2017
DOI: 10.14419/ijpr.v5i1.7093
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Thermal properties of cubic zincblende thallium-phosphide from quasi-harmonic Debye model approximation

Abstract: The thermal properties of cubic zincblende (B3) thallium -phosphide (TlP) compound under high pressure up to 12 GPa have been studied using the quasi-harmonic Debye model approximation. The relative unit cell volume, the isothermal bulk modulus, the first order derivative isothermal bulk modulus, the Debye temperature and the Grüneisen parameter are studied at zero-temperature and at standard ambient temperature (298 K) respectively. Our obtained values of the different previous quantities are in general in ag… Show more

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Cited by 6 publications
(6 citation statements)
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“…Similar behavior for the bulk modulus versus pressure was observed for the two approaches. Similar behavior for the bulk modulus under pressure was observed for calciumbased chalcogenides CaX (X = S, Se, Te) [20], cubic zincblende (B3) aluminum phosphide (AlP) semiconducting compound [24], and cubic zincblende thallium -phosphide (TlP) material [25]. The fit of our data on the bulk modulus as a function of pressure p (where both B and p are expressed in GPa) obeys the 2 nd order polynomial expression: B = 115.37 + 3.84 p -7.25 x 10 -3 p 2 .…”
Section: Theory Results and Discussionsupporting
confidence: 66%
“…Similar behavior for the bulk modulus versus pressure was observed for the two approaches. Similar behavior for the bulk modulus under pressure was observed for calciumbased chalcogenides CaX (X = S, Se, Te) [20], cubic zincblende (B3) aluminum phosphide (AlP) semiconducting compound [24], and cubic zincblende thallium -phosphide (TlP) material [25]. The fit of our data on the bulk modulus as a function of pressure p (where both B and p are expressed in GPa) obeys the 2 nd order polynomial expression: B = 115.37 + 3.84 p -7.25 x 10 -3 p 2 .…”
Section: Theory Results and Discussionsupporting
confidence: 66%
“…The Debye temperature is usually used to distinguish between low and high temperature regions [33]. In our recent work [28], the plasmon energy (ћωp) used with success to predict the Debye temperature (θD) of BBi compound.…”
Section: Debye Temperature and Melting Temperaturementioning
confidence: 99%
“…2 that the Debye temperature θD of Na2He compound increases non-linearly with increasing in pressure from 100 to 500 GPa. We note that a similar behavior was observed in comparison to data obtained for Cu3N compound up to 30 GPa [3], for cubic zincblende boron nitride [12], for BeSe compound up to 50 GPa [20], for CaTe semiconducting material up to 27.8 GPa [25], for calcium oxide (CaO) compound [26,27], for alkaline earth CaX (X = S, Se, Te) semiconducting materials [28], for both α-PbO2 and β-PbO2 materials [29], for cubic zincblende thallium-phosphide (TlP) up to 12 GPa [30], and for Ni3Mo intermetallic compound up to 30 GPa [31]. The best fit of our data on θD (expressed in K) versus pressure p (expressed in GPa) for Na2He compound is given as follows: θD = 301.1 +4.25 p -0.007 p 2 +0.54 x 10 -5 p 3 .…”
Section: Theory Results and Discussionmentioning
confidence: 99%