The thermal conductive properties, including the thermal diffusivity and resultant thermal conductivity, of nonwoven nanocellulose sheets were investigated by separately measuring the thermal diffusivity of the sheets in the in-plane and thickness directions with a periodic heating method. The cross-sectional area (or width) of the cellulose crystallites was the main determinant of the thermal conductive properties. Thus, the results strongly indicate that there is a crystallite size effect on phonon conduction within the nanocellulose sheets. The results also indicated that there is a large interfacial thermal resistance between the nanocellulose surfaces. The phonon propagation velocity (i.e., the sound velocity) within the nanocellulose sheets was estimated to be ∼800 m/s based on the relationship between the thermal diffusivities and crystallite widths. The resulting in-plane thermal conductivity of the tunicate nanocellulose sheet was calculated to be ∼2.5 W/mK, markedly higher than other plastic films available for flexible electronic devices.
We
developed flexible polymeric “heat-guiding materials”
by simply drawing bacterial cellulose (BC) hydrogels to align the
cellulose nanofibers and form “nanopapers” with anisotropic
thermal conductivity. The in-plane anisotropy of thermal conductivity
between the drawn and transverse directions increased as the draw
ratio increased. For the drawn BC nanopapers, the coefficient of thermal
expansion was found to be inversely correlated with the thermal diffusivity.
We fabricated a planar spiral sheet by assembling the drawn BC strips
to visualize the “heat flux controllability”. The coexistence
of heat-diffusing and heat-insulating capacities within the single
nanopaper plane could help to cool future thin electronics.
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