Ab initio optimization of phonon drag effect for lower-temperature thermoelectric energy conversion

Abstract: Although the thermoelectric figure of merit zT above 300 K has seen significant improvement recently, the progress at lower temperatures has been slow, mainly limited by the relatively low Seebeck coefficient and high thermal conductivity. Here we report, for the first time to our knowledge, success in first-principles computation of the phonon drag effect-a coupling phenomenon between electrons and nonequilibrium phonons-in heavily doped region and its optimization to enhance the Seebeck coefficient while red… Show more

“…In a later study using a full first-principles calculation with both electron and phonon relaxation times extracted from DFT calculations, the Seebeck coefficient including the phonon drag was predicted with excellent agreements compared to the experiment [126], as shown in Fig. 11a.…”

“…It was shown that at room temperature in lightly-doped n-type (p-type) silicon the phonon drag contribute to 30% (40%) of the total Seebeck coefficient [126]. As we have mentioned, phonon drag effect can be understood as the momentum transfer from non-equilibrium phonons with long mean free paths to the electron system.…”

“…This emphasizes the use of a first-principles approach for better description of coupled electron-phonon transport. These calculations [125,126] quantitatively investigated the temperature dependence of the phonon drag effect:…”

“…For example, one can enhance the thermoelectric performance by filtering out short-mean-free-path phonons, in which case the phonon drag will be retained but the thermal conductivity can be reduced, a strategy recently proposed in Ref. [126]. Furthermore, by considering the phonon scattering by electrons in the phonon relaxation time calculation, the reduction of the phonon drag effect at higher carrier concentrations, known as the saturation effect [39], can also be captured by the fully first-principles approach [126], with a good agreement with the experiment shown in Fig.…”

“…However, up to now there are only few materials whose mobility or Seebeck coefficient has been calculated using a parameter-free first-principles approach, with examples including silicon, MoS2 and phosphorene [36][37][38]126,127]. Here we deem the use of the deformation potential model (even with deformation potential extracted from the first-principles) as an complementary but not a predictive method, because it neglects the electron-state-dependence of the electron-phonon coupling, which is hardly justified for general materials, especially considering the fact that the material search has been going towards more complex ones.…”

First-principles calculations of thermal, electrical, and thermoelectric transport properties of semiconductors

“…In a later study using a full first-principles calculation with both electron and phonon relaxation times extracted from DFT calculations, the Seebeck coefficient including the phonon drag was predicted with excellent agreements compared to the experiment [126], as shown in Fig. 11a.…”

“…It was shown that at room temperature in lightly-doped n-type (p-type) silicon the phonon drag contribute to 30% (40%) of the total Seebeck coefficient [126]. As we have mentioned, phonon drag effect can be understood as the momentum transfer from non-equilibrium phonons with long mean free paths to the electron system.…”

“…This emphasizes the use of a first-principles approach for better description of coupled electron-phonon transport. These calculations [125,126] quantitatively investigated the temperature dependence of the phonon drag effect:…”

“…For example, one can enhance the thermoelectric performance by filtering out short-mean-free-path phonons, in which case the phonon drag will be retained but the thermal conductivity can be reduced, a strategy recently proposed in Ref. [126]. Furthermore, by considering the phonon scattering by electrons in the phonon relaxation time calculation, the reduction of the phonon drag effect at higher carrier concentrations, known as the saturation effect [39], can also be captured by the fully first-principles approach [126], with a good agreement with the experiment shown in Fig.…”

“…However, up to now there are only few materials whose mobility or Seebeck coefficient has been calculated using a parameter-free first-principles approach, with examples including silicon, MoS2 and phosphorene [36][37][38]126,127]. Here we deem the use of the deformation potential model (even with deformation potential extracted from the first-principles) as an complementary but not a predictive method, because it neglects the electron-state-dependence of the electron-phonon coupling, which is hardly justified for general materials, especially considering the fact that the material search has been going towards more complex ones.…”

First-principles calculations of thermal, electrical, and thermoelectric transport properties of semiconductors

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