3 June 2009
Heat is on for NEMS
With just a small technological breakthrough, nanoelectromechanical systems (NEMS) devices can revolutionize the world of sensors: motion, chemical, temperature.
But taking electromechanical devices from the micro scale down to the nano requires finding a means to dissipate the heat output of this tiny gadgetry.
The solution is to build these devices using a thermal material that naturally dissipates heat from the device’s center through a hierarchical branched network of carbon nanotubes, said Professor Markus Buehler and postdoctoral associate Zhiping Xu of MIT’s Department of Civil and Environmental Engineering, who also wrote a paper on the subject.
The template for this thermal material’s design is a living cell, specifically, the hierarchical protein networks that allow a cell’s nucleus to communicate with the cell’s outermost regions.
“The structure now used when designing materials with carbon nanotubes resembles spaghetti,” said Buehler, who studies protein-based materials at the nano and atomistic scales with the goal of using biomimetic-engineering principles to design human-made materials.
“We show that a precise arrangement of carbon nanotubes similar to those found in the cytoskeleton of cells will create a thermal material that effectively dissipates heat, which could prevent a NEMS device from failing or melting,” he said.
NEMS devices are extremely small, high-density heat sources that cannot undergo cooling in the traditional sense. Even the microelectromechanical systems (MEMS) devices used in automobiles and electronics are hard to cool because conventional thermal management strategies such as fans, fluids, pastes, and wiring often do not work at these small scales; heat buildup in MEMS frequently leads to catastrophic device failure, which limits the reliability of larger systems.
But the number of heat-conducting fibers or carbon nanotubes (CNTs) that connect to the heat source at the center of a NEMS device sees limits with the physical size of the heat source itself. Buehler and Xu said a simple geometric structure—a branched-tree hierarchy of at least two branches sprouting off each branch—is far more effective at heat dissipation than the non-hierarchical “spaghetti” of most existing CNT-based material.
They show a single fiber (or branch) connected to the heat source, with 99 additional branched links between it and the heat sink, will provide the same dissipation effect as if 50 long fibers connected directly to the heat source. If five carbon nanotubes are in direct connection to the heat source, each of which uses this branched-tree hierarchical structure, the heat dissipation will be the equivalent of 250 direct connections from the heat source to an external heat sink.
“Our paper provides a breakthrough in the understanding of how nanostructural elements can be utilized effectively to bridge scales from the nano to macro through formation of hierarchical structures,” Xu said. “The results could change the way nanodevices are designed and fabricated by enabling technological innovations for highly integrated systems.”
For related information, go to www.isa.org/manufacturing_automation.