Nanopatterning of silicon surfaces by low-energy ion-beam sputtering: dependence on the angle of ion incidence

Gago, R.; Vázquez, Luís; Cuerno, Rodolfo; Varela, M.; Ballesteros, C.; Albella, J. M.

doi:10.1088/0957-4484/13/3/313

Cited by 68 publications

(35 citation statements)

References 18 publications

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“…This may be connected with a low conductivity of Si samples used in our experiments (specific resistance 5 k cm). However, a distinct nanorelief similar to that revealed in [14] was observed by using AFM for both Ge and Si samples. Figure 6 shows the AFM-image of Ge target after bombardment with 10 keV Ar + ions at fluence of about 10 18 ion/cm 2 .…”

Section: Resultssupporting

confidence: 67%

Angular distribution of atoms sputtered from germanium by 1–20 keV Ar ions

Chernysh

Patrakeev

Shulga

2006

Radiation Effects and Defects in Solids

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The angular distribution of atoms sputtered from germanium under 1-20 keV Ar + ion bombardment (normal incidence) has been studied experimentally and using computer simulations. A collector technique combined with Rutherford backscattering to analyze the distribution of collected material was used. In addition, the surface topography was under control. It was found that the experimental angular distribution of sputtered atoms (E 0 = 3-10 keV) could be approximated by the function cos n θ with n ≈ 1.65. Such a high value of n is connected with the surface scattering of ejected atoms and a noticeable contribution of backscattered ions to the formation of the sputter flux (the mass effect). The target surface was found to be practically flat even at ion fluencies ∼ 10 18 ions/cm 2 . The results obtained are compared with data from the literature, including our recent data on Si sputtering.

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Section: Resultssupporting

confidence: 67%

Angular distribution of atoms sputtered from germanium by 1–20 keV Ar ions

Chernysh

Patrakeev

Shulga

2006

Radiation Effects and Defects in Solids

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“…Hence, depositions on complex-shaped substrates are usually challenging for PVD processes, which can be seen from the differences of microstructure, density and growth rate from on-axis and off-axis deposited thin films [75]. In the following subsections, brief introduction is presented for the PVD methods used in this work, namely the direct current magnetron sputtering and the pulsed cathodic arc deposition processes.…”

Section: Physical Vapor Depositionmentioning

confidence: 99%

Thin Film Synthesis of New Nanolaminated Ternary Carbides

Lai¹

2016

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Ternary transition metal carbides with inherently nanolaminated crystal structure are a class of materials with typically higher damage tolerance, better machinability and lower brittleness compared to the binary counterparts, yet retaining their satisfactory electrical and thermal conductivity. Their interesting properties can be related to the laminated structure. Though studies of their properties based on calculations and bulk materials have suggested potential thin film applications, such as high temperature hard coatings and electrical contacts, a relatively small number of these phases have been synthesized as thin films. Investigation of thin film deposition of these inherently nanolaminated materials further the understanding of their phase formation and crystal growth.Motivated by predicted superconductivity and thermoelectric properties of molybdenum carbides and related layered molybdenum compounds, nanolaminated materials in the Mo-Ga-C ternary system were studied. Apart from the previously reported Mo2GaC, a new layered carbide, Mo2Ga2C, was synthesized in both thin film and bulk form with a postulated crystal structure related to Mo2GaC. The proposed structure was further validated by first principles calculations, showing higher stability compared to other crystal structure as well as other competing phases. The calculated lattice parameters were consistent with values from Rietveld analysis of X-ray and neutron diffraction patterns. In addition, both scanning transmission electron microscopy and X-ray photoelectron spectroscopy showed experimental evidence of the close structural-chemical relation between Mo2Ga2C and Mo2GaC.Driven by a need of high temperature protective coatings in nuclear applications, Zr-based nanolaminated carbides have become more attractive. In this work, another nanolaminated carbide, Zr2Al3C4, was synthesized in thin film form by pulsed cathodic arc deposition.Formation of the Zr2Al3C4 phase and its competing phases was studied with X-ray diffraction of thin films deposited with varying incoming flux compositions, temperatures and substrate ii materials. On 4H-SiC(001) substrates, highly phase-pure epitaxial Zr2Al3C4 films were formed, whereas depositions on Al2O3(001) substrates resulted in competing phases. A growth behavior similar to that of nanolaminated Mn+1AXn phases (M is a group 3-7 transition metal; A is commonly a group 13-14 element; X is C or N; n = 1 -3) was observed, despite the structuraland chemical differences between Zr2Al3C4 and MAX phases. Manuscript in Final PreparationIn Paper III, I took part in design of the experiments, and performed a major part of the thin film synthesis. I acquired and analyzed X-ray diffraction patterns, and prepared specimen for other characterization. I wrote a major part of the manuscript. Special thanks to Mark Tucker, our former colleague, who gave me important supports in the first year of my doctoral study, and helps me continuously after he left from IFM.Finally, lots of appreciations to my dearest family, C...

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“…As several articles in this volume describe, for a variety of surface types and system parameters (e.g. ion type and energy, beam angle and temperature, substrate type), the evolving surface patterns can take the form of ordered or disordered arrays of one-dimensional ripples or two-dimensional structure of dots, whose typical length scales are 10 2±1 nm [1][2][3][4][5][6][7][8][9][10][11][12][13][14][15][16][17][18]. The large separation of scales between the patterns and the characteristic penetration depth of ions into a solid surface (typically at least an order of magnitude) suggests that evolution of surface morphology can be described as a dynamics of continuous media.…”

Section: Introductionmentioning

confidence: 99%

Linear dynamics of ion sputtered surfaces: instability, stability and bifurcations

Davidovitch

Aziz

Brenner

2009

J. Phys.: Condens. Matter

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The linear dynamics of ion sputtered solids is essential to understanding the evolution of ordered and disordered surface patterns. We review the existing models of linear dynamics and point out qualitative discrepancies between theory and experimental observations that characterize the linear regime. In particular, we emphasize the importance of experimental and theoretical analysis of bifurcation points: certain values of control parameters such as ion beam angle or energy, where flat surfaces undergo a transition from stability to instability.PACS numbers:

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Nanopatterning of silicon surfaces by low-energy ion-beam sputtering: dependence on the angle of ion incidence

Cited by 68 publications

References 18 publications

Angular distribution of atoms sputtered from germanium by 1–20 keV Ar ions

Angular distribution of atoms sputtered from germanium by 1–20 keV Ar ions

Thin Film Synthesis of New Nanolaminated Ternary Carbides

Linear dynamics of ion sputtered surfaces: instability, stability and bifurcations

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