Debye temperature of CaO under high  pressure up to 65.2 GPa

Bioud, Nadhira

doi:10.14419/ijac.v11i1.32228

Cited by 4 publications

(7 citation statements)

References 48 publications

(72 reference statements)

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“…We calculate the Vickers hardness HV of pore-free polycrystalline ceramics according to the following empirical expression: HV = 0.92(G/B) 1.137 G 0.708 [32], [38], whereG is the shear modulus and B is the bulk modulus. Frequently, the elastic moduli of the polycrystalline materials are calculated [39][40][41][42][43][44][45][46][47][48]. Iuga et al [45] have investigated the elastic constants Cij of ceramic crystals using an Ab-initio calculation.…”

Section: Theory and Discussion Of The Resultsmentioning

confidence: 99%

Quasi-linear correlation between shear and young’s moduli in some polycrystalline ceramics

Daoud,

Saini,

Rekab-Djabri

2024

IJPR

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This work aims to investigate the correlation between the shear modulus and the Young’s modulus of some pore-free polycrystalline ceram-ics. Our study shows that the shear modulus correlates quasi-linearly with the Young’s modulus. The best fit was obtained using the linear model. The fit of the shear modulus G as a function of the Young modulus E obeys this linear expression: G = 0.43E - 7.7 (where both G and E are expressed in GPa). The coefficient of the correlation was found at around 0.994. Our expression was used to predict the shear modulus G of some other polycrystalline ceramics, especially: Dy2O3, Er2O3, and Y2O3 materials, which are estimated at around 65.6, 72.4, and 51.8 GPa, respectively. We attempt also to estimate the Vickers hardness of our materials of interest using an empirical expression of the literature. Unfortunately our predicted results are larger than those reported previously in the literature.

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Section: Theory and Discussion Of The Resultsmentioning

confidence: 99%

Quasi-linear correlation between shear and young’s moduli in some polycrystalline ceramics

Daoud,

Saini,

Rekab-Djabri

2024

IJPR

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“…The evolutions of the Cauchy pressure Cp and the generalized elastic stability criteria under compression in the pressure ranging from 100 to 500 GPa of Na2He compound were presented in Figure1 (curves (a) and (b), respectively). The Debye temperature θD is an essential parameter in solid state physic [19][20][21][22][23]. For cubic crystals, the Debye temperature θD could be calculated using the following expression: [24][25][26], where, Cc = (26.05 ± 0.81) K (m kg N -1 ) 1/2 (the numerical value 26.05 ± 0.81 K (m kg N -1 ) 1/2 is valuable only for with cubic crystals), s is the number of atoms in the unit cell, a is the lattice parameter expressed in m, and M is the atomic weight (arithmetical average of the masses of the species), respectively [24][25][26].…”

Section: Theory Results and Discussionmentioning

confidence: 99%

Mechanical stability criterions of cubic Na2He up to 500 GPa

Daoud,

Rekab-Djabri

2023

Int. J. Sci. World

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The Cauchy pressure Cp was usually used to explain the atomic bonding character in a compound, while the mechanical stability criterions are usually used to study the stability of the structure under external compression. Using the elastic constants reported recently by Zahidur Rahaman et al. in Chinese Journal of Physics, 56 (2018) 231-237, as well as different mathematical formula, we reported on the Cauchy violation and the generalized mechanical stability criterions of cubic Na2He compound under high hydrostatic compression from 100 GPa to 500 GPa. For pressures ranging from 100 to 500 GPa, all values of both Cauchy pressure Cp and the generalized mechanical stability criteria G are negative. In addition we calculated the Debye temperature θD of Na2He compound using Siethoff’s approach. The results obtained are slightly lower than those obtained from the Debye approach reported by Zahidur Rahaman et al.

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“…In the past decade, a wide range of semiconductors were known; however, attention was focused on the simplest the III-V and II-VI compounds [1]. Debye temperature θD of material is an essential parameter in solid state physic [2][3][4][5][6], this because it is correlated with many physical properties of solids; such as specific heat, elastic moduli, melting point, and lattice energy [7]. At low temperature, the vibrational excitations arise solely from acoustic vibrations, with consequence the Debye temperature calculated from elastic constants is the same as that determined from the measurements of the specific heat [8].…”

Section: Introductionmentioning

confidence: 99%

“…First we recalculate the bulk modulus B, shear modulus G, Pugh ratio (B/G), Young modulus E and the Poisson's ratio σ, then the Debye temperature θD. In cubic polycrystalline crystals, the bulk modulus B could be calculated from the elastic constants Cij as follows: B = (C11 + 2C12)/3 [3,13], while the shear modulus G was usually calculated using the Voigt-Reuss-Hill approach, which is expressed as follows: G = (GV + GR)/2 [3,13], where GV is the Voigt shear modulus, while GR is the Reuss shear modulus. The Lamé's first parameter λ is expressed as follows: λ= σE/[(1+σ)(1-2σ)] [14].…”

Section: Introductionmentioning

confidence: 99%

“…A typical value of σ for ionic materials is 0.25 and G = 0.6B, while for metallic bonded materials σ is typically 0.33 and G = 0.4B [15]. There are different expressions usually used to calculate the Debye temperature θD of crystal from the acoustic wave speed [3,13]. The expression used here is the same like that used in the work [3] for CaO compound (for more details on the calculation of the acoustic wave speed and the Debye temperature θD polycrystalline materials, please see for example the references [3,13]).…”

Section: Introductionmentioning

confidence: 99%

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Some physical properties of K2TlAsX6 (X = Cl, Br) and CsPbBr3 semiconducting compounds

Bioud

2024

IJAC

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Some physical properties of K2TlAsX6 (X = Cl, Br) double perovskite compounds have been predicted using the theoretical unit cell parameters and elastic constants computed by Munir et al. (Materials Science and Engineering B 298 (2023) 116830). At equilibrium the Debye temperatures of K2TlAsCl6 and K2TlAsBr6 materials were found to be 193.5 K and 159.6 K, respectively. Furthermore, the mass density, the longitudinal, transverse and mean acoustic wave speeds, the acoustic impedance and the Debye temperature of Cesium Lead Bromide (CsPbBr3) inorganic perovskite compound under high stress up to 15 GPa have been predicted using the theoretical unit cell parameters and elastic constants computed by Junaid Zaidi et al. (Materials Research Express, Vol. 9, No. 12, (2022) 125501). To the best of our knowledge, there is no any data in the literature that can be compared to the findings we’ve achieved on the Debye temperature of K2TlAsX6 (X = Cl, Br) and CsPbBr3 materials.

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Debye temperature of CaO under high pressure up to 65.2 GPa

Cited by 4 publications

References 48 publications

Quasi-linear correlation between shear and young’s moduli in some polycrystalline ceramics

Quasi-linear correlation between shear and young’s moduli in some polycrystalline ceramics

Mechanical stability criterions of cubic Na2He up to 500 GPa

Some physical properties of K2TlAsX6 (X = Cl, Br) and CsPbBr3 semiconducting compounds

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