posted on 2021-04-13, 17:37authored byMohammadreza Shahzadeh, Olga Andriyevska, Ruslan Salikhov, Lorenzo Fallarino, Olav Hellwig, Simone Pisana
Despite the numerous reports over
the last two decades dedicated
to the study of interfacial thermal transport, physics of thermal
transport across nanoscale metallic multilayers is less explored.
This is in part due to the relatively high conductance characteristic
of these interfaces, which renders them difficult to characterize.
Interfacial transport in these systems has so far appeared to be diffusive,
a surprising behavior when the interface density increases and the
layer thicknesses become comparable with the mean free path of electrons.
To address the limit of diffusive theories describing heat transport
across high-density metallic interfaces, we systematically investigate
heat transport in and across Pt/Co multilayers via frequency domain
thermoreflectance. Sensitivity gained from offsetting the laser beam
and reducing the laser spot size allows for the measurement of anisotropic
thermal conductivity of the multilayers. By changing the number of
interfaces while keeping the overall thickness of Pt and Co in the
multilayer structure constant, the effect of interface density on
the multilayers’ effective thermal conductivity is studied.
The extracted Pt/Co interface thermal boundary conductance is then
compared to the calculations from the electronic diffuse mismatch
model and experimental data available in the literature. We show that
as the multilayer period thickness becomes much smaller than the electron
mean free path, measurements markedly deviate from the diffusive transport
theory. We attribute this deviation to the nondiffusive nature of
heat transport in subnanometric scales at interface densities above
1/nm.