Evacuated Quartz Ampoules Research Articles

ChemInform Abstract: Thermoelectric Properties of p‐Type Semiconducting NaB5C with Hexaboride‐Type Structure, Compared to Layered MB2C2 (M: La, Ce).

AbstractNaB5C is prepared by solid state reaction of the elements in the molar ratio of Na:B:C = 6:5:1 (sealed boronated Ta tubes in evacuated quartz ampoule, 1000 °C, 6‐8 h) and densified by high‐pressure spark plasma sintering (923 K, 100 MPa, 90 min).

Superconductivity at 4.4 K in PdTe2 Chains of a Ta-Based Compound

Superconductivity in PdTe2 heavy transition metal-based compounds is a rapidly developing field in condensed matter physics community. Here, we report superconductivity in a nominal ternary telluride Ta2Pd0.97Te6 compound, which is synthesized in sealed evacuated quartz ampoule. The resultant compound is crystallized in layered monoclinic Ta4Pd3Te16 phase with space group C2/m, having lattice parameters a = 21.304(6)Å, b = 3.7365(7)Å and c = 17.7330Å with β = 120.65(1)∘. Both transport and magnetic measurements demonstrated bulk superconductivity at 4.4 K in studied polycrystalline sample. The metallic normal state conductivity can be well ascribed to Fermi liquid behaviour. The superconducting upper critical field of the compound is determined to be 5.5 T based on magnetoresistivity measurements.

ChemInform Abstract: ZrSe3‐Type Variant of TiS3: Structure and Thermoelectric Properties.

AbstractA dense TiS3 sample is prepared by solid state reaction of a 1:4 mixture of Ti and S (evacuated quartz ampoule, 600 °C) followed by spark plasma sintering in vacuum and subsequent hot press molding (600 °C, 50 MPa, 10 min).

Preparation and characterization of new phases in Na-(U0.5Pu0.5)-Mo-O and Na-(Th x U1−x )-Mo-O (x = 0.5 and 0.8) systems by X-ray and thermal methods

Abstract Na2(Th x U1−x )(MoO4)3 and Na4(Th x U1−x )(MoO4)4 (x = 0.5 and 0.8) were synthesized, by reacting (Th x U1−x )(MoO4)2 with Na2MoO4 in appropriate molar ratios at 873 K in an evacuated quartz ampoule for 25 h. While Na2(U0.5Pu0.5)(MoO4)3 and Na4(U0.5Pu0.5)(MoO4)4 were synthesized, by reacting (U0.5Pu0.5)(MoO4)2 with Na2MoO4 in appropriate molar ratios at 873 K in argon atmosphere for 45 h. The crystal structure of these compounds were derived from powder XRD data in a tetragonal system (space group: I41/a) by Rietveld profile method. Thermogravimetric curves of Na2(Th x U1−x )(MoO4)3 and Na4(Th x U1−x )(MoO4)4 did not show any weight changes up to 973 K in helium atmosphere. High temperature X-ray diffraction (HTXRD) studies of Na2(Th x U1−x )(MoO4)3 and Na4(Th x U1−x )(MoO4)4 in vacuum showed positive thermal expansion in the temperature range of 298 to 873 K.

ChemInform Abstract: Crystal Structure and Physical Properties of Ternary Phases Around the Composition Cu5Sn2Se7 with Tetrahedral Coordination of Atoms.

AbstractPolycrystalline Cu5Sn2Se7 is prepared from the elements (evacuated quartz ampoule, 1173 K, 12 h).

ChemInform Abstract: Comparison of Magnetocaloric Properties of the Mn2‐xFexP0.5As0.5 (x = 1.0 and 0.7) Compounds.

AbstractMn1.3Fe0.7P0.5As0.5 (I) and MnFeP0.5As0.5 (II) are prepared by melting stoichiometric amounts of Mn2P and Fe2As (evacuated quartz ampoule, 1473 K, 2 d) followed by Bridgman directional crystallization (1000 K, 1 d).

ChemInform Abstract: First Single Crystal Growth and Structural Analysis of Superconducting Layered Bismuth Oxyselenide; La(O,F)BiSe2.

AbstractSingle crystals of La(O,F)BiSe2 are grown by a CsCl flux method involving powders of La, Bi2O3, BiF3, Bi, Bi2Se3, and Se in the molar ratio of 6:1:1:1:1:9 corresponding to LaO0.5F0.5BiSe2 (evacuated quartz ampoule, 900 °C, 2 h; controlled cooling).

ChemInform Abstract: Thermal Expansion and Phase Transitions of α‐AlF3.

Abstractα‐AlF3 is prepared by thermal treatment of anhydrous AlF3 (Ni tube in evacuated quartz ampoule, 1338 K, 72 h).

ChemInform Abstract: Synthesis and Crystal Structure of the New Indide La8Co2In3.

AbstractSingle crystals of the title compound are grown from an arc‐melted composition of La55Co22.5In22.5 by annealing under argon (Ta foil in evacuated quartz ampoule, 1.

ChemInform Abstract: Synthesis and Crystal Growth of Tetragonal β‐Fe1.00Se.

AbstractPlate‐shaped single crystals of tetragonal β‐Fe1.00Se are grown from polycrystalline material by chemical vapor transport with AlCl3 as transport additive (evacuated quartz ampoule, temp.

AIn2S4(A= Mn-Ni): New synthesis methods and structural characterization

Ternary chalcogenides with the spinel crystal structure have been widely studied for the last 60 years. These compounds are more covalent and allow different interactions between ions when compared to corresponding oxides while maintaining the versatility of the spinel structure. Particularly, spinels with formula AIn2S4(A= Mn-Ni) are found to be semiconductors with a large band gap (~2.0 eV), showing mainly antiferromagnetic interactions at temperatures below 100 K. These properties are dependent on the distribution of cations between octahedral and tetrahedral sites in the structure and also on the synthesis method. Syntheses of these compounds have been extensively reported, involving long heating periods of mixtures of elements or binary sulfides inside evacuated quartz ampoules, lasting for up to two weeks or longer. We report two new, faster synthesis methods for polycrystalline samples of indium thiospinels avoiding evacuated ampoules. Polycrystalline FeIn2S4and MnIn2S4samples were synthesized from stoichiometric mixtures of binary sulfides, heating in a constant gas flow of 1% H2in Ar at 1073 K for 6 and 24 hours respectively. Polycrystalline samples of FeIn2S4, CoIn2S4and NiIn2S4have also been synthesized in a piston-cylinder press, from stoichiometric mixtures of the binary sulfides, at a pressure of 3.5 GPa at 1173 K for 1 hour. From x-ray powder diffraction data all crystal structures were refined by means of Rietveld analysis. Refined cell parameters are in agreement with previous reports. Different degrees of inversion were obtained for each sample. NiIn2S4and both FeIn2S4samples are in accordance with previous reports, while MnIn2S4and CoIn2S4differ from reported values [1]. FeIn2S4and MnIn2S4synthesized in H2/Ar flux were characterized by Raman spectroscopy to further assess cation distribution. In addition, their thermal stability in air was tested by Thermogravimetric Analysis (TGA).

ChemInform Abstract: A New Semiconducting Quaternary Mixed Halogenide: Pentathallium Dimercury Pentabromide Tetraiodide, Tl5Hg2Br5I4.

AbstractTl5Hg2Br5I4 is prepared by fusion of TlBr and HgI2 in a 5:2 molar ratio (evacuated quartz ampoule, 770 K, 6 h, cooling rate of 10 K/h).

Effects of post-annealing and cobalt co-doping on superconducting properties of (Ca,Pr)Fe2As2 single crystals

In order to clarify the origin of anomalous superconductivity in (Ca,RE)Fe2As2 system, Pr doped and Pr,Co co-doped CaFe2As2 single crystals were grown by the FeAs flux method. These samples showed two-step superconducting transition with Tc1=25–42K, and Tc2<16K, suggesting that (Ca,RE)Fe2As2 system has two superconducting components. Post-annealing performed for these crystals in evacuated quartz ampoules at various temperatures revealed that post-annealing at ∼400°C increased the c-axis length for all samples. This indicates that as-grown crystals have a certain level of strain, which is released by post-annealing at ∼400°C. Superconducting properties also changed dramatically by post-annealing. After annealing at 400°C, some of the co-doped samples showed large superconducting volume fraction corresponding to the perfect diamagnetism below Tc2 and high Jc values of 104–105Acm−2 at 2K in low field, indicating the bulk superconductivity of (Ca,RE)Fe2As2 phase occurred below Tc2. On the contrary, the superconducting volume fraction above Tc2 was always very small, suggesting that 40K-class superconductivity observed in this system is originating in the local superconductivity in the crystal.

ChemInform Abstract: Synthesis and Structural Characterization of Cs2Ga2Se5.

AbstractCs2Ga2Se5 is obtained by thermal decomposition of CsN3 in the presence of stoichiometric amounts of GaSe and Se (evacuated quartz ampoule, 873 K, several days).

ChemInform Abstract: Synthesis, Crystal Structure and Characterization of the Copper Iron Phosphate Cu8Fe2O5(PO4)4.

AbstractThe phase diagram of the CuO—Fe2O3—P2O5 system is given.

Rapid Solution Chemistry Approach for Synthesizing Mo6S8 Chevrel Phase Cathode for Rechargeable Magnesium Battery

Recently, energy storage systems based on bivalent Mg2+ ions spurred considerable interest as a promising high energy density alternative battery system among others [1, 2]. Magnesium (Mg) has several positive attributes which set it apart from Li-ion battery system. It is environmental friendly, cost effective (~$ 2700/ton for Mg compared to $64,000/ton for Li) and is relatively more abundant in the earth’s crust (~13.9% Mg compared to ~0.0007% of Li) compared to hitherto used popular systems. Additionally, magnesium is more stable in air compared to lithium, and is theoretically capable of rendering higher volumetric capacity (3832 mAh/cc for Mg vs. 2062 mAh/cc for Li).In the year 2000, Aurbach and coworkers successfully demonstrated a prototype Mg cell using the Mo6S8 Chevrel Phase a new class of cathodes, Mg anode, and the 0.25 molar Mg(AlCl2EtBu)2/tetrahydrofuran electrolyte where Mg2+ can be (de)intercalated reversibly ~ 1-1.2V offering an energy density ~ 60 Whkg-1 up to 2000 cycles with little fade in capacity [3]. Relatively fast and easy intercalation of Mg2+ ions at room temperature makes Mo6S8 a model cathode for magnesium battery. However, Mo6S8 is a metastable phase at room temperature, and is therefore indirectly stabilized when generated via leaching of the metal from the thermodynamically stable ternary Chevrel phase compounds, MxMo6T8 (M = metal, T = S, Se, Te) [4]. Typical synthesis approach of CuxMo6S8 (CuxCP) requires high temperature reactions of elemental blends in an evacuated quartz ampoules (EQA) at ~1150○C for 7 days [3] or by a molten salt (MS) route using Mo-MoS2-CuS reactants in a KCl salt, and heat treating the reaction mixtures at ~850○C for 60h in an Ar atmosphere [5]. Both approaches are extremely tedious and require chemical leaching either in 6 molar HCl/H2O or 0.2 molar I2/acetonitrile solutions for several days at room temperature for complete removal of copper [5].Herein, we report a rapid solution chemistry route (total manufacturing time required for the synthesis of CP is only ~12h) for the synthesis of Mo6S8 following modification of a previous report [6] which only reported the synthesis of the Cu analog of the Mo6S8 phase. The structural analysis (XRD and SEM) shows the formation of phase-pure micrometer (~1-1.5 mm) size cuboidal shaped Cu2Mo6S8 and Mo6S8 crystals [See Fig. 1(a-d)]. Electrochemical performance of the resultant Mo6S8 cathode exhibits a discharge capacity ~ 76 mAhg-1 with excellent capacity retention up to ~100 cycles, when cycled at a current rate of 20mA/g (~C/6). The excellent cyclability, rate capability and high Coulombic efficiency (~99.3% at ~1.C rate) of the Mo6S8 cathode, renders the solution chemistry route a convenient approach for synthesizing the electrochemically active model Chevrel phase Mo6S8. Results of these studies will be presented and discussed.

Synthesis, Crystal Structure and Characterization of the Copper Iron Phosphate Cu8Fe2O5(PO4)4

AbstractThe system CuO‐Fe2O3‐P2O5 has been investigated by means of the solid state reaction between CuO, Fe2O3 and (NH4)2HPO4 in quartz crucibles at 900 °C. The powder samples were characterized by X‐ray diffraction, IR spectroscopy and TG/DTA. Single crystals of a new quaternary phase Cu8Fe2P4O21 were achieved by cooling from the melt of the compound in a sealed, evacuated quartz ampoule. Cu8Fe2O5(PO4)4 crystallizes in the monoclinic space group C2/m (No 12) with a = 15.9733(8) Å, b = 5.9438(3) Å, c = 9.5530(5) Å, β = 113.76(1)°, Z = 2. The three‐dimensional framework consists of [FeO6] octahedra, three different [CuO5] polyhedra and [PO4] tetrahedra. Cu8Fe2P4O21 exhibits an incongruently melting point at 945 °C.

ChemInform Abstract: Ternary Antimonides RE4T7Sb6 (RE: Gd—Lu; T: Ru, Rh) with Cubic U4Re7Si6‐Type Structure.

AbstractThe title compounds are prepared by arc‐melting of the elements followed by annealing (evacuated quartz ampoules, 1370 K, 1 h).

ChemInform Abstract: Magnetic Properties and Magnetocaloric Effect of GdCr2Si2 Compound under Hydrostatic Pressure.

AbstractGdCr2Si2 is prepared by arc melting of stoichiometric amounts of the elements followed by annealing (evacuated quartz ampoules, 1073 K, 10 d).

ChemInform Abstract: Effect of Heavy Doping of Nickel in Compound Mo3Sb7: Structure and Thermoelectric Properties.

AbstractPolycrystalline heavily Ni‐doped Mo3Sb7 phases (NixMo3‐yNiySb7, x + y = 0.00, 0.15, 0.20, 0.25 and 0.30) are prepared by solid state reaction of stoichiometric mixtures of the elements (evacuated quartz ampoules, 1043 K, 5 d).