Exponential series representation for heat capacities of semiconductors and wide‐bandgap materials

Pässler, R.

doi:10.1002/pssb.200743480

Cited by 18 publications

(39 citation statements)

References 60 publications

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“…Within the frame of numerical analyses of experimental heat capacity data, however, one is continually concerned with a basic theoretical complication due to the inherent differences between the temperature dependencies of theoretical ℎ ( ) functions, on the one hand, and those of measured (isobaric) heat capacities, ( ), on the other hand. The latter are well known to be throughout somewhat higher, ( ) > ℎ ( ), than their theoretical (isochoric) counterparts pertaining to the harmonic lattice regime [4,50,54]. The respective differences, ( ) − ℎ ( ) > 0, are usually found to be very small from 0 up to temperatures of order ℎ , where the heat capacity amounts to about 50% of the Delong-Petit limiting value, ( ℎ ) ≅ ℎ ( ℎ ) = ℎ (∞)/2.…”

Section: Basic Equations For Temperature Dependencies Of Heat Capacitmentioning

confidence: 92%

“…Within the frame of the harmonic lattice regime, the temperature dependencies of the isochoric heat capacities, ℎ ( ), are well known to be given by corresponding heat capacity shape functions, ℎ ( ), of the general form [4,6,45,[50][51][52][53][54][55] ℎ ( ) ℎ (∞)…”

Section: Basic Equations For Temperature Dependencies Of Heat Capacitmentioning

confidence: 99%

“…On the other hand, one is usually concerned with a relatively strong monotonic increase of these differences, ( ( ) − ℎ ( ))/ > 0, at higher temperatures ( > ℎ ). These differences are generally ascribed to cumulative effects of lattice expansion and lattice anharmonicities [3,11,18,21,23,39,50,54,56,57]. We have repeatedly found within a larger series of heat capacity studies [14,15,21,50,54] that, within regions from ℎ up to temperatures of order 5 ℎ (at least), the rapid increase of these differences can be simulated in good approximation by a proportionality of type ( ) − ℎ ( ) ∝ × ( ℎ ( )) 2 ∝ × ( ℎ ( )) 2 (note that the structure of the latter is analogous to the known Nernst-Lindemann formula [2,3,58]…”

Section: Basic Equations For Temperature Dependencies Of Heat Capacitmentioning

confidence: 99%

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Unprecedented Integral-Free Debye Temperature Formulas: Sample Applications to Heat Capacities of ZnSe and ZnTe

Pässler

2017

Advances in Condensed Matter Physics

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Detailed analytical and numerical analyses are performed for combinations of several complementary sets of measured heat capacities, for ZnSe and ZnTe, from the liquid-helium region up to 600 K. The isochoric (harmonic) parts of heat capacities, ℎ ( ), are described within the frame of a properly devised four-oscillator hybrid model. Additional anharmonicity-related terms are included for comprehensive numerical fittings of the isobaric heat capacities, ( ). The contributions of Debye and nonDebye type due to the low-energy acoustical phonon sections are represented here for the first time by unprecedented, integralfree formulas. Indications for weak electronic contributions to the cryogenic heat capacities are found for both materials. A novel analytical framework has been constructed for high-accuracy evaluations of Debye function integrals via a couple of integralfree formulas, consisting of Debye's conventional low-temperature series expansion in combination with an unprecedented hightemperature series representation for reciprocal values of the Debye function. The zero-temperature limits of Debye temperatures have been detected from published low-temperature ( ) data sets to be significantly lower than previously estimated, namely, 270 (±3) K for ZnSe and 220 (±2) K for ZnTe. The high-temperature limits of the "true" (harmonic lattice) Debye temperatures are found to be 317 K for ZnSe and 262 K for ZnTe.

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Section: Basic Equations For Temperature Dependencies Of Heat Capacitmentioning

confidence: 92%

Section: Basic Equations For Temperature Dependencies Of Heat Capacitmentioning

confidence: 99%

Section: Basic Equations For Temperature Dependencies Of Heat Capacitmentioning

confidence: 99%

See 1 more Smart Citation

Unprecedented Integral-Free Debye Temperature Formulas: Sample Applications to Heat Capacities of ZnSe and ZnTe

Pässler

2017

Advances in Condensed Matter Physics

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“…In this model, the ratio for the respective oscillation frequencies was taken to be 1/2. However, this model could not well describe the heat capacities in the cryogenic region T < 100 K [5].…”

Section: Introductionmentioning

confidence: 95%

“…, where Θ D (∞) is the Debye temperature at T → ∞ K. Different models based on Thirring and exponential series expansions have also been given for the intermediate to high temperature regions, respectively [5]. However, these models are complex and sets of seven or eight empirical parameters should be determined.…”

Section: Introductionmentioning

confidence: 99%

New Kinetic Theory for Absorption and Emission Rates of Radiation and New Equations for Lattice and Electronic Heat Capacities, Enthalpies and Entropies of Solids: Application to Copper

Bozdoğan

2017

Acta Phys. Pol. A

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New equations, which have analytical solutions, for lattice and electronic heat capacities, entropies and enthalpies at constant volume and constant pressure were derived by using kinetic theory, Kirchhoff and Stefan-Boltzmann laws and Wien radiation density equation. These equations were applied to the experimental constant volume heat capacity data of copper. The temperature ΘV corresponding to 3R/2 was found to be 78.4 K for copper. Copper shows the dimensionality crossover from 3 to 2 at about 80 K. The ΘV (T ) is proportional to Debye temperature. The relationship between dimension and ΘV was given. Temperature dependence of Debye temperature and nonmonotonic behavior were discussed. The heat capacity and entropy values, predicted by the proposed models were compared with the values predicted by the Debye models. The results have shown that the proposed models fit the data better than the Debye models. Enthalpy equations derived in this study were compared with the polynomial model and a good fitting was obtained. The equation for the photon absorption equilibrium constant of copper was derived.

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Limiting Debye temperature behavior following from cryogenic heat capacity data for group-IV, III-V, and II-VI materials

Pässler

2009

phys. stat. sol. (b)

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We perform analyses of cryogenic heat capacity data sets, that are available from thermo-physical literature for group-IV materials (diamond, Si, Ge, and 3C-SiC), a variety of III-V materials (BN, BP, BAs, GaN, GaP, GaAs, GaSb, InP, InAs, InSb), and several II-VI materials (ZnO, ZnS, ZnSe, CdS, and CdTe). A prominent new result of the present study consists above all in a general high-precision formula,

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Exponential series representation for heat capacities of semiconductors and wide‐bandgap materials

Cited by 18 publications

References 60 publications

Unprecedented Integral-Free Debye Temperature Formulas: Sample Applications to Heat Capacities of ZnSe and ZnTe

Unprecedented Integral-Free Debye Temperature Formulas: Sample Applications to Heat Capacities of ZnSe and ZnTe

New Kinetic Theory for Absorption and Emission Rates of Radiation and New Equations for Lattice and Electronic Heat Capacities, Enthalpies and Entropies of Solids: Application to Copper

Limiting Debye temperature behavior following from cryogenic heat capacity data for group-IV, III-V, and II-VI materials

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