Thermoelectric Properties of InA Nanowires from Full-Band Atomistic Simulations

Thermoelectric Properties of InA Nanowires from Full-Band Atomistic Simulations

In this work we theoretically explore the effect of dimensionality on the thermoelectric power factor of indium arsenide (InA) nanowires by coupling atomistic tight-binding calculations to the Linearized Boltzmann transport formalism. We consider nanowires with diameters from 40 nm (bulk-like) down...

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Bibliographic Details
Published in:Molecules (Basel, Switzerland) Vol. 25; no. 22; p. 5350
Main Authors: Archetti, Damiano, Neophytou, Neophytos
Format: Journal Article
Language:English
Published: Switzerland MDPI AG 16-11-2020
MDPI
Subjects:
Arsenic
Arsenicals - chemistry
Calibration
Computer applications
Computer Simulation
Conductivity
Electric Conductivity
electrical conductivity
electron mobility
Electronics
Heat conductivity
InAs nanowires
Indium
Indium - chemistry
Indium arsenides
Investigations
Lorenz number
Nanotechnology
Nanowires
Nanowires - chemistry
Phonons
Power factor
Quantum dots
Scattering
Seebeck coefficient
Seebeck effect
Surface roughness
Thermal Conductivity
Thermoelectricity
thermoelectrics
Seebeck coefficient
InAs nanowires
polar optical phonons
electron mobility
thermoelectrics
sp3d5s tight-binding model
Semiclassical Boltzmann transport
electrical conductivity
power factor
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Summary:In this work we theoretically explore the effect of dimensionality on the thermoelectric power factor of indium arsenide (InA) nanowires by coupling atomistic tight-binding calculations to the Linearized Boltzmann transport formalism. We consider nanowires with diameters from 40 nm (bulk-like) down to 3 nm close to one-dimensional (1D), which allows for the proper exploration of the power factor within a unified large-scale atomistic description across a large diameter range. We find that as the diameter of the nanowires is reduced below < 10 nm, the Seebeck coefficient increases substantially, as a consequence of strong subband quantization. Under phonon-limited scattering conditions, a considerable improvement of ~6× in the power factor is observed around = 10 nm. The introduction of surface roughness scattering in the calculation reduces this power factor improvement to ~2×. As the diameter is decreased to = 3 nm, the power factor is diminished. Our results show that, although low effective mass materials such as InAs can reach low-dimensional behavior at larger diameters and demonstrate significant thermoelectric power factor improvements, surface roughness is also stronger at larger diameters, which takes most of the anticipated power factor advantages away. However, the power factor improvement that can be observed around = 10 nm could prove to be beneficial as both the Lorenz number and the phonon thermal conductivity are reduced at that diameter. Thus, this work, by using large-scale full-band simulations that span the corresponding length scales, clarifies properly the reasons behind power factor improvements (or degradations) in low-dimensional materials. The elaborate computational method presented can serve as a platform to develop similar schemes for two-dimensional (2D) and three-dimensional (3D) material electronic structures.
ISSN:1420-3049
1420-3049
DOI:10.3390/molecules25225350