Your search keyword '"I.Yu. Zavaliy"' showing total 30 results

1. Solid gas and electrochemical hydrogenation properties of the R1-xR’xMgNi4-yCoy (R, R’ = Y, La, Ce) alloys

Author

Yu. Verbovytskyy, V. V. Berezovets, P. Ya. Lyutyy, and I.Yu. Zavaliy

Subjects

magnesium compoun, crystal structure, Materials science, Hydrogen, metal hydride electrodes, chemistry.chemical_element, Sintering, Crystal structure, Condensed Matter Physics, Electrochemistry, lcsh:QC1-999, hydrogen storage, Hydrogen storage, rare earth compounds, chemistry, Physical chemistry, General Materials Science, Orthorhombic crystal system, Physical and Theoretical Chemistry, Cobalt, lcsh:Physics, Bar (unit)

Abstract

New R1-xR’xMgNi4-yCoy (R, R’ = Y, La, Ce; x = 0.5; y = 0, 1, 2) alloys have been synthesized by powder sintering method, and their crystal structure and hydrogen storage properties have been studied. X-ray diffraction analysis showed that R1-xR’xMgNi4-yCo alloys belong to the MgCu4Sn-type structure. The synthesized alloys absorb hydrogen at room temperature and hydrogen pressure 0.1-10 bar. For some of the studied compounds, the formation of hydrides with cubic and orthorhombic structures was found. Highest hydrogen content is found for the Co-rich compounds: La0.5Y0.5MgNi2Co2H5.18 and La0.5Ce0.5MgNi2Co2H6.48. Electrochemical studies showed that Y-based electrode materials exhibit better electrochemical performance comparing with Ce-doped ones. Highest discharge capacity of 292 mА∙h/g was observed for La0.5Y0.5MgNi3Co, but the best cyclic stability after 50th cycle of 92% was seen for La0.5Y0.5MgNi2Co2. Additionally, obtained results of the electrochemical properties were compared with related compounds. High rate dischargeability of Co-free alloys at I = 1 A/g were twice higher than ones containing cobalt.

Published

2020

2. Solid-gas and electrochemical hydrogenation properties of the La1-Nd MgNi4-Co alloys

Author

I.Yu. Zavaliy, H. Drulis, A. Hackemer, V.V. Shtender, P. Ya. Lyutyy, and Yu. Verbovytskyy

Subjects

Materials science, Mechanical Engineering, Alloy, Metals and Alloys, Sintering, 02 engineering and technology, Crystal structure, engineering.material, 010402 general chemistry, 021001 nanoscience & nanotechnology, Electrochemistry, 01 natural sciences, 0104 chemical sciences, Hydrogen storage, Volume (thermodynamics), Chemical engineering, Mechanics of Materials, Desorption, Materials Chemistry, engineering, Chemical stability, 0210 nano-technology

Abstract

New La1-xNdxMgNi4-yCoy (x = 0, 0.5, 1; y = 0, 0.5, 1) alloys have been synthesized by powder sintering method, and their crystal structure and hydrogen storage properties have been systematically studied. X-ray diffraction analysis showed that La1-xNdxMgNi4-yCoy alloys belong to the MgCu4Sn-type structure. Hydrogen storage capacity of the alloys is in the 1.1–1.7 wt % H range. The alloy hydrides of are stable in air at room temperature. XRD studies have shown that hydrides retain the crystalline structure of the starting alloy while increasing the cellular volume by 15–23%. Pressure–composition–temperature (PСT) measurements demonstrated that thermodynamic stability of hydrides decreases with an increasing Nd content whereas increasing Co content in the alloys leads to the increase their stability which is demonstrated by the lowering desorption plateau pressure with Co content. Electrochemical studies showed that La-rich electrode materials exhibit the maximum discharge capacity (300–330 mAh/g), but Nd-doped ones show better cyclic stability.

Published

2018

3. Phase equilibria in the Nd–Mg–Co system at 300 and 500 °C, crystal structure and hydrogenation behavior of selected compounds

Author

Roman V. Denys, Volodymyr Pavlyuk, Valérie Paul-Boncour, Bernard Marciniak, V.V. Shtender, I.Yu. Zavaliy, O. Ya. Zelinska, and Ewa Rozycka-Sokolowska

Subjects

Materials science, Hydrogen, Hydride, Mechanical Engineering, Metals and Alloys, Thermal desorption, chemistry.chemical_element, Disproportionation, 02 engineering and technology, General Chemistry, Electron microprobe, Crystal structure, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Hydrogen storage, Crystallography, chemistry, Mechanics of Materials, Materials Chemistry, 0210 nano-technology, Solid solution

Abstract

The isothermal sections of the Nd–Mg–Co phase diagram at 300 and 500 °C have been constructed on the basis of X-ray diffraction (XRD), Wavelength Dispersive Spectrometry (WDS) and Electron Probe Micro Analyzer (EPMA) analysis. The existence of two ternary compounds Nd 4 Mg 3 Co 2 (own structure type) and Nd 4 MgCo (Gd 4 RhIn type) was confirmed. The latter has homogeneity range defined as Nd 4- x Mg 1+ x Co with 0 ≤ x ≤ 0.2 at 300 °С and 0 ≤ x ≤ 0.3 at 500 °С. Four new ternary compounds were identified in this work: Nd 23- x Mg 4+ x Co 7 (Pr 23 Mg 4 Ir 7 type; −1.5 ≤ x ≤ 0.1 at 300 °С and −0.6 ≤ x ≤ 0.3 at 500 °С); NdMg 2 Co 9 (YIn 2 Ni 9 type), ∼Nd 77 Mg 14 Co 9 (cubic) and ∼Nd 56 Mg 6 Co 38 (unknown crystal structure). Two binary compounds, NdCo 2 and NdCo 3 , were found to dissolve significant amount of Mg with the formation of substitutional solid solutions Nd 1- x Mg x Co 2 (MgCu 2 type; x ≤ 0.1 at 300 °С and x ≤ 0.15 at 500 °C) and Nd 1- x Mg x Co 3 (PuNi 3 type; x ≤ 0.33 at 300 °С and x ≤ 0.5 at 500 °C), respectively. The Nd 4 Mg 3 Co 2 , Nd 4- x Mg 1+ x Co, Nd 23- x Mg 4+ x Co 7 and Nd 1- x Mg x Co 2 compounds irreversibly absorb hydrogen at room temperature and pressure 1–10 bar to form crystalline or amorphous hydrides with hydrogen content 1.6–2.1 wt. %. Hydrogen thermal desorption from these hydrides in vacuum results in their disproportionation with formation of binary NdH 2 hydride. The Nd 1- x Mg x Co 3 (0 ≤ x ≤ 0.5) alloys reversibly absorb up to 1.3 wt. % of hydrogen. NdMg 2 Co 9 compound has small hydrogenation capacity, absorbing only 0.5 wt. % at room temperature and hydrogen pressure 185 bar.

Published

2017

4. Crystal structure, hydrogen absorption-desorption behavior and magnetic properties of the Nd3−Mg Co9 alloys

Author

I.Yu. Zavaliy, Roman V. Denys, Daniel D. Taylor, Valérie Paul-Boncour, V.V. Shtender, and Yu. Verbovytskyy

Subjects

Materials science, Hydrogen, Mechanical Engineering, Metals and Alloys, chemistry.chemical_element, 02 engineering and technology, Crystal structure, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, chemistry.chemical_compound, Magnetization, Hydrogen storage, Crystallography, chemistry, Ferromagnetism, Octahedron, Mechanics of Materials, Ternary compound, Materials Chemistry, Curie temperature, 0210 nano-technology

Abstract

New Nd 3− x Mg x Co 9 alloys have been synthesized by powder sintering method and their crystal structure, hydrogen storage and magnetic properties have been systematically studied. X-ray diffraction analysis showed that Nd 3− x Mg x Co 9 ( x ≤ 1.5) alloys belong to the PuNi 3 -type structure and NdMg 2 Co 9 is an individual ternary compound with YIn 2 Ni 9 -type structure. Hydrogen storage capacity of the PuNi 3 -type Nd 3− x Mg x Co 9 alloys is in the range 1.1–1.6 wt % H at room temperature, while for NdMg 2 Co 9 it is below 0.5 wt % H. PСT measurements demonstrated that thermodynamic stability of hydrides decrease with increasing Mg content. Hydrides of the alloys with lower Mg content ( x ≤ 1.0) are stable in air at room temperature. XRD study of these hydrides showed preserved PuNi 3 -type structure with hydrogen-induced volume expansion 16.7–24%. The positions of hydrogen atoms were determined by neutron powder diffraction study of Nd 2 MgCo 9 D 10 . In the Nd 2 MgCo 9 D 10 structure D atoms partially occupy four types of interstices, including octahedral Nd 2 Co 4 sites, tetrahedral Nd 2 Co 2 sites and two types of trigonal bipyramids (Nd,Mg) 3 Co 2 . Electrochemical investigations of the Nd 2 MgCo 9 electrode demonstrated rather low discharge capacity, 100 mAh/g, which is about 30% of its theoretical capacity. Magnetic measurements have shown that Nd 2 MgCo 9 is ferromagnetic with high Curie temperature (T C = 633 K) and spin reorientation at 225 K, its hydrogenation causes a significant decrease of the magnetization.

Published

2017

5. Synthesis and Structure of Ni-Based Nanopowders

Author

Yu. Verbovytskyy, Yu.O. Kulyk, I.Yu. Zavaliy, A. R. Kytsya, and P.Yu. Zavalij

Subjects

Diffraction, Range (particle radiation), Nickel, Materials science, chemistry, Chemical engineering, Small-angle X-ray scattering, Sem analysis, chemistry.chemical_element, Nanoparticle, Crystal structure, Crystallite

Abstract

Ni and Ni-Cu,Co nanopowders have been synthesized by chemical reduction method. It was demonstrated early that hydrogenation properties are critically dependent from the structure of the particles. Therefore the crystal structure of Ni-based nanopowders has been studied precisely by SEM, XRD and SAXS methods. X-ray diffraction and SEM analysis showed that the size of the obtained nickel nanoparticles covered the range from 20 to 200 nm. The particles consist from crystallites, which are characterized by the size about 5–20 nm. The complicated structure of the particles was confirmed by SAXS method.

Published

2018

6. Phase equilibria in the Tb-Mg-Co system at 500°C, crystal structure and hydrogenation properties of selected compounds

Author

O. Ya. Zelinska, I.Yu. Zavaliy, V.V. Shtender, Volodymyr Pavlyuk, Roman V. Denys, and Valérie Paul-Boncour

Subjects

Hydride, Chemistry, Inorganic chemistry, Thermal desorption, Crystal structure, Condensed Matter Physics, Electronic, Optical and Magnetic Materials, Inorganic Chemistry, Hydrogen storage, Phase (matter), Materials Chemistry, Ceramics and Composites, Physical chemistry, Physical and Theoretical Chemistry, Ternary operation, Phase diagram, Solid solution

Abstract

The isothermal section of the Tb–Mg–Co phase diagram at 500 °C has been built on the basis of XRD analysis of forty samples prepared by powder metallurgy. The existence of two ternary compounds Tb4Mg3Co2 and Tb4MgCo was confirmed. The formation of two solid solutions, Tb1−xMgxCo3 (0≤x≤0.4) and Tb1-−xMgxCo2 (0≤x≤0.6), was found for the first time. It is shown that Tb5Mg24 also dissolves a small amount of Co. Other binary compounds do not dissolve the third component. The Tb4MgCo and TbMgCo4 compounds form hydrides (12.7 and 5.3 at.H/f.u. capacity, respectively) that retain the original structure of metallic matrices. Upon thermal desorption the Tb4MgCoH12.7 hydride was stable up to 300 °C and disproportionated at higher temperature. Two other hydrides, Tb4Mg3Co2H∼4 and Tb2MgCo9H12, are unstable in air and decompose into the initial compounds.

Published

2015

7. Hydrogenation behavior of the R4MgCo (R=Y, La, Nd, Tb) compounds

Author

V.V. Shtender, Roman V. Denys, A.B. Riabov, I.Yu. Zavaliy, and Valérie Paul-Boncour

Subjects

Chemistry, Inorganic chemistry, Thermal desorption, Analytical chemistry, Disproportionation, Crystal structure, Condensed Matter Physics, Electronic, Optical and Magnetic Materials, Inorganic Chemistry, Metal, Matrix (chemical analysis), Hydrogen storage, visual_art, Desorption, Phase (matter), Materials Chemistry, Ceramics and Composites, visual_art.visual_art_medium, Physical and Theoretical Chemistry

Abstract

The hydrogen absorption properties of the R 4 MgCo compounds ( R =Y, La, Nd, Tb; str. type Gd 4 RhIn; sp.gr. F 4 ¯ 3 m ) have been studied for the first time. It was shown that their hydrogen storage capacity reaches about 2 wt%. At low pressure hydrogenation and moderately elevated temperatures the formed hydrides preserve the original structure of the metallic matrix. The crystal structure of the R 4 MgCoH x hydrides have been determined by XRD. Experimental hydrogen storage capacity (12 at.H/f.u. for Y 4 MgCo) is in good agreement with the theoretically calculated models, which allow also to estimate the distribution of H-atoms in metal lattice. TDS and DSC experiments demonstrated the multistep desorption process. XRD studies of the Tb 4 MgCoH x sample after TDS demonstrated the formation of TbH 2 as the main phase and disproportionation of the parent compound.

Published

2015

8. Effect of Co substitution on hydrogenation and magnetic properties of NdMgNi4 alloy

Author

Yu. Verbovytskyy, Roman V. Denys, V.V. Shtender, Valérie Paul-Boncour, and I.Yu. Zavaliy

Subjects

Hydrogen, Chemistry, Hydride, Mechanical Engineering, Inorganic chemistry, Metals and Alloys, chemistry.chemical_element, Crystal structure, Paramagnetism, Nickel, Crystallography, chemistry.chemical_compound, Mechanics of Materials, Ternary compound, Materials Chemistry, Orthorhombic crystal system, Cobalt

Abstract

The influence of Co substitution on the structural and magnetic properties of NdMgNi 4− x Co x ( x ⩽ 3) alloys and their hydrides has been investigated. The formation of NdMgCo 4 compound has not been observed. The gas hydrogenation of these alloys resulted in the formation of NdMgNi 4 H 4 , NdMgNi 3 CoH 4.8 , NdMgNi 2 Co 2 H 5.6 and NdMgNiCo 3 H 6.2 hydrides. Transformation from cubic into orthorhombic structure upon hydrogenation has been confirmed for NdMgNi 4 H 4 hydride, whereas it has been found that Co-containing hydrides preserved the parent cubic structure. PC diagrams at 50 °C for NdMgNi 4− x Co x –H 2 ( x = 0, 2, 3) showed only one absorption/desorption plateau, which equilibrium pressure decrease as the cell volume increase. The NdMgCu 4 ternary compound has been synthesized, but it does not interact with hydrogen under normal conditions. Electrochemical investigations demonstrated that substitution of the nickel atoms by the cobalt ones in NdMgNi 4 does not significantly influence on the maximum discharge capacity (244–261 mA h/g) and all alloys are characterized by high cyclic stability. NdMgNi 4 and its hydride display a Pauli paramagnet behavior. NdMgNi 2 Co 2 displays a magnetic order below 50 K whereas its hydride shows a Pauli paramagnet behavior similar to that of NdMgNi 4 H 4 .

Published

2015

9. Hydrogenation properties and crystal structure of YMgT4 (Т=Co, Ni, Cu) compounds

Author

I.Yu. Zavaliy, Valérie Paul-Boncour, V.V. Shtender, A.B. Riabov, and Roman V. Denys

Subjects

Materials science, Hydrogen, Hydride, Magnesium, Mechanical Engineering, Cell volume, Metals and Alloys, chemistry.chemical_element, Crystal structure, Hydrogen storage, chemistry, Mechanics of Materials, Materials Chemistry, Physical chemistry, Ternary operation

Abstract

New two ternary YMgCo4 and YMgCu4 and one quaternary YMgCo2Ni2 compounds have been synthesized by mechanical alloying with further annealing. The hydrogenation capacity of YMgCo4 reaches 6.8 at. H/f.u. The Pressure-Composition-Temperature studies of YMgCo4–H2 and YMgNi4–H2 systems revealed that introduction of magnesium, accompanied by shrinking of the unit cell, decreases the stability of hydrides comparing to binary YCo2 and YNi2 compounds. The values of heat and entropy of the YMgCo4H6.8 hydride formation were calculated: ΔH = −27.9 ± 0.8 kJ mol–1 H2 and ΔS = −93.4 ± 2.6 J mol−1 H2 K−1. The YMgCo2Ni2–H2 system shows intermediate thermodynamic properties compared to the ternary hydrides (ΔH = −28.8 ± 0.2 kJ mol–1 H2 and ΔS = −117.6 ± 2.4 J mol–1 H2 K−1). The YMgCo4H6.8 and YMgCo2Ni2H4.9 hydrides keep the cubic structure of the parent compounds with a cell volume expansion of 23 and 14.4% respectively. It is shown that the YMgCu4 compound does not interact with hydrogen under normal conditions.

Published

2014

10. Crystal structure analysis of the Ti3ZrFe2O0.3D6.4 and TiZr3Fe2O0.3D7.5 deuterides

Author

A.В. Riabov, P. Ya. Lyutyy, I.Yu. Zavaliy, I.V. Koval’chuck, and Roman V. Denys

Subjects

Crystallography, Materials science, General Medicine, Crystal structure

Published

2014

11. New CeMgCo4 and Ce2MgCo9 compounds: Hydrogenation properties and crystal structure of hydrides

Author

I.V. Koval’chuk, A.B. Riabov, I.Yu. Zavaliy, Roman V. Denys, and Radovan Černý

Subjects

Hydrogen, Hydride, Neutron diffraction, Intermetallic, chemistry.chemical_element, ddc:500.2, Crystal structure, Hydrogen storage, Condensed Matter Physics, Electronic, Optical and Magnetic Materials, Inorganic Chemistry, Crystallography, chemistry, Interstitial defect, X-ray crystallography, Pressure–Composition–Temperature relationships, Materials Chemistry, Ceramics and Composites, Metal hydride, Magnesium compounds, Physical and Theoretical Chemistry

Abstract

Two new ternary intermetallic compounds, CeMgCo4 (C15b pseudo-Laves phase, MgCu4Sn type) and Ce2MgCo9 (substitution derivative of PuNi3 type) were synthesized by mechanical alloying method. The structural and hydrogenation properties of these compounds were studied by X-ray diffraction and Pressure–Composition–Temperature measurements. Both compounds absorb hydrogen at room temperature and pressures below 10 MPa forming hydrides with maximum compositions CeMgCo4H6 and Ce2MgCo9H12. Single plateau behavior was observed in P–C isotherm during hydrogen absorption/desorption by Ce2MgCo9 alloy. The CeMgCo4–H2 system is characterized by the presence of two absorption/desorption plateaus corresponding to formation of β-CeMgCo4H4 and γ-CeMgCo4H6 hydride phases. The structure of β-hydride CeMgCo4H(D)4 was determined from X-ray and neutron powder diffraction data. In this structure initial cubic symmetry of CeMgCo4 is preserved and hydrogen atoms fill only one type of interstitial sites, triangular MgCo2 faces. These positions are occupied by 70% and form octahedron around Mg atom with Mg–D bond distances 1.84 Å.

Published

2012

12. Hydrogenation of Ti4-xZrxFe2Oy alloys and crystal structure analysis of their deuterides

Author

R.G. Delaplane, A.В. Riabov, I.V. Koval’chuck, Roman V. Denys, and I.Yu. Zavaliy

Subjects

Crystallography, Materials science, General Medicine, Crystal structure

Published

2009

13. Crystal structure of κ-Hf9Mo4SiD16.8 deuteride

Author

R. Cerny, I.V. Koval’chuk, Roman V. Denys, and I.Yu. Zavaliy

Subjects

Crystallography, Materials science, General Medicine, Crystal structure

Published

2008

14. Synthesis and crystal structure of -Zr9V4SH∼23

Author

Radovan Černý, I.Yu. Zavaliy, A.B. Riabov, I.V. Koval’chuck, and Roman V. Denys

Subjects

Intermetallics, Hydrogen, Chemistry, Hydride, Mechanical Engineering, Neutron diffraction, Metals and Alloys, chemistry.chemical_element, ddc:500.2, Crystal structure, X-ray diffraction, Crystallography, Hydrogen storage, Deuterium, Mechanics of Materials, X-ray crystallography, Crystal structure and symmetry, Materials Chemistry, Hydrogen storage materials, Powder diffraction

Abstract

The Zr 9 V 4 SH ∼23 hydride was synthesized by saturation from gaseous hydrogen at room temperature and 0.12 MPa hydrogen pressure. The measured hydrogen absorption capacity of the κ -Zr 9 V 4 S was 1.77 H/M. The refinement of the hydride structure with the use of X-ray powder diffraction data confirmed the preserved symmetry of the metallic matrix (sp.gr. P 6 3 / mmc , a = 9.2715 ( 2 ) , c = 9.0756 ( 4 ) A , Δ a / a = 7.3 % , Δ c / c = 6.1 % , Δ V / V = 22.1 % , Δ V / at.H = 2.62 A 3 ). The analysis of interstices in this compound revealed that without positioning hydrogen atoms in triangular Zr 3 interstices it is impossible to model the structure of k -hydride with the experimentally observed capacity. Neutron powder diffraction study of the Zr 9 V 4 SD ∼23 deuteride (sp.gr. P 6 3 / m m c , a = 9.2779 ( 5 ) , c = 9.0779 ( 5 ) A) revealed deuterium atoms filling two tetrahedral and three triangular interstices. A full occupancy of only one site (D4) was observed in our sample giving the refined deuterium content of 20.8(2) D/f.u. Filling of the D4 site causes a displacement of the sulphur atoms from the three-fold axis (splitting of 2c to 6h position).

Published

2005

15. Interaction of hydrogen with RECu2 and RE(Cu,Ni)2 intermetallic compounds (RE=Y, Pr, Dy, Ho)

Author

Radovan Černý, I.Yu. Zavaliy, V.N. Verbetsky, Roman V. Denys, and A.B. Riabov

Subjects

Hydrogen, Crystal structure, Mechanical Engineering, Metallurgy, Metals and Alloys, Intermetallic, chemistry.chemical_element, Rare earth compounds, ddc:500.2, Metal, Crystallinity, Crystallography, Hydrogen absorbing materials, chemistry, Mechanics of Materials, visual_art, Materials Chemistry, visual_art.visual_art_medium, Metal hydrides, Orthorhombic crystal system, Ternary operation, Transition metal compounds, Bar (unit)

Abstract

Hydrogenation of RECu2 (RE=Dy, Ho, Y) at room temperature and pressures of 100–1500-bar H2 has not resulted in the formation of ternary hydrides. The interaction of hydrogen with Pr(Cu1−xNix)2 (x=0, 0.1, 0.17, 0.25, 0.32) at room temperature and pressure of 25 bar resulted in the formation of Pr(Cu1−xNix)2H∼3 hydrides. It was found that the PrCu2H3 and Pr(Cu0.9Ni0.1)2H2.9 hydrides are poorly crystallized, but that an increase of the Ni-content leads to improved crystallinity of the hydrides. The hydrides Pr(Cu0.75Ni0.25)2H∼3 and Pr(Cu0.68Ni0.32)2H∼3 preserve, shortly after the hydrogen absorption, the CeCu2 type structure of their metallic matrix with a hydrogen induced volume expansion up to 28% compared to the parent compound. During long-term exposure in the air they undergo a structural transformation from the orthorhombic CeCu2 to the hexagonal Fe2P type with a hydrogen induced volume expansion up to 16.6% compared to the parent compound.

Published

2003

16. ChemInform Abstract: Hydrogenation Properties and Crystal Structure of YMgT4(T: Co, Ni, Cu) Compounds

Author

V.V. Shtender, Roman V. Denys, A.B. Riabov, Valérie Paul-Boncour, and I.Yu. Zavaliy

Subjects

Argon, Transition metal, Chemistry, Annealing (metallurgy), Inorganic chemistry, chemistry.chemical_element, Physical chemistry, General Medicine, Crystal structure, Arc melting

Abstract

The title compounds are prepared by mechanical alloying of YM4 (M: Co, Ni, Cu; obtained by arc melting of the elements) and Mg powder followed by annealing under argon (Ta containers, 600—800 °C, 8 h).

Published

2014

17. The crystal structure of the oxygen-stabilized η-phase Zr3V3OxD9.6

Author

I.Yu. Zavaliy, Vitalij K. Pecharsky, I. V. Saldan, W. B. Yelon, and Peter Y. Zavalij

Subjects

Neutron powder diffraction, Materials science, Phase stability, Mechanical Engineering, Neutron diffraction, Metals and Alloys, chemistry.chemical_element, Crystal structure, Oxygen, Hydrogen storage, Crystallography, chemistry, Mechanics of Materials, Phase (matter), Materials Chemistry, Physical chemistry, Stoichiometry

Abstract

Hydrogen storage capacity and crystal structure of hydrogen-free Zr3V3O0.6 and its saturated deuteride, Zr3V3OxD9.6, have been studied using both X-ray and neutron powder diffraction. Experimental data together with the geometrical analysis of the crystal structure of the deuteride indicate that oxygen non-stoichiometry plays a significant role in the 2-fold increase of hydrogen storage capacity of Zr3V3O0.6 compared with the stoichiometric oxygenated Zr3V3O.

Published

2000

18. Hydrogen ordering and H-induced phase transformations in Zr-based intermetallic hydrides

Author

Bjørn C. Hauback, I.Yu. Zavaliy, Helmer Fjellvåg, Volodymyr A. Yartys, M.H. Sørby, A.B. Riabov, and I.R. Harris

Subjects

Zirconium, Hydrogen, Crystal chemistry, Chemistry, Mechanical Engineering, Neutron diffraction, Metals and Alloys, Intermetallic, chemistry.chemical_element, Crystal structure, Crystallography, Hydrogen storage, Mechanics of Materials, Phase (matter), Materials Chemistry

Abstract

Crystal chemistry aspects of hydrogen behaviour in the zirconium–iron intermetallic deuterides (hydrides), Zr2FeD1.80–5.00, Zr3FeD1.27–6.70 and Zr4Fe2O0.6H7.80, were studied with a focus on the application of high resolution powder neutron diffraction. The effects of crystal structure, chemical composition of the metal matrices, temperature and hydrogen contents on preferences in the interstices occupation and H ordering were investigated and discussed in relation to the H absorption–desorption properties. The Hydrogenation–Disproportionation–Desorption–Recombination process was successfully applied to all materials studied, including the first reported example of an oxygen-containing compound, Zr4Fe2O0.6.

Published

1999

19. Effect of oxygen content on hydrogen storage capacity of Zr-based η-phases

Author

I.Yu. Zavaliy

Subjects

Chemistry, Mechanical Engineering, Zirconium alloy, Inorganic chemistry, Metals and Alloys, chemistry.chemical_element, Crystal structure, Oxygen, Hydrogen storage, Oxygen atom, Mechanics of Materials, X-ray crystallography, Materials Chemistry, Hydrogen concentration, Oxygen content

Abstract

The hydrogen storage capacity of η-phases Zr 3 V 3 O x and Zr 4 Fe 2 O x has been found to depend substantially on the oxygen content. Increase of the hydrogen storage capacities to H/f.u. ∼10.5 and 9.4 with the decrease of O-content have been observed for Zr 3 V 3 O x and Zr 4 Fe 2 O x , respectively. The hydrogen concentration in the title phases is higher than that in the corresponding ZrV 2 H 4.9 and Zr 2 FeH 4.5 saturated hydrides. The maximum hydrogen storage capacity is observed at x =0.6 for η-Zr 3 V 3 O x and x =0.3 for η-Zr 4 Fe 2 O x . Based on these results, it is believed that other Zr-based oxygen-stabilised η-phases could also display large hydrogen storage capacity due to partial occupation of 16(c) or 8(a) sites by oxygen atoms.

Published

1999

20. Hydrogenation of Zr6MeX2 intermetallic compounds (Me=Fe, Co, Ni; X=Al, Ga, Sn): Crystallographic and theoretical analysis

Author

L.G Akselrud, Gordon J. Miller, Vitalij K. Pecharsky, and I.Yu Zavaliy

Subjects

Hydrogen, Mechanical Engineering, Neutron diffraction, Metals and Alloys, Intermetallic, chemistry.chemical_element, Crystal structure, Crystallography, Hydrogen storage, chemistry, Mechanics of Materials, Formula unit, X-ray crystallography, Materials Chemistry, Powder diffraction

Abstract

Experimental studies on the series of ternary intermetallic compounds, Zr6MeX2, where Me=Fe, Co, and Ni, and X=Al, Ga, and Sn, show that they have large hydrogen storage capacities ranging from 9.3 to 10.8 H-atoms per formula unit. The crystal structure of the parent intermetallic compounds changes upon hydrogenation with a two-fold increase of the crystallographic c-axis length and a corresponding change in space group from P 6 m2 to P 6 2c . Full profile (Rietveld) refinement using X-ray powder diffraction data indicates that the crystal structures of the new hydrides, Zr6CoAl2H10, Zr6NiAl2H9.7 and Zr6NiSn2H10.8 are analogous to Zr6FeAl2D10, which was examined by neutron powder diffraction. Thermal desorption of hydrogen in all hydrides occurs in the temperature range between 400 and 900 K and is characterized by two similar events. The compounds Zr6FeAl2Hx (x=0, 10 and 0.1–0.2) order magnetically at 45, 155 and 10 K, respectively. Electronic structure calculations are carried out on Zr6FeAl2Hx (0≤x≤10) to interpret their structural and thermal behavior. Site energies for hydrogen incorporation, energetics of hydrogen desorption, as well as quantitative details of the densities of states are evaluated. Site energies and metal–metal bonding largely affect the maximum hydrogen content, while H–H repulsions constitute the greatest driving force for the change in space group upon hydrogenation.

Published

1999

21. Hydrogenation of Zr6FeAl2 and crystal structure of Zr6FeAl2D10

Author

F. Gingl, Klaus Yvon, Volodymyr A. Yartys, Peter Fischer, and I.Yu. Zavaliy

Subjects

Materials science, Hydride, Crystal structure, Mechanical Engineering, Inorganic chemistry, Metals and Alloys, Intermetallic, chemistry.chemical_element, ddc:500.2, Metal, Crystallography, Trigonal bipyramidal molecular geometry, chemistry, Deuterium, Mechanics of Materials, Aluminium, visual_art, Materials Chemistry, visual_art.visual_art_medium, Substructure, Hydrogenation

Abstract

The intermetallic compound Zr6FeAl2 was hydrogenated (deuterated) at room temperature and investigated by X-ray and neutron powder diffraction. The hydride (deuteride) crystallizes with hexagonal symmetry (space group P62c; deuteride: a = 8.1354(4) A, c = 7.0940(6) A, V = 406.62(5) A3, Z = 2, refined composition Zr6FeAl2D9.82(3)). Its metal atom substructure derives from an ordered Fe2P type host structure (space group P62m) by small atomic displacements that lead to a doubling of the c axis. Deuterium occupies two types of tetrahedral [Zr4], one type of tetrahedral [Zr3Fe] and one type of trigonal bipyramidal [Zr3Fe2] interstices, thus avoiding the neighbourhood of aluminium. The metal-deuterium bond distances are in the range Zr-D = 2.03–2.22 A and Fe-D = 1.73–1.77 A, while the shortest Al-D distance is 2.90 A. The hydrogen sorption properties of Zr6FeAl2 are intermediate to those of Zr2Fe and Zr2Al.

Published

1995

22. Hydrogen absorption and phase structural characteristics of oxygen-containing ZrV alloys substituted by Hf, Ti, Nb, Fe

Author

I.Yu. Zavaliy, A.B. Riabov, and Volodymyr A. Yartys

Subjects

Materials science, Hydrogen, Mechanical Engineering, Zirconium alloy, Metals and Alloys, chemistry.chemical_element, Crystal structure, Oxygen, Crystallography, chemistry, Mechanics of Materials, Phase (matter), Phase composition, Materials Chemistry, Hydrogen absorption, Powder diffraction

Abstract

Hydrogen absorption properties of ZrVO alloys where some of the Zr or V is substituted by Ti, Hf, or Nb, Fe, respectively have been investigated. Phase structural characteristics of these alloys and their hydrides have been determined by X-ray powder diffraction. The interdependence of obtained crystallographic and hydrogenation characteristics has been discussed.

Published

1995

23. ChemInform Abstract: New CeMgCo4and Ce2MgCo9Compounds: Hydrogenation Properties and Crystal Structure of Hydrides

Author

R. Cerny, Roman V. Denys, A.B. Riabov, I.Yu. Zavaliy, and I.V. Koval’chuk

Subjects

Argon, Chemistry, Annealing (metallurgy), chemistry.chemical_element, Physical chemistry, General Medicine, Crystal structure, Stoichiometry

Abstract

The title compounds are prepared by mechanical alloying of Mg with stoichiometric amounts CeCo4 or Ce2Co9 (obtained by arc-melting in Ar) followed by annealing at 800 °C for 7 h under 1 bar argon.

Published

2012

24. Crystal structure of the novel Mg3MnNi2D3−x interstitial deuteride

Author

I.V. Koval’chuk, I.Yu. Zavaliy, Roman V. Denys, A.R. Riabov, V. V. Berezovets, and Radovan Černý

Subjects

Mechanical alloying and milling, Materials science, Hydride, Mechanical Engineering, Neutron diffraction, Metals and Alloys, General Chemistry, Crystal structure, ddc:500.2, Diffraction (neutron and X-ray), Hydrogen storage, Metal, Crystallography, Octahedron, Crystal chemistry of intermetallics, Mechanics of Materials, visual_art, Materials Chemistry, Tetrahedron, visual_art.visual_art_medium, Ternary alloy systems

Abstract

A novel low-temperature hydride, Mg3MnNi2D3−x with filled Ti2Ni-type structure has been synthesised and its crystal structure has been studied in detail by powder neutron diffraction. Refinement of the structures of β-Mg3MnNi2D1.83 and α-Mg3MnNi2D0.23 deuteride phases showed that D atoms partially fill 16d Mg6 octahedral and 32e Mg3Ni tetrahedral interstices in the cubic metal matrix (sp.gr. View the MathML sourceFd3¯m). The β-hydride was found to be rather unstable, during storage in air it transforms into α-hydride.

Published

2011

25. ChemInform Abstract: Hydrogenation of Zr6FeAl2 and Crystal Structure of Zr6FeAl2D10

Author

F. Gingl, Volodymyr A. Yartys, Klaus Yvon, Peter Fischer, and I.Yu. Zavaliy

Subjects

Crystallography, Trigonal bipyramidal molecular geometry, Deuterium, Chemistry, Hydride, Aluminium, Atom, Intermetallic, Substructure, chemistry.chemical_element, General Medicine, Crystal structure

Abstract

The intermetallic compound Zr6FeAl2 was hydrogenated (deuterated) at room temperature and investigated by X-ray and neutron powder diffraction. The hydride (deuteride) crystallizes with hexagonal symmetry (space group P62c; deuteride: a = 8.1354(4) A, c = 7.0940(6) A, V = 406.62(5) A3, Z = 2, refined composition Zr6FeAl2D9.82(3)). Its metal atom substructure derives from an ordered Fe2P type host structure (space group P62m) by small atomic displacements that lead to a doubling of the c axis. Deuterium occupies two types of tetrahedral [Zr4], one type of tetrahedral [Zr3Fe] and one type of trigonal bipyramidal [Zr3Fe2] interstices, thus avoiding the neighbourhood of aluminium. The metal-deuterium bond distances are in the range Zr-D = 2.03–2.22 A and Fe-D = 1.73–1.77 A, while the shortest Al-D distance is 2.90 A. The hydrogen sorption properties of Zr6FeAl2 are intermediate to those of Zr2Fe and Zr2Al.

Published

2010

26. ChemInform Abstract: (Hf,Zr)2Fe and Zr4Fe2O0.6 Compounds and Their Hydrides: Phase Equilibria, Crystal Structure and Magnetic Properties

Author

I.Yu. Zavaliy, V. A. Yartys, Günter Wiesinger, Herwig Michor, Gerfried Hilscher, and A.B Riabov

Subjects

Chemistry, Phase (matter), Desorption, Physical chemistry, General Medicine, Crystal structure, Structure type, Hydrogen absorption, Hyperfine structure, Chemical composition

Abstract

Hydrogen absorption and desorption properties of the (Hf,Zr) 2 Fe quasibinary alloys (Ti 2 Ni structure type) and the oxygen-stabilised compound Zr 4 Fe 2 O 0.6 with the filled-Ti 2 Ni type of structure, have been studied and discussed in relation to their phase-structural and chemical composition. The crystallographic characteristics, hyperfine parameters and magnetic properties of the hydrogenated alloys have been determined.

Published

2010

27. Synthesis and Crystal Structure of ϰ-Zr9V4SH≈23

Author

R. Cerny, Roman V. Denys, I.Yu. Zavaliy, I.V. Koval’chuck, and A.B. Riabov

Subjects

Crystallography, Chemistry, Inorganic chemistry, General Medicine, Crystal structure

Published

2006

28. Hydrogen-induced changes in crystal structure and magnetic properties of the Zr3MOx (M = Fe, Co) phases

Author

I.V. Koval’chuck, Roman V. Denys, I.Yu. Zavaliy, Radovan Černý, Gerfried Hilscher, and Günter Wiesinger

Subjects

Hydrogen, Rietveld refinement, Mechanical Engineering, Metals and Alloys, chemistry.chemical_element, Crystal structure, ddc:500.2, Zr-based alloys, Magnetic susceptibility, Neutron diffraction, X-ray diffraction, Hydrogen storage, Crystallography, Deuterium, chemistry, Octahedron, Mechanics of Materials, Mössbauer spectroscopy, Magnetic properties, Materials Chemistry, Hydrogen storage materials

Abstract

It is shown that the oxygen-stabilised compounds Zr3Fe(Co)Ox (x = 0–1.0) interact with hydrogen at ambient temperature and pressure forming saturated hydrides with filled Re 3B type structure. The hydrogen storage capacity decreases with increasing oxygen content from 6.7 H/f.u. for Zr3Fe down to 5.35 H/f.u. for Zr3FeO1.0 and from 6.9 H/f.u. for Zr3Co down to 5.3 H/f.u. for Zr3CoO1.0. A small change of the unit cell volumes for the Zr3Fe(Co)Ox parent compounds and a substantial increase of these parameters for the corresponding saturated hydrides were observed with increasing oxygen content. The partial hydrogen-induced lattice expansion, � V/at. H, increases from 2.25 A 3 for Zr3FeH6.7 up to 3.38 A 3 for Zr3FeO1.0H5.35 and from 2.08 A 3 for Zr3CoH6.9 up to 3.25 A 3 for Zr3CoO1.0H5.3. Rietveld refinement using neutron powder diffraction data for Zr 3FeO0.4D6.25 showed a distribution of deuterium atoms and a redistribution of oxygen atoms from octahedral to tetrahedral sites in a similar way as in Zr3NiOxDy. Both 57 Fe Mossbauer spectroscopy and magnetic susceptibility measurements of Fe-containing hydrides indicated weak hydrogen-induced magnetic ordering at low temperatures. The ordering temperatures of Zr3FeO0.2H6.52 and Zr3FeO0.6H6.25 are 105 and 140 K, respectively. © 2004 Elsevier B.V. All rights reserved.

Published

2005

29. ChemInform Abstract: The Crystal Structure of the Oxygen-Stabilized η-Phase Zr3V3OxD9.6

Author

I. V. Saldan, Vitalij K. Pecharsky, I.Yu. Zavaliy, W. B. Yelon, and Peter Y. Zavalij

Subjects

Neutron powder diffraction, Hydrogen storage, Chemistry, Phase (matter), Physical chemistry, chemistry.chemical_element, General Medicine, Crystal structure, Oxygen, Stoichiometry

Abstract

Hydrogen storage capacity and crystal structure of hydrogen-free Zr3V3O0.6 and its saturated deuteride, Zr3V3OxD9.6, have been studied using both X-ray and neutron powder diffraction. Experimental data together with the geometrical analysis of the crystal structure of the deuteride indicate that oxygen non-stoichiometry plays a significant role in the 2-fold increase of hydrogen storage capacity of Zr3V3O0.6 compared with the stoichiometric oxygenated Zr3V3O.

Published

2000

30. (Hf,Zr)2Fe and Zr4Fe2O0.6 compounds and their hydrides: Phase equilibria, crystal structure and magnetic properties

Author

Herwig Michor, Gerfried Hilscher, I.Yu. Zavaliy, V. A. Yartys, Günter Wiesinger, and A.B Riabov

Subjects

Magnetic structure, Chemistry, Mechanical Engineering, Inorganic chemistry, Zirconium alloy, Metals and Alloys, Crystal structure, Mechanics of Materials, Desorption, Phase (matter), Materials Chemistry, Physical chemistry, Chemical composition, Hyperfine structure, Phase diagram

Abstract

Hydrogen absorption and desorption properties of the (Hf,Zr) 2 Fe quasibinary alloys (Ti 2 Ni structure type) and the oxygen-stabilised compound Zr 4 Fe 2 O 0.6 with the filled-Ti 2 Ni type of structure, have been studied and discussed in relation to their phase-structural and chemical composition. The crystallographic characteristics, hyperfine parameters and magnetic properties of the hydrogenated alloys have been determined.