Author
N. Matuda
Bio: N. Matuda is an academic researcher from University of Tokyo. The author has contributed to research in topics: Young's modulus & Boron. The author has an hindex of 6, co-authored 7 publications receiving 205 citations.
Papers
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TL;DR: In this article, the average internal stress measured by the cantilever method was 5 x 108N m−2 compression, and the dependence of the size of the wrinkles on the film thickness was deduced and compared with experimental results.
109 citations
TL;DR: In this paper, the mechanical properties of coatings of MgF2, carbon and boron were investigated and it was found that exposure of the coatings to the atmosphere was essential to the initiation of the wrinkles.
53 citations
TL;DR: In this article, the elastic constant, internal stress and internal friction of vacuum-deposited MgF 2 thin films on quartz substrates were studied with an in situ measuring apparatus based on the vibrating reed type of cantilever method.
19 citations
TL;DR: In this paper, the effect of the substrate temperature and ion bombardment on the adhesion of metal and compound films has been investigated and the correlation between these quantities is discussed and the results on internal stress and Young's modulus were determined by simultaneous in situ measurements during film deposition.
16 citations
TL;DR: The internal stress, the elastic constant and the thermal expansion coefficient of amorphous boron films were studied in this article for substrate temperatures of 260°C, 340°C and 420°C respectively.
9 citations
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02 Feb 2004TL;DR: The role of stress in mass transport is discussed in this article, where the authors consider anisotropic and patterned films, buckling, bulging, peeling and fracture.
Abstract: 1. Introduction and overview 2. Film stress and substrate curvature 3. Stress in anisotropic and patterned films 4. Delamination and fracture 5. Film buckling, bulging and peeling 6. Dislocation formation in epitaxial systems 7. Dislocation interactions and strain relaxation 8. Equilibrium and stability of surfaces 9. The role of stress in mass transport.
1,562 citations
BP1
TL;DR: A review of the sputtered film stress literature shows that the intrinsic stress can be tensile or compressive depending on the energetics of the deposition process as discussed by the authors, and extensive experimental evidence show a direct link between the particle flux and energy striking the condensing film, which determines the nature and magnitude of the stress.
Abstract: A review of the sputtered film stress literature shows that the intrinsic stress can be tensile or compressive depending on the energetics of the deposition process. Modeling studies of film growth and extensive experimental evidence show a direct link between the energetics of the deposition process and film microstructure, which in turn determines the nature and magnitude of the stress. The fundamental quantities are the particle flux and energy striking the condensing film, which are a function of many process parameters such as pressure (discharge voltage), target/sputtering gas mass ratio, cathode shape, bias voltage, and substrate orientation. Tensile stress is generally observed in zone 1-type, porous films and is explained in terms of the grain boundary relaxation model, whereas compressive stress, observed in zone T-type, dense films, is interpreted in terms of the atomic peening mechanism. Modeling of the atomic peening mechanism and experimental data indicate that the normalized moment...
584 citations
TL;DR: In this paper, the authors used a combination of fracture mechanics and post-buckling theory to analyze the mechanics of delamination and spelling of pre-compressed films and indented coatings.
553 citations
TL;DR: In this paper, the Young's moduli and the yield strengths of thin-film materials that comprise the beams are determined using simple beam theory and the load-deflection data, the measured mechanical properties are compared to those obtained by indenting similar thin films supported by their substrate.
Abstract: The mechanical deflection of cantilever microbeams is presented as a new technique for testing the mechanical properties of thin films. Single-layer microbeams of Au and SiO2 have been fabricated using conventional silicon micromachining techniques. Typical thickness, width, and length dimensions of the beams are 1.0,20, and 30 μm, respectively. The beams are mechanically deflected by a Nanoindenter, a submicron indentation instrument that continuously monitors load and deflection. Using simple beam theory and the load-deflection data, the Young’s moduli and the yield strengths of thin-film materials that comprise the beams are determined. The measured mechanical properties are compared to those obtained by indenting similar thin films supported by their substrate.
380 citations
TL;DR: In this article, the intrinsic stresses of Al, Ti, Fe, Ta, Mo, W, Ge, Si, AlN, TiN, and Si3N4 films prepared by ion beam sputtering were investigated at low Td/Tm values.
Abstract: The intrinsic stresses of Al, Ti, Fe, Ta, Mo, W, Ge, Si, AlN, TiN, and Si3N4 films prepared by ion beam sputtering were investigated at low Td/Tm values. The intrinsic stress is compressive and its origin is explained in terms of the ion peening model. Knock‐on linear cascade theory of forward sputtering is applied to derive a simple scaling law with the film’s physical properties. The results show that the stress is directly proportional to the elastic energy/mole, given by the quantity Q=EM/(1−ν)D, where E is Young’s modulus, M the atomic mass, D the density, and ν Poisson’s ratio. Stress data taken from the literature for a variety of materials deposited by low‐pressure magnetron sputtering, and rf and ion beam sputtering also fit the correlation with Q. Furthermore, the model predicts a square‐root dependence on the incident ion energy, suggesting that the stress is momentum rather than energy driven.
365 citations