Your search keyword '"K. J. Caspersen"' showing total 3 results

1. Approaching the low-temperature limit in nucleation and two-dimensional growth of fcc (100) metal films Ag/Ag(100)

Author

James W. Evans, H. Wedler, S. Frank, K. J. Caspersen, Patricia A. Thiel, Conrad R. Stoldt, Jörg Rottler, Philipp Maass, and Rolf Jürgen Behm

Subjects

Materials science, Diffusion barrier, Chemical physics, law, Nucleation, Physical chemistry, Deposition (phase transition), Kinetic Monte Carlo, Diffusion (business), Atmospheric temperature range, Scanning tunneling microscope, Saturation (chemistry), law.invention

Abstract

We analyze the formation of two-dimensional Ag islands following deposition of about 0.1 ML of Ag on Ag(100) over a temperature regime ranging from classical nucleation and growth behavior to almost immobile adatoms, from 300 to 125 K. Particular emphasis is placed on the post-deposition dynamics at the lower end of the temperature range, where the saturation island density is not reached at the end of the deposition, and nucleation and aggregation processes continue with adatoms from the remaining adatom gas. Our analysis combines VT scanning tunneling microscopy experiments with kinetic Monte Carlo simulation of appropriate atomistic models. The only adjustable parameters in the model are the terrace diffusion barrier and prefactor, which can be determined from island density behavior near room temperature. Other processes such as rapid edge diffusion, and ``easy'' nucleation and aggregation of diagonally adjacent adatoms, are treated as instantaneous. The model excellently reproduces all aspects of behavior at low temperatures, demonstrating that nucleation and growth processes can be described in one consistent scheme, down to the regime of almost immobile adatoms.

Published

2002

2. Metal homoepitaxial growth at very low temperatures: Lattice-gas models with restricted downward funneling

Author

K. J. Caspersen and James W. Evans

Subjects

Metal, Adsorption, Materials science, Condensed matter physics, law, Lattice (order), visual_art, visual_art.visual_art_medium, Scanning tunneling microscope, law.invention

Abstract

We develop and analyze 1+1- and 2+1-dimensional (d) models for multilayer homoepitaxial growth of metal films at low temperatures (T), where intralayer terrace diffusion is inoperative. This work is motivated by recent variable-temperature scanning tunneling microscopy studies of Ag/Ag(100) homoepitaxy down to 50 K. Adsorption sites are bridge sites in our 1+1d models, and fourfold hollow sites in our 2+1d models for fcc(100) or bcc(100) surfaces. For growth at 0 K, we introduce a 'restricted downward funneling' model, wherein deposited atoms can be trapped on the sides of steep nanoprotrusions rather than always funneling down to lower adsorption sites. This leads to the formation of overhangs and internal defects (or voids), and associated 'rough' growth. Upon increasing T, we propose that a series of interlayer diffusion processes become operative, with activation barriers below that for terrace diffusion. This leads to 'smooth' growth of the film for higher T (but still within the regime where terrace diffusion is absent), similar to that observed in models incorporating 'complete downward funneling.'

Published

2001

3. Morphology of multilayer Ag/Ag(100) films versus deposition temperature: STM analysis and atomistic lattice-gas modeling

Author

Patricia A. Thiel, Conrad R. Stoldt, M. C. Bartelt, Anthony R. Layson, K. J. Caspersen, and James W. Evans

Subjects

Thermal transport, Adsorption, Condensed matter physics, law, Lattice (order), Surface finish, Scanning tunneling microscope, Nanoscale morphology, Ames Laboratory, law.invention, Deposition temperature

Abstract

Scanning tunneling microscopy is used to analyze the nanoscale morphology of 25 ML films of Ag deposited on Ag(100) at temperatures (T) between 55 and 300 K. A transition from self-affine growth to ''mound formation'' occurs as T increases above about 140 K. The roughness decreases with increasing T up until 140 K in the self-affine growth regime, and then increases until about 210 K before decreasing again in the mounding regime. We analyze mounding behavior via a lattice-gas model incorporating: downward funneling of depositing atoms from step edges to lower fourfold hollow adsorption sites; terrace diffusion of adatoms with a barrier of 0.40 eV leading to irreversible island formation in each layer; efficient transport of adatoms along island edges to kink sites; and downward thermal transport of adatoms inhibited by a step-edge barrier of 0.06--0.07 eV along close-packed step edges (but with no barrier along kinked or open steps). This model reasonably recovers the T-dependence of not just the roughness, but also of the mound slopes and lateral dimensions above 190 K. To accurately describe lateral dimensions, an appropriate treatment of the intralayer merging of growing islands is shown to be critical. To describe behavior below 190 K, onemore » must account for inhibited rounding of kinks by adatoms at island edges, as this controls island shapes, and thus the extent of open steps and of easy downward transport. Elsewhere, we describe the low-T regime of self-affine growth (with no terrace diffusion) accounting for a breakdown of the simple downward funneling picture.« less

Published

2001