<p> Scientists have engineered a kind of 'sand' - consisting of silicon dioxide nanoparticles coated with a polymer - that can inexpensively cool power-hungry electronic devices.<br /><br /></p>.<p>The unique surface properties of the coated nanoscale silicon dioxide conducts the heat at potentially higher efficiency than existing heat sink materials, researchers said.<br /><br />The theoretical physics behind the phenomenon is complicated, involving nanoscale electromagnetic effects created on the surface of the tiny silicon dioxide particles acting together.<br /><br />The bottom line could be a potentially new class of high thermal conductivity materials useful for heat dissipation from power electronics, LEDs and other applications with high heat fluxes.<br /><br />"We have shown for the first time that you can take a packed nanoparticle bed that would typically act as an insulator, and by causing light to couple strongly into the material by engineering a high dielectric constant medium like water or ethylene glycol at the surfaces, you can turn the nanoparticle bed into a conductor," said Baratunde Cola, an associate professor at the Georgia Institute of Technology.<br /><br />"Using the collective surface electromagnetic effect of the nanoparticles, the thermal conductivity can increase 20-fold, allowing it to dissipate heat," Cola said.<br /><br />The researchers decided to experiment by first using water to coat the nanoparticles and turn the silicon dioxide nanoparticle bed into a conductor.<br /><br />However, the water coating was not robust, so the researchers switched to ethylene glycol, a fluid commonly used in vehicle antifreeze.<br /><br />The new combination increased the heat transfer by a factor of 20 to about one watt per metre-kelvin, which is higher than the value ethylene glycol or silicon dioxide nanoparticles could produce alone, and competitive with expensive polymer composites used for heat dissipation.<br /><br />"You could basically take an electronic device, pack these ethylene glycol-coated nanoparticles in the air space, and it would be useful as a heat dissipation material that at the same time, won't conduct electricity," said Cola.<br /><br />"The material has the potential to be very inexpensive and easy to work with," he said.<br />Though the ethylene glycol works well, it will eventually evaporate. For that reason, Cola plans to identify polymeric materials that could be adsorbed to the silicon dioxide nanoparticles to provide a more stable coating with a reasonable product lifetime.<br /><br />The effect depends on the collective action of the silicon dioxide nanoparticles.<br />"We are basically showing a macroscopic translation of a nanoscale effect," Cola said.<br />The study was published in the journal Materials Horizons</p>
<p> Scientists have engineered a kind of 'sand' - consisting of silicon dioxide nanoparticles coated with a polymer - that can inexpensively cool power-hungry electronic devices.<br /><br /></p>.<p>The unique surface properties of the coated nanoscale silicon dioxide conducts the heat at potentially higher efficiency than existing heat sink materials, researchers said.<br /><br />The theoretical physics behind the phenomenon is complicated, involving nanoscale electromagnetic effects created on the surface of the tiny silicon dioxide particles acting together.<br /><br />The bottom line could be a potentially new class of high thermal conductivity materials useful for heat dissipation from power electronics, LEDs and other applications with high heat fluxes.<br /><br />"We have shown for the first time that you can take a packed nanoparticle bed that would typically act as an insulator, and by causing light to couple strongly into the material by engineering a high dielectric constant medium like water or ethylene glycol at the surfaces, you can turn the nanoparticle bed into a conductor," said Baratunde Cola, an associate professor at the Georgia Institute of Technology.<br /><br />"Using the collective surface electromagnetic effect of the nanoparticles, the thermal conductivity can increase 20-fold, allowing it to dissipate heat," Cola said.<br /><br />The researchers decided to experiment by first using water to coat the nanoparticles and turn the silicon dioxide nanoparticle bed into a conductor.<br /><br />However, the water coating was not robust, so the researchers switched to ethylene glycol, a fluid commonly used in vehicle antifreeze.<br /><br />The new combination increased the heat transfer by a factor of 20 to about one watt per metre-kelvin, which is higher than the value ethylene glycol or silicon dioxide nanoparticles could produce alone, and competitive with expensive polymer composites used for heat dissipation.<br /><br />"You could basically take an electronic device, pack these ethylene glycol-coated nanoparticles in the air space, and it would be useful as a heat dissipation material that at the same time, won't conduct electricity," said Cola.<br /><br />"The material has the potential to be very inexpensive and easy to work with," he said.<br />Though the ethylene glycol works well, it will eventually evaporate. For that reason, Cola plans to identify polymeric materials that could be adsorbed to the silicon dioxide nanoparticles to provide a more stable coating with a reasonable product lifetime.<br /><br />The effect depends on the collective action of the silicon dioxide nanoparticles.<br />"We are basically showing a macroscopic translation of a nanoscale effect," Cola said.<br />The study was published in the journal Materials Horizons</p>