论文信息 - Effect of linear temperature dependence of thermoelectric properties on energy conversion efficiency

Effect of linear temperature dependence of thermoelectric properties on energy conversion efficiency

Abstract New thermal rate equations were developed by taking the temperature dependences of the electrical resistivity ρ and thermal conductivity κ of the thermoelectric (TE) materials into the thermal rate equations on the assumption that they vary linearly with temperature T . The relative energy conversion efficiency η / η 0 for a single TE element was formulated by approximate analysis, where η and η 0 are the energy conversion efficiencies derived from the new and conventional thermal rate equations, respectively. Applying it to Si–Ge alloys, the temperature dependence of ρ is stronger than that of κ , so the former has a more significant effect on η / η 0 than the latter. However, the degree of contribution from both of them to η / η 0 was a little lower than 1% at the temperature difference Δ T of 600 K. When the temperature dependence of κ was increased to become equal to that of ρ , however, it was found that η / η 0 is increased by about 10% at Δ T = 600 K. It is clarified here that the temperature dependences of ρ and κ are also important factors for an improvement in η .

Osamu Yamashita | O. Yamashita

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