Thermal bridging of graphene nanosheets via covalent molecular junctions. a Non-Equilibrium Green Functions Density Functional Tight-Binding study
Diego Martinez, Alessandro di Pierro, Alessandro Pecchia, Leonardo, Medrano Sandonas, Rafael Gutierrez, Mar Bernal, Bohayra Mortazavi,, Gianaurelio Cuniberti, Guido Saracco, Alberto Fina

TL;DR
This study uses advanced computational methods to analyze how different molecular junctions affect heat transfer between graphene nanosheets, aiming to improve thermal conductance in nanomaterials.
Contribution
It provides detailed theoretical insights into how molecular junction structure influences phonon transfer and thermal conductance between graphene sheets, guiding experimental design.
Findings
Molecular junction length and conformation significantly affect phonon tunneling.
Aromaticity of molecules influences thermal conductance.
Designing molecular junctions can optimize heat transfer in graphene-based nanomaterials.
Abstract
Despite the uniquely high thermal conductivity of graphene is well known, the exploitation of graphene into thermally conductive nanomaterials and devices is limited by the inefficiency of thermal contacts between the individual nanosheets. A fascinating yet experimentally challenging route to enhance thermal conductance at contacts between graphene nanosheets is through molecular junctions, allowing covalently connecting nanosheets otherwise interacting only via weak Van der Waals forces. Beside the bare existence of covalent connections, the choice of molecular structures to be used as thermal junctions should be guided by their vibrational properties, in terms of phonon transfer through the molecular junction. In this paper, density functional tight-binding combined with Green functions formalism was applied for the calculation of thermal conductance and phonon spectra of several…
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