Voraksmy Ban scite author profile

Controlling electronic population through chemical doping is one way to tip the balance between competing phases in materials with strong electronic correlations. Vanadium dioxide exhibits a first-order phase transition at around 338 K between a high-temperature, tetragonal, metallic state (T) and a low-temperature, monoclinic, insulating state (M1), driven by electron-electron and electron-lattice interactions. Intercalation of VO2 with atomic hydrogen has been demonstrated, with evidence that this doping suppresses the transition. However, the detailed effects of intercalated H on the crystal and electronic structure of the resulting hydride have not been previously reported. Here we present synchrotron and neutron diffraction studies of this material system, mapping out the structural phase diagram as a function of temperature and hydrogen content. In addition to the original T and M1 phases, we find two orthorhombic phases, O1 and O2, which are stabilized at higher hydrogen content. We present density functional calculations that confirm the metallicity of these states and discuss the physical basis by which hydrogen stabilizes conducting phases, in the context of the metal-insulator transition.

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Tuning magnetic spirals beyond room temperature with chemical disorder

Morin¹,

Canévet²,

Raynaud³

et al. 2016

Nat Commun

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In the past years, magnetism-driven ferroelectricity and gigantic magnetoelectric effects have been reported for a number of frustrated magnets featuring ordered spiral magnetic phases. Such materials are of high-current interest due to their potential for spintronics and low-power magnetoelectric devices. However, their low-magnetic ordering temperatures (typically <100 K) greatly restrict their fields of application. Here we demonstrate that the onset temperature of the spiral phase in the perovskite YBaCuFeO5 can be increased by more than 150 K through a controlled manipulation of the Fe/Cu chemical disorder. Moreover, we show that this novel mechanism can stabilize the magnetic spiral state of YBaCuFeO5 above the symbolic value of 25 °C at zero magnetic field. Our findings demonstrate that the properties of magnetic spirals, including its wavelength and stability range, can be engineered through the control of chemical disorder, offering a great potential for the design of materials with magnetoelectric properties beyond room temperature.

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Innovative in Situ Ball Mill for X-ray Diffraction

et al. 2017

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The renewed interest of mechanochemistry as an ecofriendly synthetic route has inspired original methodologies to probe reactions, with the aim to rationalize unknown mechanisms. Recently, Friščić et al. ( Nat. Chem. 2013 , 5 , 66 - 73 , DOI: 10.1038/nchem.1505 ) monitored the progress of milling reactions by synchrotron X-ray powder diffraction (XRPD). For the first time, it was possible to acquire directly information during a mechanochemical process. This new methodology is still in its early stages, and its development will definitively transform the fundamental understanding of mechanochemistry. A new type of in situ ball mill setup has been developed at the Materials Science beamline (Swiss Light Source, Paul Scherrer Institute, Switzerland). Its particular geometry, described here in detail, results in XRPD data displaying significantly lower background and much sharper Bragg peaks, which in turn allow more sophisticated analysis of mechanochemical processes, extending the limits of the technique.

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The First Halide-Free Bimetallic Aluminum Borohydride: Synthesis, Structure, Stability, and Decomposition Pathway

et al. 2013

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Interaction of solid KBH 4 with liquid Al(BH 4 ) 3 at room temperature yields a solid bimetallic borohydride KAl(BH 4 ) 4 . According to the synchrotron X-ray powder diffraction, its crystal structure (space group Fddd, a = 9.7405(3), b = 12.4500(4), and c = 14.6975(4) Å) contains a substantially distorted tetrahedral [Al(BH 4 ) 4 ]− anion, where the borohydride groups are coordinated to aluminum atoms via edges. The η -coordination of BH 4− is confirmed by the infrared and Raman spectroscopies. The title compound is the first aluminum-based borohydride complex not stabilized by halide anions or by bulky organic cations. It is not isostructural to bimetallic chlorides, where more regular tetrahedral AlCl 4 − anions are present. Instead, it is isomorphic to the LT phase of TbAsO 4 and can be also viewed as consisting of two interpenetrated dia-type nets where BH 4 ligand is bridging Al and K cations. Variable temperature X-ray powder diffraction, TGA, DSC, and TGA-MS data reveal a single step of decomposition at 160°C, with an evolution of hydrogen and some amount of diborane. Aluminum borohydride is not released in significant amounts; however, some crystalline KBH 4 forms upon decomposition. The higher decomposition temperature than in chloride-substituted Li−Al (70°C) and Na−Al (

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Lithium Hydrazinidoborane: A Polymorphic Material with Potential for Chemical Hydrogen Storage

et al. 2014

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Metal amide and hydrogen (MNH2-H2) system is recognized as a promising reversible hydrogen storage system due to its high hydrogen capacity and lower operating temperature. However, slow reaction rate for the Li system with the highest hydrogen capacity is an important issue to be solved for practical use. In this thesis, modification of the reaction properties for the LiNH2-H2 system is carried out from thermodynamic and kinetic points of view. Particularly, the novel ammonia synthesis technique is proposed by applying the LiNH2-H2 system and Amide-imide system. Lithium hydride-Potassium hydride (LiH-KH) complex synthesized by ball-milling has been focused in order to modify the kinetic properties of the reaction between LiH and ammonia. The LiH-NH3 system is recognized as one of the most promising hydrogen storage system because it generates hydrogen at room temperature by ammonolysis reaction. Moreover, the starting system can be regenerated below 300 °C and possesses more than 8.0 wt.% hydrogen capacity. From the experimental results, it is confirmed that the hydrogen generation from the reaction between ammonia and the LiH-KH complex shows much higher reaction rate than that of the simple summation of each component as a synergetic effect. Then, a double-cation amide MNH2 (LiK(NH2)2) phase, which could not be assigned to any reported amides so far, is formed as the reaction product. Moreover, in the hydrogenation of LiK(NH2)2, two processes were confirmed at the different temperatures. After the low temperature hydrogenation, KH-lithium amide (LiNH2) composite is generated as the hydrogenated product. It is noteworthy that the hydrogenation temperature of the composite is dramatically lower than that of LiNH2 itself, which should be due to the interaction between LiNH2 and KH such as a eutectic melting phenomenon. II An ammonia synthesis technique from lithium nitride (Li3N) based on the reactions of "Amide-imide system" and "Amide-hydrogen system" is proposed. Namely, Li3N is hydrogenated below 300 °C under 0.5 MPa hydrogen atmosphere, and then LiNH2 and LiH are formed as products. Furthermore, the reaction between LiNH2 and hydrogen proceeds below 250 °C under 0.5 MPa of hydrogen flow condition, which results in the formation of ammonia and LiH. In this study, a new method of ammonia synthesis is proposed at laboratory scale using above two reactions. This method is capable of being operated under more moderate conditions than those of Haber-Bosch process. The proposed method is investigated for various reaction system such as open system, closed gas circuit system, and closed gas exchange system using couple of hydrogen storage alloys. As a result, it is experimentally clarified that the ammonia can be synthesized below 300 °C and 0.5 MPa with realistic reactions rate by non-equilibrium reaction field under certain hydrogen flow rate even in the closed system.

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Voraksmy Ban

In Situ Diffraction Study of Catalytic Hydrogenation of VO₂: Stable Phases and Origins of Metallicity

Tuning magnetic spirals beyond room temperature with chemical disorder

Innovative in Situ Ball Mill for X-ray Diffraction

The First Halide-Free Bimetallic Aluminum Borohydride: Synthesis, Structure, Stability, and Decomposition Pathway

Lithium Hydrazinidoborane: A Polymorphic Material with Potential for Chemical Hydrogen Storage

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About

Voraksmy Ban

In Situ Diffraction Study of Catalytic Hydrogenation of VO2: Stable Phases and Origins of Metallicity

Tuning magnetic spirals beyond room temperature with chemical disorder

Innovative in Situ Ball Mill for X-ray Diffraction

The First Halide-Free Bimetallic Aluminum Borohydride: Synthesis, Structure, Stability, and Decomposition Pathway

Lithium Hydrazinidoborane: A Polymorphic Material with Potential for Chemical Hydrogen Storage

Contact Info

Product

Resources

About

In Situ Diffraction Study of Catalytic Hydrogenation of VO₂: Stable Phases and Origins of Metallicity