Enhanced thermal conduction through nanostructured interfaces
Woosung Park, Aditya Sood, Joonsuk Park, Mehdi Asheghi, Robert, Sinclair, Kenneth E. Goodson

TL;DR
This paper demonstrates that nanostructured, nonplanar interfaces with interdigitating pillars significantly enhance thermal conductance beyond traditional planar interfaces, offering new strategies for nanoscale thermal management.
Contribution
It introduces a novel nanostructured interface geometry with interdigitating pillars that surpasses planar interface conductance, supported by experimental and modeling analyses.
Findings
Effective conductance increases as pillar pitch decreases.
Conductance for L_P=200 nm exceeds layered stack predictions.
Nanostructured interfaces can extend to diffusive and quasi-ballistic media.
Abstract
Interfaces dominate heat conduction in nanostructured systems, and much work has focused on methods to enhance interfacial conduction. These approaches generally address planar interfaces, where the heat flux vector is everywhere normal to the interface. Here, we explore a nanostructured interface geometry that uses nonplanar features to enhance the effective interfacial conductance beyond what is possible with planar interfaces. This interface consists of interdigitating Al pillars embedded within SiO2 with characteristic feature size ranging from 100 nm to 800 nm. The total sidewall surface area is modulated to highlight the impact of this additional channel by changing the pillar-to-pillar pitch L_P between 1.6 um and 200 nm while maintaining the same Al:SiO2 fill fraction. Using optical pump-probe thermoreflectance measurements, we show that the effective conductance of a ~65 nm…
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Taxonomy
TopicsThermal properties of materials · Thermal Radiation and Cooling Technologies · Heat Transfer and Optimization
