Dr. Peter Grünberg of Forschungszentrum Jülich in Germany has joined the growing list of Nobel Laureates associated with DOE. In 1988, Dr. Grünberg and Dr. Albert Fert of Université Paris-Sud in France each independently discovered Giant Magnetoresistance (GMR), a physical effect in which very weak changes in magnetism generate larger changes in electrical resistance. This is how information stored magnetically on a hard disk can be converted to electrical signals that the computer reads (see Office of Science press release).
The Royal Swedish Academy of Sciences awarded the 2007 Nobel Prize in Physics jointly to Dr. Grünberg and Dr. Fert for discovering “a totally new physical effect,” GMR (see featured documents), which revolutionized digital data storage and “can … be considered one of the first real applications of the promising field of nanotechnology.”
Dr. Grünberg's research as recognized in this year's Nobel Prize in Physics was based in part on his work at Argonne National Laboratory.
See a list of DOE-supported and/or -affiliated Nobel Prize winners since 1977.
Featured Documents on Giant Magnetoresistance from Information Bridge, Energy Citations Database, DOepatents, and DOE R&D Project Summaries
Featured Documents from Information Bridge
- Enhanced spin-valve giant magneto-resistance in non-exchange biased sandwich films
- Perpendicular giant magnetoresistance in a 0.4{mu}m diameter multilayer sensor
- Giant magnetoresistance effects in 5f-materials
- Atomic Scale Structure of Ultrathin Magnetic Multilayers and Correlation with Resistance and Giant Magnetoresistance and Spin-Dependent Tunneling
- Calculation of electrical conductivity and giant magnetoresistance within the free electron model
- Numerical modeling of giant magnetoresistance effect for application to magnetic data storage. Project accomplishment summary report for 93-MULT-116-D1-04
- Numerical modeling of giant magnetoresistance effect for application to magnetic data storage. CRADA final report for CRADA number Y-1293-0175
- Giant magnetoresistance in organic superconductors {kappa}-(BEDT-TTF){sub 2}Cu(NCS){sub 2}
- Giant magnetoresistance materials for magnetic recording technology
Featured Citations from Energy Citations Database
- Giant magnetoresistance in actinide systems
- Giant magnetoresistance at 300 K in single crystals of La{sub 0.65}(PbCa){sub 0.35}MnO{sub 3}
- First-principles calculations of electrical conductivity and giant magnetoresistance of Co{vert_bar}Cu{vert_bar}Co spin valves
- Microstructural influence on magnetic properties and giant magnetoresistance of melt-spun gold-cobalt
- Microstructure and giant magnetoresistance in granular and multilayer magnetic thin films
- Spectacular giant magnetoresistance effects in the polycrystalline perovskite Pr{sub 0.7}Sr{sub 0.05}Ca{sub 0.25}MnO{sub 3-{delta}}
- Annealing effect on the giant magnetoresistance of La-Ca-Mn-O thin films
- TEM studies in melt-spun Cu-Mn-Al system exhibiting giant magnetoresistance
- Effect of dimensionality on the giant magnetoresistance of the manganates: A study of the (La, Sr){sub n+1}Mn{sub n}O{sub 3n+1} family
- Superparamagnetic behavior and giant magnetoresistance in oxygen deficient R{sub 0.67}Sr{sub 0.33}MnO{ital{sub z}} (R=Nd, Pr) epitaxial films (abstract)
- Giant magnetoresistance induced by spin-correlation scattering in magnetic thin films and other compounds
- Correlation between magnetovolume and giant magnetoresistance effects in doped La{sub 2/3}Ca{sub 1/3}MnO{sub 3} perovskites
Featured Patents from DOepatents
- Patent Number US 5824165 Giant magnetoresistive heterogeneous alloys and method of making same
- Patent Number US 5882436 Giant magnetoresistive heterogeneous alloys and method of making same
- Patent Number US 5,882,436/A/ Giant magnetoresistive heterogeneous alloys and method of making same
- Patent Number US 5,824,165/A/ Giant magnetoresistive heterogeneous alloys and method of making same
Featured Projects from DOE R&D Project Summaries
- P/ANL--000705 Giant Magnetoresistive Wire Sensor
- P/ANL--000471 Materials Science: Magnetic Thin Films
- P/BNL--PO-18 Materials, Methods, Microstructure, and Magnetism
- P/ANL--001893 Melt-Spun Ribbon for Giant Magnetoresistance Wire Sensor