Current cooling systems, be they refrigerators, freezers or air conditioning units, make use of the compression and expansion of a gas. When the gas is compressed, it changes into a liquid state and when it expands it evaporates once again. To evaporate, it needs heat, which it extracts from the medium it touches and that way cools it down. However, this system is harmful for the environment and, what is more, the compressors used are not particularly effective.
One of the main alternatives that is currently being explored is magnetic cooling. It consists of using a magnetic material instead of a gas, and magnetizing and demagnetizing cycles instead of compression-expansion cycles. Magnetic cooling is a technique based on the magnetocaloric effect, in other words, it is based on the properties displayed by certain materials to modify their temperature when a magnetic field is applied to them. However, the applying of a magnetic field leads to many problems in current miniaturized technological devices (electronic chips, computer memories, etc.), since the magnetic field can interact negatively owing to its effect on nearby units. In this respect, the quest for new ways of controlling the magnetization is crucial.
Magnetism without magnetic fields
The researchers Luis Hueso, Andreas Berger and Odrej Hovorka of nanoGUNE have discovered that by using the straining of materials, they can get around the problems of applying a magnetic field. “By straining the material and then relaxing it an effect similar to that of a magnetic field is created, thus inducing the magnetocaloric effect responsible for cooling,” explains Luis Hueso, leader of the nanodevices group at nanoGUNE and researcher in this study.
“This new technology enables us to have a more local and more controlled cooling method, without interfering with the other units in the device, and in line with the trend in the miniaturization of technological devices,” adds Hueso.
20-nanometre films consisting of lanthanum, calcium, manganese and oxygen (La0.7Ca0.3MnO3) have been developed. According to Hueso, “the aim of this field of research is to find materials that are efficient, economical and environmentally friendly.”
“The idea came about at Cambridge University and among various groups in the United Kingdom, France, Ukraine and the Basque Country we have come up with the right material and an effective technique for cooling electronic chips, computer memories and all these types of applications in microelectronics. Technologically, there would not be any obstacle to using them in fridges, freezers, etc. but economically it is not worthwhile because of the size,” stresses Hueso.
Today, most of the money spent on the huge dataservers goes on cooling. That is why this new technology could be effective in applications of this kind. Likewise, one of the great limitations that computer processors have today is that they cannot operate as fast as one would like because they can easily overheat. “If we could cool them down properly, they would be more effective and could work faster,” adds Hueso.
Dr Hueso stresses that this is a very interesting subject with respect to future patents.
Luis Hueso (Madrid, 1974) is an Ikerbasque researcher and leads the nanodevices team at nanoGUNE. He has a PhD in Physics from the University of Santiago de Compostela. Between 2002 and 2005 he was a Marie Curie fellow at Cambridge University where he developed a project on spin transport in carbon nanotubes. In 2006 he moved to the Consiglio Nazionale delle Ricerche (Italy) and in 2007 was appointed Professor at the University of Leeds. Since 2008, Luis Hueso has been pursuing his scientific research activities in the nanodevices team at nanoGUNE. He has been exploring materials and functionalities to be able to develop new electronic devices that constitute a revolution with respect to the current silicon-based ones, which could soon be reaching the limits of their capacity. It was in fact this work that in 2012 earned him the prestigious Starting Grant awarded by the European Research Council to the tune of 1.3 million euros.
X.Moya, L.E. Hueso, F. Maccherozzi, A.I. Tovstolytkin, D.I. Podyalovskii, C. Ducati, L.C. Phillips, M. Ghidini, O. Hovorka, A. Berger, M.E. Vickers, E. Defay, S.S. Dhesi and N. D. Mathur. Giant and reversible extrinsic magnetocaloric effects in La0.7Ca0.3MnO3 films due to strain. Nature Materials. DOI: 10.1038/NMAT3463.
Irati Kortabitarte | Source: EurekAlert!
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