Publications

Quasi-ballistic thermal transport in silicon carbide nanowires.

Applied Physics Letters 124, 022202 (2024).

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Phonon diffraction and interference using nanometric features.

Journal of Applied Physics 135, 015103 (2024).

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Parabolic mirrors collimating and focusing fluxes of thermal phonons.

Applied Physics Letters 122, 092203 (2023).

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Impact of nanopillars on phonon dispersion and thermal conductivity of silicon membranes.

Nanoscale 15, 2248 (2023).

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In-plane surface phonon-polariton thermal conduction in dielectric multilayer systems.

Applied Physics Letters 121, 202202 (2022).

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Observation of heat transport mediated by the propagation distance of surface phonon-polaritons over hundreds of micrometers.

Applied Physics Letters 121, 112203 (2022).

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Net heat current at zero mean temperature gradient.

Physical Review B 106, L100102 (2022).

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Nanoscale limit of the thermal conductivity in crystalline silicon carbide membranes, nanowires, and phononic crystals.

NPG Asia Materials 14, 35 (2022).

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Review of thermal transport in phononic crystals.

Materials Today Physics 22, 100613 (2022).

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Ballistic heat conduction in semiconductor nanowires.

Journal of Applied Physics 130, 070903 (2021).

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Review of coherent phonon and heat transport control in one-dimensional phononic crystals at nanoscale.

APL Materials 9, 070701 (2021).

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Ray phononics: thermal guides, emitters, filters, and shields powered by ballistic phonon transport.

Materials Today Physics 15, 100272 (2020).

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Cross-plane thermal conductivity in amorphous Si/SiO2 superlattices.

Applied Physics Letters 117, 093103 (2020).

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Enhanced thermal conduction by surface phonon-polaritons.

Science Advances 6, eabb4461 (2020).

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High surface phonon-polariton in-plane thermal conductance along coupled films.

Nanomaterials 10, 1383 (2020).

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Coherent and incoherent impacts of nanopillars on the thermal conductivity in silicon nanomembranes.

ACS Applied Materials & Interfaces 12, 25478 (2020).

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Measurement of the phonon mean free path spectrum in silicon membranes at different temperatures using arrays of nanoslits.

Physical Review B 101, 115301 (2020).

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Semiballistic thermal conduction in polycrystalline SiGe nanowires.

Applied Physics Letters 115, 253101 (2019).

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Thermal conductivity reduction in a silicon thin film with nanocones.

ACS Applied Materials & Interfaces 11, 34394 (2019).

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Probing ballistic thermal conduction in segmented silicon nanowires.

Nanoscale 11, 13407 (2019).

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Thermoelectric enhancement of silicon membranes by ultrathin amorphous films.

ACS Applied Materials and Interfaces 11, 12027 (2019).

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Coherent thermal conduction in silicon nanowires with periodic wings.

Nanomaterials 9, 142 (2019).

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On the reduction and rectification of thermal conduction using phononic crystals with pacman-shaped holes.

Applied Physics Letters 114, 023102 (2019).

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Quasi-ballistic heat conduction due to Lévy phonon flights in silicon nanowires.

ACS Nano 12, 11928 (2018).

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Phonon and heat transport control using pillar-based phononic crystals.

Science and Technology of Advanced Materials 19, 863 (2018).

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Thermal phonon engineering by tailored nanostructures.

Japanese Journal of Applied Physics 57, 080101 (2018).

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Thermal conductivity reduction in silicon fishbone nanowires.

Scientific Reports 8, 4452 (2018).

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Aluminium nanopillars reduce thermal conductivity of silicon nanobeams.

Nanoscale 9, 15083 (2017).

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Heat conduction tuning by wave nature of phonons.

Science Advances 3, e1700027 (2017).

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Thermal conductivity of phononic membranes with aligned and staggered lattices of holes at room and low temperatures.

Physical Review B 95, 205438 (2017).

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Heat guiding and focusing using ballistic phonon transport in phononic nanostructures.

Nature Communications 8, 15505 (2017).

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Patent: 熱電変換材料およびその製造方法.

出願番号: 特願 2017-154070 (2017).

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Patent: 熱 流方向性制御構造.

出願番号: 特願 2017-095459 (2017).

Project

Heat conduction engineering in pillar-based phononic crystals.

Physical Review B 95, 155432 (2017).

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Impact of limiting dimension on thermal conductivity of one-dimensional silicon phononic crystals.

Applied Physics Letters 110, 133108 (2017).

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Ballistic thermal transport in silicon nanowires.

Scientific Reports 7, 41794 (2017).

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Reduction of thermal conductivity by surface scattering of phonons in periodic silicon nanostructures.

Physical Review B 93, 045411 (2016).

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Optical polarization properties of InAs/InP quantum dot and quantum rod nanowires.

Nanotechnology 26, 395701 (2015).

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Thermal conductance boost in phononic crystal nanostructures.

Physical Review B 91, 245417 (2015).

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Impeded thermal transport in Si multiscale hierarchical architectures with phononic crystal nanostructures.

Physical Review B 91, 205422 (2015).

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Piezoelectric effect in InAs/InP quantum rod nanowires grown on silicon substrate.

Applied Physics Letters 104, 183101 (2014).

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Optical properties of InAs/InP nanowire heterostructures.

PhD Thesis in INSA-Lyon (2013).

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Quantum efficiency of InAs/InP nanowire heterostructures grown on silicon substrates.

Physica status solidi (RRL) 7, 878 (2013).

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Polarization properties of single and ensembles of InAs/InP quantum rod nanowires emitting in the telecom wavelengths.

Journal of Applied Physics 113, 193101 (2013).

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Tamm plasmon polaritons in multilayered cylindrical structures.

Physical Review B 86, 235425 (2012).

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Impact of substrate-induced strain and surface effects on the optical properties of InP nanowires.

Applied Physics Letters 101, 072101 (2012).

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Growth temperature dependence of exciton lifetime in wurtzite InP nanowires grown on silicon substrates.

Applied Physics Letters 100, 011906 (2012).

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Wurtzite InP/InAs/InP core–shell nanowires emitting at telecommunication wavelengths on Si substrate.

Nanotechnology 22, 405702 (2011).

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