The Fragility of Thermoelectric Power Factor in Cross-Plane Superlattices in the Presence of Nonidealities: A Quantum Transport Simulation Approach

Abstract: Original citation: Thesberg, M., Pourfath, M., Neophytou, Neophytos and Kosina, H.. (2016) The fragility of thermoelectric power factor in cross-plane superlattices in the presence of nonidealities : a quantum transport simulation approach. Journal of Electronic Materials, 45 (3). pp. 1584-1588. Permanent WRAP url:http://wrap.warwick.ac.uk/77432 Copyright and reuse:The Warwick Research Archive Portal (WRAP) makes this work by researchers of the University of Warwick available open access under the following c… Show more

“…An important effect that needs to be considered in evaluating the influence of nanoinclusions on the power factor of nanocomposites is quantummechanical tunneling. In prior works related to the effect of tunneling in superlattices, we have shown that tunneling is detrimental to the Seebeck coefficient as it makes potential barriers transparent and takes away any benefits that energy filtering could provide to the power factor [65,66]. We have shown that in the case of superlattices tunneling becomes important when the thicknesses of the barriers drop below 1-2 nm (for channels with effective mass m * = m 0 ).…”

“…The presence of impurity scattering as well as variation in the thermal conductivities of the different regions can also improve the Seebeck coefficient even further as explained in Refs. [21,58,65,66], which might allow for higher power factors compared to what we compute here.…”

“…The behavior in the presence of NIs is different, because the charge carriers flow not only above the NI barriers, but in between them as well. This means the NIs still allow a finite transmission of carriers across low energies, and thus, do not provide the energy filtering effect and large Seebeck coefficients that can be achieved in superlattices [58,65,66].…”

“…Another important variability case that is beneficial to the power factor is the variation in the lattice thermal conductivity between the different materials that form the nanocomposite. In superlattices, for example, a lower lattice thermal conductivity in the barrier regions which have a higher local Seebeck coefficient, results in a larger overall increase in the Seebeck coefficient [21,55,65]. We have not investigated this effect here, however it might be the case that such an effect might not be utilized strongly for NIs as their filtering capabilities are weaker.…”

“…In reality, in the vicinity of the heterojunction there will be potential variations that will affect the shape of the barrier, which as we show in Refs. [64] and [65], could be important in determining the PF. These potential variations are determined by the junction details, but also by the doping of the different regions and could only be captured accurately through self-consistent calculations, which we do not consider in this work.…”

Thermoelectric power factor of nanocomposite materials from two-dimensional quantum transport simulations

“…An important effect that needs to be considered in evaluating the influence of nanoinclusions on the power factor of nanocomposites is quantummechanical tunneling. In prior works related to the effect of tunneling in superlattices, we have shown that tunneling is detrimental to the Seebeck coefficient as it makes potential barriers transparent and takes away any benefits that energy filtering could provide to the power factor [65,66]. We have shown that in the case of superlattices tunneling becomes important when the thicknesses of the barriers drop below 1-2 nm (for channels with effective mass m * = m 0 ).…”

“…The presence of impurity scattering as well as variation in the thermal conductivities of the different regions can also improve the Seebeck coefficient even further as explained in Refs. [21,58,65,66], which might allow for higher power factors compared to what we compute here.…”

“…The behavior in the presence of NIs is different, because the charge carriers flow not only above the NI barriers, but in between them as well. This means the NIs still allow a finite transmission of carriers across low energies, and thus, do not provide the energy filtering effect and large Seebeck coefficients that can be achieved in superlattices [58,65,66].…”

“…Another important variability case that is beneficial to the power factor is the variation in the lattice thermal conductivity between the different materials that form the nanocomposite. In superlattices, for example, a lower lattice thermal conductivity in the barrier regions which have a higher local Seebeck coefficient, results in a larger overall increase in the Seebeck coefficient [21,55,65]. We have not investigated this effect here, however it might be the case that such an effect might not be utilized strongly for NIs as their filtering capabilities are weaker.…”

“…In reality, in the vicinity of the heterojunction there will be potential variations that will affect the shape of the barrier, which as we show in Refs. [64] and [65], could be important in determining the PF. These potential variations are determined by the junction details, but also by the doping of the different regions and could only be captured accurately through self-consistent calculations, which we do not consider in this work.…”

Thermoelectric power factor of nanocomposite materials from two-dimensional quantum transport simulations

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