Monday, April 16, 2018

Holey Silicon May Be The Holy Grail of Electronics?

Electronics miniaturization has put high-powered computing capability into the hands of ordinary people, but the ongoing downsizing of integrated circuits is challenging engineers to come up with new ways to thwart component overheating.

Scientists at the University of California, Irvine made a breakthrough recently in verifying a new material configuration to facilitate cooling. In a study in the journal Nanotechnology, members of UCI’s Nano Thermal Energy Research Group highlight the attributes of holey silicon, a computer chip wafer with tiny, vertically etched orifices that work to shuttle heat to desired locations.

“We found that heat prefers to travel vertically through but not laterally across holey silicon, which means the material can effectively move the heat from local hot spots to on-chip cooling systems in the vertical direction while sustaining the necessary temperature gradient for thermoelectric junctions in the lateral direction,” said corresponding author Jaeho Lee, UCI assistant professor of mechanical & aerospace engineering.

Jaeho Lee, UCI assistant professor of mechanical & aerospace engineering, believes that holey silicon – microchip material vertically etched with nanoscale orifices – might be a breakthrough in the quest to keep modern electronics cool. 

Credit: Steve Zylius / UCI


“This innovation could potentially be ideal for keeping electronic devices such as smartphones cool during operation,” said lead author Zongqing Ren, a graduate student researcher in the NTERG.

He said that lab simulations demonstrated that the cooling effectiveness of holey silicon is at least 400 percent better than chalcogenides, compounds commonly used in thermoelectric cooling devices.

The lab’s holey silicon research is a follow-on to a study published in Nature Communications in early 2017 in which Lee, as lead author, and his UC Berkeley-based collaborators employed nanometer-scale silicon mesh material to investigate properties of phonons, quasiparticles that give scientists insight into thermal transport mechanisms.

“We know that phonons can show wave-like as well as particle-like behavior during thermal transport,” Lee said. “Using meshes with different hole sizes and spacing, we were able to clarify complex thermal transport mechanisms at the nanoscale.”

Knowledge gained from the earlier study helped his team understand how small, neck-shaped structures created by the etched holes in holey silicon cause phonon backscattering, a particle effect leading to low in-plane thermal conductivity. High cross-plane thermal conductivity was caused by long-wavelength phonons that help to move heat away. 

Lee said the temperature problem in electronics has grown in the past few years as microchip designers seem to have reached a size boundary. With larger components, manufacturers can use heat sinks, fins and even fans to funnel warmth away from critical hardware. On today’s densely packed chips with billions of nanoscale transistors – often sandwiched in slim, pocketable consumer products – there’s no room for such cooling technologies.

Other key issues are longevity and reliability. Semiconductor chips are being embedded in many new places – acting as sensors and actuators in cars and appliances and as nodes along the internet of things. These devices are expected to run continuously for years and even decades. Prolonged exposure to heat could cause the failure of such infrastructure.

“On one hand, nanotechnology has opened up a whole new world of possibilities, but on the other, it’s created a host of challenges,” Lee said. “It’s important that we continue to develop a better understanding of the fundamentals of thermal transport and find ways to control heat transfer at the nanoscale.”




Contacts and sources:
Brian Bell
University of California, Irvine

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