to yield unusual 1-D chains along the c-axis, which further form 3-D supramolecular networks via hydrogen-bonding. Compounds 2 and 3 are heterogeneous isostructural compounds. Both are built from M[Mo₆P₄]₂ (M?=?Ni or Cu) blocks as the structural motif combined with [MO₄(H₂O)₂] (M?=?Ni or Cu) octahedra to form 1-D chains, where M[Mo₆P₄]₂ (M?=?Ni or Cu) is bonded by [M′(H₂O)₅] (M′?=?K or Na). Furthermore, bulk carbon paste electrode modified with 1 (1-CPE) displays good electrocatalytic activity toward reduction of nitrite or bromate.     

An 17O nuclear quadrupole double resonance study of several crystal hydrates

Using the technique of double resonance with coupled multiplets (DRCM), ¹⁷O double resonance signals were detected in natural abundance from the H₂O molecule in the hydrates BeSO₄ · 4H₂O, AlCl₃ · 6H₂O, CH₃COOLi · 2H₂O, LiClO₄ · 3H₂O, Sr(OH)₂ · H₂O, Ba(OH)₂ · 8H₂O, LiBr · 2H₂O and MgSO₄ · 7H₂O.Using the DRCM technique approximate values for the HOH bond angle and the OH bond length were determined from the dipolar structure present on the ¹⁷O double resonance signals. A Townes and Dailey analysis was used to examine the small differences in the ¹⁷O quadrupole coupling constants and asymmetry parameters between these samples.     

Natural specimen of triple solid solution ettringite–thaumasite–chromate-ettringite

Three natural minerals of ettringite group were investigated by TG to refine their chemical composition. Two samples are ettringite Ca_5.97Mg_0.01Sr_0.02Al_1.99Cr_0.01(SO₄)₃(OH)₁₂·23.7H₂O and bentorite Ca_5.99Mg_0.01Cr_1.95Al_0.01Si_0.03(SO₄)_2.82·(CO₃)_0.20(OH)₁₂·19.4H₂O, but the third one Ca_5.99Na_0.01Al_1.38Si_0.62(SO₄)_2.49·(CrO₄)_0.36·(CO₃)_0.46(OH)₁₂·15.8H₂O has found to be a solid solution among ettringite, thaumasite, and chromate-ettringite, not registered yet as a new mineral species. Similar phase is well known in concrete formed with Cr⁶⁺ admixture, but is found for the first time as a natural compound. X-ray single-crystal investigation allowed us to refine the structure and support substitution (SO₄)^2? ? (CrO₄)^2? in natural minerals of ettringite group.     

Fabrication of mesoporous ZnO nanosheets from precursor templates grown in aqueous solutions

Mesoporous ZnO nanosheets were successfully prepared by pyrolytic transformation of zinc carbonate hydroxide hydrate, Zn₄CO₃(OH)₆·H₂O. The nanosheets were initially formed as assemblies on glass substrates during chemical bath deposition (CBD) in aqueous solutions of urea and zinc acetate dihydrate, zinc chloride, zinc nitrate hexahydrate, or zinc sulfate heptahydrate at 80°C. It was key to induce heterogeneous nucleation of Zn₄CO₃(OH)₆·H₂O by promoting a gradual hydrolysis reaction of urea and controlling the degree of supersaturation of zinc hydroxide species. Morphology of Zn₄CO₃(OH)₆·H₂O was largely influenced by the anions present in the CBD solutions. The Zn₄CO₃(OH)₆·H₂O nanosheets were transformed into wurtzite ZnO by heating at 300°C in air without losing the microstructural feature.     

Über kristalline Natriumhydroxogallate

About Crystalline Sodium Hydroxogallates Two crystalline sodium hydroxogallates 4,5 Na₂O · Ga₂O₃ · 13,5 H₂O ( I ) and 5 Na₂O · Ga₂O₃ · 8 H₂O ( II ), as well as a crystalline phase of the composition Na₂O · Ga₂O₃ · 4 H₂O · 2 NaCl ( III ) are described.     

Synthesis and physicochemical characterization of nanocrystalline chitosan-containing calcium carbonate apatites

The CaCl₂-(NH₄)₂HPO₄-NH₄HCO₃-(C₆H₁₁NO₄) _n -H₂O system at 25°C has been investigated by the solubility (Tananaev’s residual concentration) method and pH measurements. Coprecipitation conditions have been determined for nanocrystalline type A and B calcium carbonate apatites. Type A: Ca₁₀(PO₄)₆(CO₃) _x (OH)_{2 − 2x} · yC₆H₁₁NO₄ · zH₂O (x = 0.2, 0.5, 1.0; y = 0.1, 0.3, 0.5; z = 5.3−6.7); type B: Ca₁₀[(PO₄)_5.7(CO₃)_0.45]CO₃ · 0.3C₆H₁₁NO₄ · 9H₂O, and Ca₁₀[(PO₄)_5.55(CO₃)_0.675]CO₃ · 0.3C₆H₁₁NO₄ · 9.2H₂O. The solid phases have been characterized by chemical analysis, X-ray diffraction, thermogravimetric analysis, and IR spectroscopy.     

Untersuchung des einflusses der analysenbedingungen auf die zersetzung von 4MgCO3 ·Mg(OH)2 · 4H2O und die bildung von magnesit MgCO3

The processes, which influence the decomposition of 4MgCO₃ ·-Mg(OH)₂ · 4H₂O, could be determined by systematical variation of the analytical parameters. The original crystal structure exists in a wide temperature range during the decomposition. The formation of magnesite is a secondary reaction of the gaseous phase with the reaction product.H₂O and CO₂, are released simultaneously in different proportions during the decomposition to 500°C. Stoichiometric intermediates were not found. The original crystal structure collapsed, when the last H₂O escapes. The ratio of MgCO₃: MgO can be influenced by partial pressure of CO₂ in a wide range.     

Effect of hydrothermal and ultrasonic/hydrothermal treatment on the phase composition and micromorphology of yttrium hydroxocarbonate

The effect of hydrothermal and ultrasonic/hydrothermal treatment on the phase composition and micromorphology of yttrium hydroxocarbonates has been studied. The hydrothermal treatment of a suspension of amorphous yttrium hydroxocarbonate hydrate, Y(OH)CO₃ · 1.25H₂O, does not significantly alter the composition of the powder, while ultrasonication directly in the course of hydrothermal treatment under the same conditions yields crystalline yttrium hydroxocarbonate Y(OH)CO₃. The thermolysis of yttrium hydroxocarbonates Y(OH)CO₃ · xH₂O and Y(OH)CO₃ has been studied.     

A Ga‐MIL‐53‐type Framework based on 1,4‐Phenylenediacetate Showing Subtle Flexibility

The new MOF Ga‐MIL‐53‐PDA [Ga(OH)(O₂C‐C₈H₈‐CO₂)] · H₂O ( 1 ) was synthesized by a hydrothermal reaction of gallium nitrate, 1,4‐phenylenediacetic acid (H₂PDA) and sodium hydroxide at 100 °C for 24 h. The product is a structural analogue of the archetypical MIL‐53 framework. Its crystal structure was determined by Rietveld refinement of powder X‐ray diffraction (PXRD) data. Furthermore 1,4‐phenylenedipropionic acid (H₂PDP) was employed for further synthesis, which resulted in the dense layered coordination polymers [Ga₂(OH)₄(O₂C‐C₁₀H₁₂‐CO₂)] ( 2 ) and [Ga(OH)(O₂C‐C₁₀H₁₂‐CO₂)] ( 3 ), for which accurate structural models could be established. All compounds were fully characterized and tested regarding potential breathing behavior. Most remarkably, Ga‐MIL‐53‐PDA showed a subtle flexibility upon de/‐rehydration also confirming its porosity, but no drastic structural changes were observed.     

Metal Salts of Dinitro‐, Trinitropyrazole,and Trinitroimidazole

The syntheses of alkali and earth alkaline dinitropyrazolate (DNP), trinitropyrazolate (TNP), and trinitroimidazolate (TNI) salts are reported. Additionally, copper trinitroimidazolate was synthesized. Their characterization by NMR spectroscopy, mass spectrometry, elemental analysis, and vibrational spectroscopy is reported as well. Crystal structures of compound Ba(DNP)₂ ( 9 ), which crystallizes with one molecule of methanol and ethyl ether as well as of compounds Sr(TNP)₂ · 3H₂O ( 12 ), Ba(TNP)₂ · 3H₂O ( 13 ), and LiTNI · 3H₂O ( 14 ) were determined. The energetic and thermal properties were measured as well. Green‐ and red‐burning pyrotechnic formulations containing barium salts 9 and 13 as well as strontium salts 8 and 12 serving as colorants are tested. Additionally, formulations using Sr(TNP)₂ · 3H₂O ( 12 ) and Ba(TNP)₂ · 3H₂O ( 13 ) as the oxidizer and colorant at the same time were examined. The formulations were investigated with regard to their combustion behavior and performances such as burn time, dominant wavelength, spectral purity, luminous intensity, and luminous efficiency. The sensitivities towards ignition stimuli and the decomposition temperatures were determined as well.     

Controlling Complexation Behavior of Early Lanthanides via the Subtle Interplay of their Lewis Acidity with the Chemical Stability of 5,5'-(Azobis)tetrazolide

Two novel nitrogen-rich lanthanide compounds of 5,5'-(azo bis)tetrazolide (ZT) were synthesized and structurally characterized. The dinuclear, isostructural compounds [Ce₂(ZT)₂CO₃(H₂O)₁₂] · 4 H₂O ( 1 ) and [Pr₂(ZT)₂CO₃(H₂O)₁₂] · 4H₂O ( 2 ) were synthesized via two independent routes. Compound 1 was obtained after partial Lewis acidic decomposition of ZT by Ce^IV in aqueous solution of (NH₄)₂Ce(NO₃)₆ and Na₂ZT. Compound 2 was obtained by crystallization from aqueous solutions of Pr(NO₃)₃, Na₂ZT, and Na₂CO₃. By X-ray diffraction analysis at 200 K, it was found that the trivalent lanthanide cations are bridged by a bidentate carbonato ligand and each cation is further coordinated by six H₂O ligands and one ZT ligand thus being ninefold coordinated.     

Darstellung und Kristallstrukturen der ersten Alkalimetall‐hexacarbonatooxotetraberyllate: K6[Be4O(CO3)6] · 7 H2O und K6[Be4O(CO3)6]

Preparation and Crystal Structures of the first Alkalimetall‐hexacarbonato‐oxotetraberyllates: K₆[Be₄O(CO₃)₆] · 7 H₂O and K₆[Be₄O(CO₃)₆] K₆[Be₄O(CO₃)₆] · 7 H₂O has been prepared by dissolving freshly precipitated Be(OH)₂ in an aqueous KHCO₃ solution. After enriching the title compound by extraction with ethanol the heptahydrate crystallizes from the organic phase (triklin, P1¯ (No. 2) with a = 951, 01(11), b = 958, 45(12), c = 1601, 7(2) pm, α = 79, 253(13)°, β = 78, 943(12)°, γ = 65, 119(12)°, V_EZ = 1290, 6(3)·10⁶ pm³, Z = 2). Thermal decomposition forms rhombohedral crystals of the anhydrous compound (trigonal‐rhombohedric, R3¯ (No. 148) with a = 1416, 42(6), c = 1704, 5(1) pm, V_EZ = 2961, 4(3)·10⁶ pm³, Z = 6).