The
Royal Swedish Academy of Sciences has decided
to award the Nobel Prize in Physics for 2007 jointly to
Albert Fert
Unité Mixte de Physique CNRS/THALES, Université Paris-Sud, Orsay, France,
Unité Mixte de Physique CNRS/THALES, Université Paris-Sud, Orsay, France,
and
Peter Grünberg
Forschungszentrum Jülich, Germany,
"for the discovery of Giant Magnetoresistance".
Forschungszentrum Jülich, Germany,
"for the discovery of Giant Magnetoresistance".
Nanotechnology gives sensitive read-out heads for compact hard disks
This year's physics prize is awarded for the technology that is used
to read data on hard disks. It is thanks to this technology that it
has been possible to miniaturize hard disks so radically in recent
years. Sensitive read-out heads are needed to be able to read data from
the compact hard disks used in laptops and some music players, for
instance.
In 1988 the Frenchman Albert Fert and the German Peter Grünberg each independently discovered a totally new physical effect – Giant Magnetoresistance or GMR. Very weak magnetic changes give rise to major differences in electrical resistance in a GMR system. A system of this kind is the perfect tool for reading data from hard disks when information registered magnetically has to be converted to electric current. Soon researchers and engineers began work to enable use of the effect in read-out heads. In 1997 the first read-out head based on the GMR effect was launched and this soon became the standard technology. Even the most recent read-out techniques of today are further developments of GMR.
A hard disk stores information, such as music, in the form of microscopically small areas magnetized in different directions. The information is retrieved by a read-out head that scans the disk and registers the magnetic changes. The smaller and more compact the hard disk, the smaller and weaker the individual magnetic areas. More sensitive read-out heads are therefore required if information has to be packed more densely on a hard disk. A read-out head based on the GMR effect can convert very small magnetic changes into differences in electrical resistance and there-fore into changes in the current emitted by the read-out head. The current is the signal from the read-out head and its different strengths represent ones and zeros.
The GMR effect was discovered thanks to new techniques developed during the 1970s to produce very thin layers of different materials. If GMR is to work, structures consisting of layers that are only a few atoms thick have to be produced. For this reason GMR can also be considered one of the first real applications of the promising field of nanotechnology.
In 1988 the Frenchman Albert Fert and the German Peter Grünberg each independently discovered a totally new physical effect – Giant Magnetoresistance or GMR. Very weak magnetic changes give rise to major differences in electrical resistance in a GMR system. A system of this kind is the perfect tool for reading data from hard disks when information registered magnetically has to be converted to electric current. Soon researchers and engineers began work to enable use of the effect in read-out heads. In 1997 the first read-out head based on the GMR effect was launched and this soon became the standard technology. Even the most recent read-out techniques of today are further developments of GMR.
A hard disk stores information, such as music, in the form of microscopically small areas magnetized in different directions. The information is retrieved by a read-out head that scans the disk and registers the magnetic changes. The smaller and more compact the hard disk, the smaller and weaker the individual magnetic areas. More sensitive read-out heads are therefore required if information has to be packed more densely on a hard disk. A read-out head based on the GMR effect can convert very small magnetic changes into differences in electrical resistance and there-fore into changes in the current emitted by the read-out head. The current is the signal from the read-out head and its different strengths represent ones and zeros.
The GMR effect was discovered thanks to new techniques developed during the 1970s to produce very thin layers of different materials. If GMR is to work, structures consisting of layers that are only a few atoms thick have to be produced. For this reason GMR can also be considered one of the first real applications of the promising field of nanotechnology.
Read more about this year's prize |
Information for the Public (pdf) |
Scientific Background (pdf) |
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Links and Further Reading |
Albert Fert, French citizen. Born 1938 in Carcassonne,
France. Ph.D. in 1970 at Université Paris-Sud, Orsay, France. Professor
at Université Paris-Sud, Orsay, France, since 1976. Scientific
director of Unité mixte de physique CNRS/Thales, Orsay, France, since
1995.
www2.cnrs.fr/en/338.htm
Peter Grünberg, German citizen. Born 1939 in Pilsen. Ph.D. in 1969 at Technische Universität Darmstadt, Germany. Professor at Institut für Festkörperforschung, Forschungszentrum Jülich, Germany, since 1972.
www.fz-juelich.de/portal/gruenberg_e
Prize amount: SEK 10 million to be shared equally between the Laureates
Contact persons: Erik Huss, Press Officer, Phone +46 8 673 95 44, mobile +46 70 673 96 50, erik.huss@kva.se
Ulrika Björkstén, Scientific editor, mobile +46 70 206 67 50, ulrika.bjorksten@kva.se
www2.cnrs.fr/en/338.htm
Peter Grünberg, German citizen. Born 1939 in Pilsen. Ph.D. in 1969 at Technische Universität Darmstadt, Germany. Professor at Institut für Festkörperforschung, Forschungszentrum Jülich, Germany, since 1972.
www.fz-juelich.de/portal/gruenberg_e
Prize amount: SEK 10 million to be shared equally between the Laureates
Contact persons: Erik Huss, Press Officer, Phone +46 8 673 95 44, mobile +46 70 673 96 50, erik.huss@kva.se
Ulrika Björkstén, Scientific editor, mobile +46 70 206 67 50, ulrika.bjorksten@kva.se
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