Thermoelectric Properties of CoAsSb: An Experimental and Theoretical Study

Abstract: Polycrystalline samples of CoAsSb were prepared by annealing a stoichiometric mixture of the elements at 1073 K for 2 weeks. Synchrotron powder X-ray diffraction refinement indicated that CoAsSb adopts arsenopyrite-type structure with space group P2 1 /c. Sb vacancies were observed by both elemental and structural analysis, which indicate CoAsSb 0.883 composition. CoAsSb was thermally stable up to 1073 K without structure change but decomposed at 1168 K. Thermoelectric properties were measured from 300 to 1000… Show more

“…The Seebeck coefficient calculated with LQSGW P BE approach is presented in Figure 3 for various doping levels. Zero doping results in a positive Seebeck coefficient at low temperatures and a negative Seebeck coefficient at high temperatures in contrast to the consistent negative Seebeck coefficient from the experiment (Figure 7a in [18]). From a small increase in the doping, the LQSGW P BE curves suddenly become much more similar to the experiment and T max increases.…”

“…LDA resulted in a metallic band structure contradicting with experimental results. 18 Consequently there was a mismatch of the calculated transport properties in accordance with general tendencies discovered in high-throughput calculations. 8 To compare ways of resolving the bandgap issue, authors of the Ref.…”

“…LQSGW results in a band gap of 0.279 eV which is slightly above the experimental range 0.12-0.256 eV. 18 The range of exact exchange in PBE0 (10%-25%) results in bandgaps which cover the experimental uncertainty. For the optimized geometry, we obtained a tiny gap in our DFT calculation (0.005 eV), which can be at- tributed to using GGA instead of LDA as in [18].…”

“…18 The range of exact exchange in PBE0 (10%-25%) results in bandgaps which cover the experimental uncertainty. For the optimized geometry, we obtained a tiny gap in our DFT calculation (0.005 eV), which can be at- tributed to using GGA instead of LDA as in [18]. But with LQSGW, a noticeable overestimation of the band gap (0.441eV) is observed.…”

“…However, the above slightly more advanced method LQSGW P BE (as compared to LQSGW) still mimics true vertex-corrected GW calculations and improves the bandgap. CoAsSb has a large unit cell (12 atoms), and its symmetry group (P2 1 /c, arsenopyrite-type structure 18 ) has 4 operations. The evaluation of the band energies on sufficiently fine k-mesh in the Brillouin zone is necessary followed by subsequent interpolation to even finer k-mesh used to study transport properties.…”

Electronic structure and thermoelectric properties of CoAsSb with post-DFT approaches

“…The Seebeck coefficient calculated with LQSGW P BE approach is presented in Figure 3 for various doping levels. Zero doping results in a positive Seebeck coefficient at low temperatures and a negative Seebeck coefficient at high temperatures in contrast to the consistent negative Seebeck coefficient from the experiment (Figure 7a in [18]). From a small increase in the doping, the LQSGW P BE curves suddenly become much more similar to the experiment and T max increases.…”

“…LDA resulted in a metallic band structure contradicting with experimental results. 18 Consequently there was a mismatch of the calculated transport properties in accordance with general tendencies discovered in high-throughput calculations. 8 To compare ways of resolving the bandgap issue, authors of the Ref.…”

“…LQSGW results in a band gap of 0.279 eV which is slightly above the experimental range 0.12-0.256 eV. 18 The range of exact exchange in PBE0 (10%-25%) results in bandgaps which cover the experimental uncertainty. For the optimized geometry, we obtained a tiny gap in our DFT calculation (0.005 eV), which can be at- tributed to using GGA instead of LDA as in [18].…”

“…18 The range of exact exchange in PBE0 (10%-25%) results in bandgaps which cover the experimental uncertainty. For the optimized geometry, we obtained a tiny gap in our DFT calculation (0.005 eV), which can be at- tributed to using GGA instead of LDA as in [18]. But with LQSGW, a noticeable overestimation of the band gap (0.441eV) is observed.…”

“…However, the above slightly more advanced method LQSGW P BE (as compared to LQSGW) still mimics true vertex-corrected GW calculations and improves the bandgap. CoAsSb has a large unit cell (12 atoms), and its symmetry group (P2 1 /c, arsenopyrite-type structure 18 ) has 4 operations. The evaluation of the band energies on sufficiently fine k-mesh in the Brillouin zone is necessary followed by subsequent interpolation to even finer k-mesh used to study transport properties.…”

Electronic structure and thermoelectric properties of CoAsSb with post-DFT approaches

First Principles Investigation of Thermoelectric Properties of Naphyne

Virtual Issue on Machine-Learning Discoveries in Materials Science