Low energy ion assisted control of interfacial structure: Ion fluence effects

Citation
Xw. Zhou et Hng. Wadley, Low energy ion assisted control of interfacial structure: Ion fluence effects, J APPL PHYS, 88(10), 2000, pp. 5737-5743
Citations number
26
Categorie Soggetti
Apllied Physucs/Condensed Matter/Materiales Science
Journal title
JOURNAL OF APPLIED PHYSICS
ISSN journal
00218979 → ACNP
Volume
88
Issue
10
Year of publication
2000
Pages
5737 - 5743
Database
ISI
SICI code
0021-8979(20001115)88:10<5737:LEIACO>2.0.ZU;2-3
Abstract
Multilayered thin films consisting of high electrical conductivity copper l ayers sandwiched between pairs of low coercivity ferromagnetic alloys can e xhibit giant magnetoresistance. The magnitude of the magnetoresistance incr eases with the structural and chemical perfection of the interfaces. Recent atomistic modeling and experimental observations have shown that nickel an d cobalt atoms in the ferromagnetic layer readily exchange with underlying copper atoms during the deposition of the ferromagnetic layer upon the copp er spacer. This results in mixing at the ferromagnetic metal on copper inte rface. Low energy (1-20 eV) inert gas ions can be used during deposition to flatten the surface of layers, in some cases without causing interlayer mi xing. Here we use the molecular dynamics simulation method to investigate t he effects of the assisting ion fluence upon the surface roughness and inte rlayer mixing of a model Ni/Cu/Ni multilayer system. The results reveal tha t the surface roughness initially drops rapidly with ion fluence and then a pproaches a limiting roughness that is dependent upon the surface type, the ion energy, and the ion mass. For a Cu on Ni surface irradiated by 2.0 eV Xe+ ions, the flattening transition occurs at a fluence of about 0.2 ions/A 2 (corresponding to an ion to metal deposition flux ratio of about 5). The same transition was seen at a similar fluence for a Ni on Cu surface, but a t a higher Xe+ ion energy of 14.0 eV. Threshold energies for flattening and mixing were identified for various surfaces. The probabilities of both fla ttening and mixing were found to increase with ion fluence and ion energy. Because the threshold energy for mixing was lower than that for smoothing, significant interfacial mixing was only seen during ion assisted flattening of the Ni on Cu interface. Simple models have been developed to establish the functional dependence of interfacial structural parameters upon the ass isting ion fluence. (C) 2000 American Institute of Physics. [S0021-8979(00) 06022-9].