Morphology of ion-sputtered surfaces

Makeev, Maxim A.; Cuerno, Rodolfo; Barabási, Albert László

doi:10.1016/s0168-583x(02)01436-2

Cited by 487 publications

(558 citation statements)

References 108 publications

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“…Displaced atoms that reach the surface with enough kinetic energy to leave are permanently sputtered away; all other displaced atoms come to rest within the solid or on the surface after phonon emission times of ~10 − 12 s. These processes contribute prompt erosive 14,15 and prompt redistributive 11,16,17 components of morphology evolution and are collectively denoted P [x].…”

mentioning

confidence: 99%

Molecular dynamics of single-particle impacts predicts phase diagrams for large scale pattern formation

et al. 2011

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Energetic particle irradiation can cause surface ultra-smoothening, self-organized nanoscale pattern formation or degradation of the structural integrity of nuclear reactor components. A fundamental understanding of the mechanisms governing the selection among these outcomes has been elusive. Here we predict the mechanism governing the transition from pattern formation to flatness using only parameter-free molecular dynamics simulations of single-ion impacts as input into a multiscale analysis, obtaining good agreement with experiment. our results overturn the paradigm attributing these phenomena to the removal of target atoms via sputter erosion: the mechanism dominating both stability and instability is the impact-induced redistribution of target atoms that are not sputtered away, with erosive effects being essentially irrelevant. We discuss the potential implications for the formation of a mysterious nanoscale topography, leading to surface degradation, of tungsten plasma-facing fusion reactor walls. Consideration of impact-induced redistribution processes may lead to a new design criterion for stability under irradiation.

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confidence: 99%

Molecular dynamics of single-particle impacts predicts phase diagrams for large scale pattern formation

et al. 2011

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“…[4,[7][8][9][10][11]. Initiated by advances in the statistical mechanics of various non-equilibrium systems, it has been observed that the roughness of many natural surfaces follows rather simple scaling laws, which can be quantified using scaling exponents.…”

Section: Methodsmentioning

confidence: 99%

Scaling laws in PZT thin films grown on Si(001) and Nb-Doped SrTiO3(001) substrates

Ramírez¹,

Cortés²,

Lopera³

et al. 2006

Braz. J. Phys.

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A dynamic scaling and kinetic roughening study was done on digitized atomic force microscope (AFM) images of Pb(Zr 0.52 , Ti 0.48 )O 3 (PZT) thin films. The films were grown on Si(001) and Nb − SrTiO 3 (001) (STNO) substrates via rf-sputtering technique at high oxygen pressures at substrate temperatures of 600 o C by varying the deposition time and keeping other growth parameters fixed. By using a specific self-designed algorithm, we can extract from digitized 512-pixel resolution AFM-images, quantitative values of roughness parameters, i.e., interface width (σ ( )), lateral correlation length (ξ || ) and, roughness exponent (α). Herein, we report on the sputter-time deposition dependence of the parameters describing roughness for both kinds of substrates. We report α-values for different time depositions (between 15 and 60 minutes) close to 0.55 for Si substrates and 0.63 for Nb − SrTiO 3 substrates, indicating that the surface becomes more correlated in STNO substrates. The α-values are associated to the Lai-Das-Sarma-Villain model.

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“…The model is completed by expressing the currents and current densities in terms of the surface geometry and the surfactant density. Expressions for the erosion currents in the absence of surfactants are available from the theory of Bradley and Harper [12] and its generalizations [13,14,15]. In addition, we take into account modifications of the sputtering yields so that the erosion currents of substrate and surfactant, J A and J B , respectively, are given by…”

Section: Continuum Theory and Monte Carlo Modelmentioning

confidence: 99%

“…J 0 denotes the flux of incident ions, Y A , Y B are the sputtering yields of the pure A and B system, respectively. We keep the first terms of the standard gradient expansion of the yield modification due to surface morphology [12,15],…”

Section: Continuum Theory and Monte Carlo Modelmentioning

confidence: 99%

Surfactant Sputtering: Theory of a new method of surface nanostructuring by ion beams

Kree

Yasseri

Hartmann

2009

Nuclear Instruments and Methods in Physics Research Section B:

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We present a new Monte Carlo model and a new continuum theory of surface pattern formation due to "surfactant sputtering", i.e. erosion by ion-beam sputtering including a submonolayer coverage of additional, cosputtered surfactant atoms. This setup, which has been realized in recent experiments in a controlled way leads to a number of interesting possibilities to modifiy pattern forming processing conditions. We will present three simple scenarios, which illustrate some potential applications of the method. In all three cases, simple Bradley-Harper type ripples appear in the absence of surfactant, whereas new, interesting structures emerge during surfactant sputtering.

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Morphology of ion-sputtered surfaces

Cited by 487 publications

References 108 publications

Molecular dynamics of single-particle impacts predicts phase diagrams for large scale pattern formation

Molecular dynamics of single-particle impacts predicts phase diagrams for large scale pattern formation

Scaling laws in PZT thin films grown on Si(001) and Nb-Doped SrTiO3(001) substrates

Surfactant Sputtering: Theory of a new method of surface nanostructuring by ion beams

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