Journal ArticleDOI
Transmission electron microscopy of nanomachined silicon crystals
TLDR
In this article, the mean depth of permanent damage in both cases lies in the range 100-400 nm, and the damage consists of regions of well defined dislocation loops on several slip systems, other regions with a very high density of irregular dislocation arrays, and occasional microcracks up to 500nm deep which do not always intersect the surfaces.Abstract:
Silicon substrate slices in (111) or (001) surface orientation have been machined in two ways: precision ground by a diamond abrasive wheel to a surface roughness R a ≈ 11 nm, or turned on a highly stiff single-point diamond turning machine to R a,≈0·5 nm Transmission electron microscopy of cross-sections of the machined surfaces has established the following The mean depth of permanent damage in both cases lies in the range 100–400 nm In the ground specimens the damage depth is very variable, and the damage consists of regions of well defined dislocation loops on several slip systems, other regions with a very high density of irregular dislocation arrays, and occasional microcracks up to 500nm deep which do not always intersect the surfaces Patches of amorphous silicon are also observed Beneath the turned surfaces the damage appears more homogeneous, consisting of dislocation loops predominantly on a single slip system in any given region of the specimenread more
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Technological Advances in Fine Abrasive Processes
TL;DR: In this paper, the authors focus on fine abrasive processes with emphasis on material removal in brittle workmaterials, and make an attempt to rationalize various models by linking conventional machining, grinding, ultraprecision machining and indentation sliding.
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Fundamental investigation of subsurface damage in single crystalline silicon caused by diamond machining
TL;DR: In this paper, a single crystalline silicon was plunge-cut using diamond tools at a low speed, and cross-sectional transmission electron microscopy and laser micro-Raman spectroscopy were used to examine the subsurface structure of the machined sample.
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Ductile-regime turning mechanism of single-crystal silicon
TL;DR: In this paper, the Schmid factor was used to predict the surface features turned along each crystallographic orientation, and demonstrated that it was useful for turning in the critical regime between ductile and brittle.
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Grinding induced subsurface cracks in silicon wafers
TL;DR: In this article, the authors present the observation of subsurface cracks in silicon wafers machined by surface grinding process and investigate the effects of sample location on crack depth.
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Influence of microstructure on the cutting behaviour of silicon
TL;DR: In this paper, the authors use molecular dynamics simulation to study the mechanisms of plasticity during cutting of monocrystalline and polycrystalline silicon, showing that brittle cracking typically inclined at an angle of 45°-55° to the cut surface leads to the formation of periodic arrays of nanogrooves in monocrystine silicon.
References
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Journal ArticleDOI
Amorphization and conductivity of silicon and germanium induced by indentation.
TL;DR: Variation de la conductivite electrique en fonction de l'indentation dans les monocristaux par microscopie electronique a transmission.
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New evidence for a pressure-induced phase transformation during the indentation of silicon
TL;DR: In this paper, electron micrographs of indents in (111) silicon reveal that a thin layer of material immediately adjacent to the indenter is plastically extruded, which indicates that the material can be deformed in this way.
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Single-Point Diamond Machining of Glasses
TL;DR: In this paper, a machine tool of very high stiffness has been constructed and used for single-point diamond grooving of blanks of soda-lime glass and optical glassy quartz.
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Bragg diffraction by amorphous silicon
TL;DR: In this paper, Bragg diffraction from supernanometre regions of 'amorphous' silicon reveals the existence of crystalline clusters too small to be observed by X-ray diffraction in bulk.