Super-Suppression of Long Phonon Mean-Free-Paths in Nano-engineered Si due to Heat Current Anticorrelations.

The ability to minimize the thermal conductivity of dielectric materials with a minimal structural intervention that could affect electrical properties is an important tool for engineering good thermoelectric efficiency in low-cost semiconductor materials such as Si. Special arrangements for pores in nanoporous Si have been recently identified in our previous work to produce a particularly large reduction in thermal conductivity accompanied by strongly anticorrelated heat current fluctuations. This manuscript presents the results of molecular dynamics simulations and a Monte Carlo ray-tracing model that further teases apart this phenomenon to reveal how the special pore layouts produce correlated scattering of the heat-carrying phonons. This means that heat carried by a phonon before scattering is undone by the scattered phonon, resulting in an effective mean-free-path which is significantly shorter than the distance that the phonons travel between the pores. This effect is particularly noticeable for the long wavelength, long mean-free-path phonons whose transport is impeded drastically more than what expected purely from the usual considerations of scattering defined by the distance between defects. This super suppression of the mean-free-path below the characteristic scale of the nanostructuring offers a route for minimizing thermal conductivity with minimal structural impact, while the stronger impact on long wavelengths offer possibilities for the design of `band-pass' phonon filtering. Moreover, the ray-tracing model developed in this paper shows that different forms of correlated scattering imprint a unique signature in the heat current autocorrelation function that could be used as a diagnostic in other nanostructured systems.