M. Bouchenafa scite author profile

Abstract:The effects of pressure on the crystal structure of the three known polymorphs of magnesium sulfate (α-MgSO 4 , β-MgSO 4 , and γ-MgSO 4 ) have been theoretically study by means of density-functional theory calculations up to 45 GPa. We determined that at ambient conditions γ-MgSO 4 is an unstable polymorph, which decompose into MgO + SO 3 , and that the response of the other two polymorphs to hydrostatic pressure is non-isotropic.Additionally we found that at all pressures β-MgSO 4 has a largest enthalpy than α-MgSO 4 .This indicates that β-MgSO 4 is thermodynamically unstable versus α-MgSO 4 and predicts the occurrence of a β−α phase transition under moderate compression. Our calculations also predict the existence under pressure of additional phase transitions to two new polymorphs of MgSO 4 , which we named as δ-MgSO 4 and ε-MgSO 4 . The α−δ transition is predicted to occur at 17.5 GPa, and the δ−ε transition at 35 GPa, pressures that nowadays can be 2 experimentally easily achieved. All the predicted structural transformations are characterized as first-order transitions. This suggests that they can be non-reversible, and therefore the new polymorphs could be recovered as metastable polymorphs at ambient conditions. The crystal structure of the two new polymorphs is reported. In them, the coordination number of sulfur is four as in the previously known polymorphs, but the coordination number of magnesium is eight instead of six. In the article we will report the axial and bond compressibility for the four polymorphs of MgSO 4 . The pressure-volume equation of state of each phase is also given, which is described by a third-order Birch-Murnaghan equation. The values obtained for the bulk modulus are 62 GPa, 57 GPa, 102 GPa, and 119 GPa for α-MgSO 4 , β-MgSO 4 , δ-MgSO 4 , and ε-MgSO 4 , respectively. Finally, the electronic band structure of these four polymorphs of MgSO 4 has been calculated by the first time. The obtained results will be presented and discussed.

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Synthesis, Characterization, and Crystal Structure Determination of a New Lithium Zinc Iodate Polymorph LiZn(IO3)3

Hebboul

Galez

Benbertal

et al. 2019

Crystals

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Synthesis and characterization of anhydrous LiZn(IO3)3 powders prepared from an aqueous solution are reported. Morphological and compositional analyses were carried out by using scanning electron microscopy and energy-dispersive X-ray measurements. The synthesized powders exhibited a needle-like morphology after annealing at 400 °C. A crystal structure for the synthesized compound was proposed from powder X-ray diffraction and density-functional theory calculations. Rietveld refinements led to a monoclinic structure, which can be described with space group P21, number 4, and unit-cell parameters a = 21.874(9) Å, b = 5.171(2) Å, c = 5.433(2) Å, and  = 120.93(4)°. Density-functional theory calculations supported the same crystal structure. Infrared spectra were also collected, and the vibrations associated with the different modes were discussed. The non-centrosymmetric space group determined for this new polymorph of LiZn(IO3)3, the characteristics of its infrared absorption spectrum, and the observed second-harmonic generation suggest it is a promising infrared non-linear optical material.

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Theoretical investigation of the structural, elastic, electronic and optical properties of the ternary indium sulfide layered structures A InS 2 ( A = K, Rb and Cs)

Bouchenafa

Sidoumou

Halit

et al. 2018

Solid State Sciences

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Ab initio study of the mechanical and electronic properties of scheelite-type XWO₄(X = Ca, Sr, Ba) compounds

Benmakhlouf

Errandonea

Bouhemadou

et al. 2017

Int. J. Mod. Phys. B

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The structural, mechanical, and electronic properties of scheelite-type CaWO4, SrWO4, and BaWO4 have been investigated using density-functional theory (DFT) within the generalized-gradient approximation (GGA). In particular, we have studied the effect of pressure in the crystal structure, elastic constants [Formula: see text], elastic moduli ([Formula: see text], [Formula: see text] and [Formula: see text]), and elastic anisotropy. We have also investigated the band structure of the three studied compounds and the effect of pressure in their electronic bandgap. The obtained results compare well with experimental results regarding the high-pressure (HP) behavior of the crystal structure. The reported calculations allow us to get a better understanding of effects caused by compression on scheelite-type oxides and to predict the HP response of physical properties of importance for different technological applications.

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M. Bouchenafa

New pressure-induced polymorphic transitions of anhydrous magnesium sulfate

Synthesis, Characterization, and Crystal Structure Determination of a New Lithium Zinc Iodate Polymorph LiZn(IO3)3

Theoretical investigation of the structural, elastic, electronic and optical properties of the ternary indium sulfide layered structures A InS 2 ( A = K, Rb and Cs)

Ab initio study of the mechanical and electronic properties of scheelite-type XWO₄(X = Ca, Sr, Ba) compounds

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M. Bouchenafa

New pressure-induced polymorphic transitions of anhydrous magnesium sulfate

Synthesis, Characterization, and Crystal Structure Determination of a New Lithium Zinc Iodate Polymorph LiZn(IO3)3

Theoretical investigation of the structural, elastic, electronic and optical properties of the ternary indium sulfide layered structures A InS 2 ( A = K, Rb and Cs)

Ab initio study of the mechanical and electronic properties of scheelite-type XWO4(X = Ca, Sr, Ba) compounds

Contact Info

Product

Resources

About

Ab initio study of the mechanical and electronic properties of scheelite-type XWO₄(X = Ca, Sr, Ba) compounds