Half‐Heusler materials as model systems for phase‐separated thermoelectrics

Fecher, Gerhard H.; Rausch, Elisabeth; Balke, Benjamin; Weidenkaff, Anke; Felser, Claudia

doi:10.1002/pssa.201532595

Cited by 33 publications

(23 citation statements)

References 78 publications

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“…Doping or substitution is used to manipulate the chemical potential by varying the number of valence electrons in compounds and alloys. By definition, = 0 corresponds to the top of the valence band in semiconductors [20]. Chemical potential is determined by the temperature and by the total number of carriers.…”

Section: Transport Properties As a Function Of Chemical Potentialmentioning

confidence: 99%

DFT Study on the Carrier Concentration and Temperature-Dependent Thermoelectric Properties of Antimony Selenide

Jayaraman

Kademane

Molli

2016

Indian Journal of Materials Science

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We present the thermoelectric properties of Antimony Selenide (Sb 2 Se 3 ) obtained using first principles calculations. We investigated the electronic band structure using the FP-LAPW method within the sphere of the density functional theory. Thermoelectric properties were calculated using BoltzTrap code using the constant relaxation time ( ) approximation at three different temperatures 300 K, 600 K, and 800 K. Seebeck coefficient ( ) was found to decrease with increasing temperature, electrical conductivity ( / ) was almost constant in the entire temperature range, and electronic thermal conductivity ( / ) increased with increasing temperature. With increase in temperature decreased from 1870 V/K (at 300 K) to 719 V/K (at 800 K), electronic thermal conductivity increased from 1.56 × 10 15 W/m K s (at 300 K) to 3.92 × 10 15 W/m K s (at 800 K), and electrical conductivity decreased from 22 × 10 19 /Ω m s (at 300 K) to 20 × 10 19 /Ω m s (at 800 K). The thermoelectric properties were also calculated for different hole concentrations and the optimum concentration for a good thermoelectric performance over a large range of temperatures (from 300 K to 1000 K) was found for hole concentration around 10 19 cm −3 .

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Section: Transport Properties As a Function Of Chemical Potentialmentioning

confidence: 99%

DFT Study on the Carrier Concentration and Temperature-Dependent Thermoelectric Properties of Antimony Selenide

Jayaraman

Kademane

Molli

2016

Indian Journal of Materials Science

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“…9,10 Improvements in their thermoelectric figure of merit zT = S 2 σ κ T -where T represents temperature, S the Seebeck coefficient, σ the electrical conductivity and κ the thermal conductivity comprising both the lattice (κ ) and electronic (κ e ) contributions -have been achieved mostly for multicomponent half-Heusler alloys with complex microstructures. [11][12][13][14][15][16][17][18][19] Despite the tremendous importance of defects on materials' technological applications, determining the concentration of different defects and their effects is still a very challenging problem. 1 One such example is of the thermoelectric half-Heusler ZrNiSn.…”

Section: Introductionmentioning

confidence: 99%

Unraveling the dominant phonon scattering mechanism in the thermoelectric compound ZrNiSn

2016

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Determining defect types and concentrations remains a big challenge of semiconductor materials science. By using ab-initio thermal conductivity calculations we reveal that Ni/vacancy antisites, and not the previously claimed Sn/Zr antisites, are the dominant defects affecting thermal transport in half-Heusler compound ZrNiSn. Our calculations correctly predict the thermal conductivity dependence with temperature and concentration, in quantitative agreement with published experimental results. Furthermore, we find a characteristic proportionality between phonon-antisite scattering rates and the sixth power of phonon frequency, for which we provide an analytic derivation. These results suggest that thermal conductivity measurements in combination with ab-initio calculations can be used to quantitatively assess defect types and concentrations in semiconductors.

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“…In particular, theoretical studies of NiZrSn with focus on thermoelectric applications have been published recently. 9,10 From an experimental perspective, half-Heusler materials with similar composition, e.g. NiTiSn or Ni(Zr,Hf)Sn or CoTiSb, have already shown promising performance.…”

Section: Introductionmentioning

confidence: 99%

Ternary semiconductors NiZrSn and CoZrBi with half-Heusler structure: A first-principles study

Fiedler

Kratzer

2016

Phys. Rev. B

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The ternary semiconductors NiZrSn and CoZrBi with C1 b crystal structure are introduced by calculating their basic structural, electronic and phononic properties using density functional theory. Both the gradient-corrected PBE functional and the hybrid functional HSE06 are employed. While NiZrSn is found to be a small-band-gap semiconductor (Eg = 0.46 eV in PBE and 0.60 eV in HSE06), CoZrBi has a band gap of 1.01 eV in PBE (1.34 eV in HSE06). Moreover, effective masses and deformation potentials are reported. In both materials ABC, the intrinsic point defects introduced by species A (Ni or Co) are calculated. The Co-induced defects in CoZrBi are found to have a higher formation energy compared to Ni-induced defects in NiZrSn. The interstitial Ni atom (Nii ) as well as the VNiNii complex introduce defect states in the band gap, whereas the Ni vacancy (VNi) only reduces the size of the band gap. While Nii is electrically active and may act as a donor, the other two types of defects may compensate extrinsic doping. In CoZrBi, only the VCoCoi complex introduces a defect state in the band gap. Motivated by the reported use of NiZrSn for thermoelectric applications, the Seebeck coefficient of both materials, both in the p-type and the n-type regime, is calculated. We find that CoZrBi displays a rather large thermopower of up to 500µV/K when p-doped, whereas NiZrSn possesses its maximum thermopower in the n-type regime. The reported difficulties in achieving p-type doping in NiZrSn could be rationalized by the unintended formation of Niin conjunction with extrinsic acceptors, resulting in their compensation. Moreover, it is found that all types of defects considered, when present in concentrations as large as 3%, tend to reduce the thermopower compared to ideal bulk crystals at T = 600 K. For NiZrSn, the calculated thermodynamic data suggest that additional Ni impurities could be removed by annealing, leading to precipitation of a metallic Ni2ZrSn phase.

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Half‐Heusler materials as model systems for phase‐separated thermoelectrics

Cited by 33 publications

References 78 publications

DFT Study on the Carrier Concentration and Temperature-Dependent Thermoelectric Properties of Antimony Selenide

DFT Study on the Carrier Concentration and Temperature-Dependent Thermoelectric Properties of Antimony Selenide

Unraveling the dominant phonon scattering mechanism in the thermoelectric compound ZrNiSn

Ternary semiconductors NiZrSn and CoZrBi with half-Heusler structure: A first-principles study

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