ResearchGateBeyond the State of the Art: Novel Approaches for Thermal and Electrical Transport in Nanoscale Devices
Entropy 21, 752 (2019).
R. Biele, and R. D’Agosta.
Journal DOI: https://doi.org/10.3390/e21080752

Almost any interaction between two physical entities can be described through the transfer of either charge, spin, momentum, or energy. Therefore, any theory able to describe these transport phenomena can shed light on a variety of physical, chemical, and biological effects, enriching our understanding of complex, yet fundamental, natural processes, eg, catalysis or photosynthesis. In this review, we will discuss the standard workhorses for transport in nanoscale devices, namely Boltzmann’s equation and Landauer’s approach. We will emphasize their strengths, but also analyze their limits, proposing theories and models useful to go beyond the state of the art in the investigation of transport in nanoscale devices.

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©https://doi.org/10.3390/e21080752
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ResearchGateBeyond the State of the Art: Novel Approaches for Thermal and Electrical Transport in Nanoscale Devices
Entropy 21, 752 (2019).
R. Biele, and R. D’Agosta.
Journal DOI: https://doi.org/10.3390/e21080752

Almost any interaction between two physical entities can be described through the transfer of either charge, spin, momentum, or energy. Therefore, any theory able to describe these transport phenomena can shed light on a variety of physical, chemical, and biological effects, enriching our understanding of complex, yet fundamental, natural processes, eg, catalysis or photosynthesis. In this review, we will discuss the standard workhorses for transport in nanoscale devices, namely Boltzmann’s equation and Landauer’s approach. We will emphasize their strengths, but also analyze their limits, proposing theories and models useful to go beyond the state of the art in the investigation of transport in nanoscale devices.

Cover
©https://doi.org/10.3390/e21080752
Share


Involved Scientists