Ultrathin Mn layers on Rh(001): Investigations using scanning tunneling microscopy and density functional calculations

Author(s)
Martin Zeleny, Fabian D Natterer, Albert Biedermann, Juergen Hafner
Abstract

The structural and magnetic properties of ultrathin layers of Mn grown on Rh (001) surfaces have been investigated using scanning tunneling microscopy (STM) and ab initio density-functional calculations. STM shows perfect wetting of the Rh substrate by the first Mn monolayer (ML) accompanied by a high mobility of the Mn atoms and only little film-substrate intermixing. By way of contrast, the second monolayer is unstable against formation of multilayer islands at 300 K. However, this is only a transient effect and growth approaches a layer-by-layer mode in thicker films. At 170 K growth proceeds layer-by-layer throughout. The structure of the films is face-centered tetragonal (fct) without any indication of lateral lattice mismatch up to 20 ML thickness. The apparent height differences between terraces of different local thickness are consistent with an average axial ratio close to unity (near fcc) for 2-3-ML-thick films that decreases continuously to approximate to 0.94 in thicker films. Detailed spin-polarized density-functional calculations have been performed for the bulk and the (001) surface of strained fct Mn, as well as for free-standing and supported Mn/Rh (001). The results demonstrate that structure and stability of surface and thin films are strongly influenced by antiferromagnetic (AFM) ordering. In-plane c (2x2) AFM is found at the surface while bulk and the deeper layers prefer layered AFM. The calculations reproduce and explain the growth instability of 2 ML films and reproduce qualitatively the thickness-dependent variation in the film structure while the tetragonal distortion imposed by the size mismatch is overestimated because with all known exchange-correlation functionals the size ratio of bulk Rh and Mn crystals is overestimated. The calculations show that interface alloying is slightly exothermic but kinetically hindered because of a high activation energy for exchange processes.

Organisation(s)
Computational Materials Physics, Physics of Nanostructured Materials
Journal
Physical Review B
Volume
82
No. of pages
15
ISSN
1098-0121
DOI
https://doi.org/10.1103/PhysRevB.82.165422
Publication date
2010
Peer reviewed
Yes
Austrian Fields of Science 2012
103018 Materials physics
Portal url
https://ucrisportal.univie.ac.at/en/publications/ec929cab-b7fe-4562-8fec-8f0903aced1a