Thursday, 4 July 2013

Graphene Provides Efficient Electronics Cooling

Graphene Provides Efficient Electronics Cooling

July 3, 2013 — A layer of graphene can reduce the working temperature in hotspots inside a processor by up to 25 percent -- which can significantly extend the working life of computers and other electronics. An international group of researchers, headed by Chalmers University of Technology in Sweden, are the first in the world to show that graphene has a heat dissipating effect on silicon based electronics.
An electronic component where a graphene layer has been placed on the hotspots. (Credit: Image courtesy of Chalmers University of Technology)
"This discovery opens the door to increased functionality and continues to push the boundaries when it comes to miniaturising electronics," said Chalmers Professor Johan Liu who heads the international research project.
Modern electronic systems generate a great deal of heat, above all due to the constantly increasing demand for more and more functionality. It is important to be able to remove the heat generated in an efficient way to maintain the long life of the system. One rule of thumb is that a 10-degree Celsius increase in working temperature halves the working life of an electronics system.
During the study, the researchers focused on reducing the temperature in the small area where the electronics work most intensively -- such as inside a processor, for instance. These tiny hotspots are found in all electronics. Size wise, they are on a micro or nano scale, in other words a thousandth of a millimetre or smaller.
"The normal working temperature in the hotspots we have cooled with a graphene layer has ranged from 55 to 115 degrees Celsius. We have been able to reduce this by up to 13 degrees, which not only improves energy efficiency, it also extends the working life of the electronics."
Efficient cooling is a major challenge in many different applications, such as automotive electronics, power electronics, computers, radio base stations and in various light emitting diodes, or LED lights. In automotive electronics systems, any single device in the ignition system can pump out up to 80 W continuously and in transient stage up to 300 W (within 10 nanoseconds). LED devices can have a thermal intensity almost on a par with the sun, up to 600 W/cm2 due to their extremely small size.
Superior cooling of electronics can deliver tremendous advantages. According to a study in the USA based on data from 2006, around 50 percent of the total electricity used to run data servers goes on cooling the systems.

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