Isaac M. Felix scite author profile

Superlattices are ideal model systems for the realization and understanding of coherent (wave-like) and incoherent (particle-like) phonon thermal transport. Single layer heterostructures of graphene and hexagonal boron nitride have been produced recently with sharp edges and controlled domain sizes. In this study we employ nonequilibrium molecular dynamics simulations to investigate the thermal conductivity of superlattice nanoribbons with equal-sized domains of graphene and hexagonal boron nitride. We analyze the dependence of the conductivity with the domain sizes, and with the total length of the ribbons. We determine that the thermal conductivity reaches a minimum value of 89 W m−1K−1 for ribbons with a superlattice period of 3.43 nm. The effective phonon mean free path is also determined and shows a minimum value of 32 nm for the same superlattice period. Our results also reveal that a crossover from coherent to incoherent phonon transport is present at room temperature for BNC nanoribbons, as the superlattice period becomes comparable to the phonon coherence length. Analyzing phonon populations relative to the smallest superlattice period, we attribute the minimum thermal conductivity to a reduction in the population of flexural phonons when the superlattice period equals 3.43 nm. The ability to manipulate thermal conductivity using superlattice-based two-dimensional materials, such as graphene-hBN nanoribbons, opens up opportunities for application in future nanostructured thermoelectric devices.

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Suppression of coherent thermal transport in quasiperiodic graphene-hBN superlattice ribbons

Felix

Pereira

2020

Carbon

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Nanostructured superlattices are promising materials for novel electronic devices due to their adjustable physical properties. Periodic superlattices facilitate coherent phonon thermal transport due to constructive wave interference at the boundaries between the materials.However, it is possible to induce a crossover from coherent to incoherent transport regimes by adjusting the superlattice period. We have recently observed such crossover in periodic graphene-boron nitride nanoribbons as the length of individual domains was increased. In

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Electronic, optical and thermoelectric properties of boron-doped nitrogenated holey graphene

Tromer

Freitas

Felix

et al. 2020

Phys. Chem. Chem. Phys.

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Diboron-porphyrin monolayer: A new 2D semiconductor

Tromer

Felix

Freitas

et al. 2020

Computational Materials Science

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Thermal conductivity of Thue–Morse and double-period quasiperiodic graphene-hBN superlattices

Felix

Pereira

2022

International Journal of Heat and Mass Transfer

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Isaac M. Felix

Thermal Conductivity of Graphene-hBN Superlattice Ribbons

Suppression of coherent thermal transport in quasiperiodic graphene-hBN superlattice ribbons

Electronic, optical and thermoelectric properties of boron-doped nitrogenated holey graphene

Diboron-porphyrin monolayer: A new 2D semiconductor

Thermal conductivity of Thue–Morse and double-period quasiperiodic graphene-hBN superlattices

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