Journal
NANOSCALE AND MICROSCALE THERMOPHYSICAL ENGINEERING
Volume 25, Issue 1, Pages 1-24Publisher
TAYLOR & FRANCIS INC
DOI: 10.1080/15567265.2021.1881193
Keywords
Nonequilibrium Green's functions; atomistic Green's functions; thermal transport; phonon transport
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Funding
- Office of Science of the U.S. Department of Energy [DE-AC02-05CH11231]
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Recent advances in fabrication techniques have enabled the development of materials sculpted at the nanoscale, revolutionizing thermal management technologies. Atomistic simulations are crucial for understanding dynamics on an atomic level, with nonequilibrium Green's functions (NEGF) simulations focusing on vibrational energy propagation. NEGF methodology, whether including harmonic interatomic potentials (h-NEGF) or anharmonic terms (a-NEGF), presents challenges and potential for quantum mechanical description of thermal transport.
Recent advances in fabrication techniques have enabled the development of materials sculpted at the nanoscale (similar to 10 nm). These nano-materials could revolutionize thermal management technologies by providing novel ways to manipulate energy propagation in solids. Atomistic simulations are critical to forging this revolution, given their ability to describe a system's dynamics on an atom by atom basis. This topical review focuses on nonequilibrium Green's functions (NEGF) simulations to model vibrational energy propagation at the nanoscale. NEGF is an atomistic and purely quantum mechanical approach well-suited to compute thermal transport in spatially varying systems such as nano-materials. This review presents the NEGF methodology from a top-to-bottom perspective, focusing on the concepts behind the mathematical expressions. We start describing the implementation of NEGF that assumes harmonic interatomic potentials (h-NEGF) and some recent advances that distinguish the transport contributions by different polarizations. This review also discusses the less common implementation of NEGF that includes the anharmonic terms of the potentials (a-NEGF), outlining existing approximations and standing challenges. Our success in tackling these challenges will determine whether we will harness the full potential of NEGF to describe thermal transport from a quantum mechanical standpoint.
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