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Book Chapter
Series: ASM Technical Books
Publisher: ASM International
Published: 01 January 2017
DOI: 10.31399/asm.tb.sccmpe2.t55090341
EISBN: 978-1-62708-266-2
... Abstract Glasses and ceramics are susceptible to stress-corrosion cracking (SCC), as are metals, but the underlying mechanisms differ in many ways. One of the major differences stems from the lack of active dislocation motion that, in metals, serves to arrest cracks by reducing stress...
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Published: 01 August 2013
Fig. 8.3 Commercial glasses contain alkali and alkaline earth ions, which substitute ionic bonds for the covalent bonds between tetrahedra. Source: Ref 8.2
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Published: 01 August 2013
Fig. 8.4 Temperature dependence of viscosity for several glasses. The “working range” is the temperature range in which glasses can be economically shaped. The straight lines on the semi-log plot do not extend below the glass transition temperature.
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Published: 01 June 1983
Figure 4.33 Thermal conductivity of several glasses from 4 to 300 K ( Childs et al., 1973 ). 1 — quartz-1; 2 — quartz-2; 3 — quartz-3; 4 — Phoenix-1; 5 — Phoenix-2; 6 — glass; 7 — Pyrex.
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in Mechanical Behavior of Nonmetallic Materials
> Mechanics and Mechanisms of Fracture: An Introduction
Published: 01 August 2005
Fig. 7.5 Environmental subcritical crack growth in glasses. (a) Crack velocity as a function of environment and pH for vitreous silica glass. Source: Ref 7.5 . (b) Soda-lime glass tested at different temperatures. Source: Ref 7.5 . (c) Crack velocity curves for sapphire in moist air (25 °C
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Published: 01 February 2005
Fig. 20.19 Viscosity temperature curves for various metalworking glasses [ Semiatin et al., 1983 ]
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Published: 01 December 2003
Fig. 24 Chop marks on the fracture surface of the glass fibers in a glass/polyimide composite tested as a notched four-point bend specimen that failed in compression. 1800×
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in Cross-Sectioning: Mechanical Polishing, Ion Milling, and Focused Ion Beam (FIB)
> Microelectronics Failure Analysis: Desk Reference
Published: 01 November 2019
Fig. 4 Small sample and epoxy on glass
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in Cross-Sectioning: Mechanical Polishing, Ion Milling, and Focused Ion Beam (FIB)
> Microelectronics Failure Analysis: Desk Reference
Published: 01 November 2019
Fig. 5 Small sample on glass mounted on chuck. Note the change in epoxy color. This color denotes a proper cure.
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in Cross-Sectioning: Mechanical Polishing, Ion Milling, and Focused Ion Beam (FIB)
> Microelectronics Failure Analysis: Desk Reference
Published: 01 November 2019
Fig. 6 Making the glass sandwich
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in Cross-Sectioning: Mechanical Polishing, Ion Milling, and Focused Ion Beam (FIB)
> Microelectronics Failure Analysis: Desk Reference
Published: 01 November 2019
Fig. 8 Glass/epoxy on trimmed substrate prior to thinning
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Published: 01 November 2019
Figure 6 Cross-section of glass substrate showing: (a) the side of the substrate where the weak point was placed, (b) the area of the initiation scribe, and (c) the area away from the weak point where the cleave was allowed to propagate.
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Published: 01 November 2019
Figure 13 10 keV image of circuit with glass passivation showing negative (bright) charging. Only the metal bond pads are grounded and thus charge-free.
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Published: 01 November 2019
Figure 14 1.0 keV image of a circuit with glass passivation showing positive (dark) charging. Positive charging tends to be less severe than negative charging and the effects are more subtle.
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in Failure Analysis Techniques and Methods for Microelectromechanical Systems (MEMS)[1]
> Microelectronics Failure Analysis: Desk Reference
Published: 01 November 2019
Figure 43 a) Schematic of a Si membrane of a pressure sensor bonded to a glass substrate. The membrane is in under-pressure, b) deflection of the membrane measured using laser interference, c) biaxial mechanical stress in the membrane measured using micro-Raman spectroscopy.
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in Acoustic Microscopy of Semiconductor Packages
> Microelectronics Failure Analysis: Desk Reference
Published: 01 November 2019
Figure 55 Acoustic GHz-images of an indented glass sample at different spacings between the acoustic lens and the sample. Left: sample surface in focus. The defocus increases from left to right.
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Published: 01 August 2013
Fig. 1.11 Structure of a silicate glass consists of tetrahedra with silicon atoms in the centers and oxygen atoms on the corners. Source: Ref 1.2
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Published: 01 August 2013
Fig. 2.13 Golf clubs made from metallic glass. Courtesy of: Otis Buchanan, Liquidmetal Technology, Lake Forrest, CA
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Published: 01 August 2013
Fig. 8.2 Silica glass is composed of tetrahedra with four O −2 ions (shown by open circles) surrounding Si+ 4 ions. Each O −2 ion is shared by two tetrahedra. Source: Ref 8.2
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Published: 01 August 2013
Fig. 8.5 Until the 19th century, panes of glass were made by spinning a rod with a glob of glass at the end and letting the centrifugal force form a disc from which panes could be cut. Source: Ref 8.3
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