Magnetism from the Atom to the Bulk in Iron, Cobalt, and Nickel Clusters
- 16 September 1994
- journal article
- other
- Published by American Association for the Advancement of Science (AAAS) in Science
- Vol. 265 (5179) , 1682-1684
- https://doi.org/10.1126/science.265.5179.1682
Abstract
Molecular beam deflection measurements of small iron, cobalt, and nickel clusters show how magnetism develops as the cluster size is increased from several tens to several hundreds of atoms for temperatures between 80 and 1000 K. Ferromagnetism occurs even for the smallest sizes: for clusters with fewer than about 30 atoms the magnetic moments are atomlike; as the size is increased up to 700 atoms, the magnetic moments approach the bulk limit, with oscillations probably caused by surface-induced spin-density waves. The trends are explained in a magnetic shell model. A crystallographic phase transition from high moment to low moment in iron clusters has also been identified.Keywords
This publication has 19 references indexed in Scilit:
- Low-temperature stable nanometer-size fcc-Fe particles with no magnetic orderingPhysical Review B, 1992
- Exchange interaction and local environment effects on the magnetic properties ofclustersPhysical Review B, 1992
- Large ion volume time-of-flight mass spectrometer with position- and velocity-sensitive detection capabilities for cluster beamsReview of Scientific Instruments, 1991
- Improved pulsed laser vaporization source for production of intense beams of neutral and ionized clustersReview of Scientific Instruments, 1990
- Magnetism and local order. II. Self-consistent cluster calculationsPhysical Review B, 1989
- Magnetism at the Ni(001) surface: A high-precision, all-electron local-spin-density-functional studyPhysical Review B, 1984
- Scaling for first-order phase transitions in thermodynamic and finite systemsPhysical Review B, 1982
- Surface states, surface magnetization, and electron spin polarization: Fe(001)Physical Review B, 1981
- Finite-size rounding of a first-order phase transitionPhysical Review B, 1980
- Origin of the Hyperfine Fields in Pure Fe and at Solute Atoms in FePhysical Review B, 1971