Masato Ohnishi scite author profile

The potential impact of encapsulated molecules on the thermal properties of individual carbon nanotubes (CNTs) has been an important open question since the first reports of the strong modulation of electrical properties in 2002. However, thermal property modulation has not been demonstrated experimentally because of the difficulty of realizing CNT-encapsulated molecules as part of thermal transport microstructures. Here we develop a nanofabrication strategy that enables measurement of the impact of encapsulation on the thermal conductivity (κ) and thermopower (S) of single CNT bundles that encapsulate C , Gd@C and Er @C. Encapsulation causes 35-55% suppression in κ and approximately 40% enhancement in S compared with the properties of hollow CNTs at room temperature. Measurements of temperature dependence from 40 to 320 K demonstrate a shift of the peak in the κ to lower temperature. The data are consistent with simulations accounting for the interaction between CNTs and encapsulated fullerenes.

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Machine-Learning-Optimized Aperiodic Superlattice Minimizes Coherent Phonon Heat Conduction

Iwamoto

Feng

et al. 2020

Phys. Rev. X

102

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Multifunctional structural design of graphene thermoelectrics by Bayesian optimization

et al. 2018

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Effects of defects on thermoelectric properties of carbon nanotubes

2017

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Carbon nanotubes (CNTs) have recently attracted attention as materials for flexible thermoelectric devices. To provide theoretical guideline of how defects influence the thermoelectric performance of CNTs, we theoretically studied the effects of defects (vacancies and Stone-Wales defects) on its thermoelectric properties; thermal conductance, electrical conductance, and Seebeck coefficient. The results revealed that the defects mostly strongly suppresses the electron conductance, and deteriorates the thermoelectric performance of a CNT. By plugging in the results and the intertube-junction properties into the network model, we further show that the defects with realistic concentrations can significantly degrade the thermoelectric performance of CNT-based networks. Our findings indicate the importance of the purification of CNTs for improving CNT-based thermoelectrics.

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Incremental Construction of Delaunay Overlaid Network for Virtual Collaborative Space

Ohnishi

Nishide

Ueshima

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Masato Ohnishi

Modulation of thermal and thermoelectric transport in individual carbon nanotubes by fullerene encapsulation

Machine-Learning-Optimized Aperiodic Superlattice Minimizes Coherent Phonon Heat Conduction

Multifunctional structural design of graphene thermoelectrics by Bayesian optimization

Effects of defects on thermoelectric properties of carbon nanotubes

Incremental Construction of Delaunay Overlaid Network for Virtual Collaborative Space

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