Skip Nav Destination
Close Modal
Search Results for
transmission
Update search
Filter
- Title
- Authors
- Author Affiliations
- Full Text
- Abstract
- Keywords
- DOI
- ISBN
- EISBN
- Issue
- ISSN
- EISSN
- Volume
- References
Filter
- Title
- Authors
- Author Affiliations
- Full Text
- Abstract
- Keywords
- DOI
- ISBN
- EISBN
- Issue
- ISSN
- EISSN
- Volume
- References
Filter
- Title
- Authors
- Author Affiliations
- Full Text
- Abstract
- Keywords
- DOI
- ISBN
- EISBN
- Issue
- ISSN
- EISSN
- Volume
- References
Filter
- Title
- Authors
- Author Affiliations
- Full Text
- Abstract
- Keywords
- DOI
- ISBN
- EISBN
- Issue
- ISSN
- EISSN
- Volume
- References
Filter
- Title
- Authors
- Author Affiliations
- Full Text
- Abstract
- Keywords
- DOI
- ISBN
- EISBN
- Issue
- ISSN
- EISSN
- Volume
- References
Filter
- Title
- Authors
- Author Affiliations
- Full Text
- Abstract
- Keywords
- DOI
- ISBN
- EISBN
- Issue
- ISSN
- EISSN
- Volume
- References
NARROW
Format
Topics
Book Series
Date
Availability
1-20 of 551 Search Results for
transmission
Follow your search
Access your saved searches in your account
Would you like to receive an alert when new items match your search?
1
Sort by
Book: STEM in SEM Introduction to Scanning Transmission Electron Microscopy for Microelectronics Failure
Series: ASM Technical Books
Publisher: ASM International
Published: 23 January 2020
DOI: 10.31399/asm.tb.stemsem.t56000001
EISBN: 978-1-62708-292-1
... Abstract This chapter discusses the principles of scanning transmission electron microscopy (STEM) as implemented using conventional scanning electron microscopes (SEMs). It describes the pros and cons of low-energy imaging and diffraction, addresses basic hardware requirements, and provides...
Abstract
This chapter discusses the principles of scanning transmission electron microscopy (STEM) as implemented using conventional scanning electron microscopes (SEMs). It describes the pros and cons of low-energy imaging and diffraction, addresses basic hardware requirements, and provides information on imaging modes, detector positioning and alignment, and the effect of contrast reversal. It also discusses beam convergence and angular selectivity, the use of application-specific masks, and how to generate grain orientation maps for different material systems.
Series: ASM Technical Books
Publisher: ASM International
Published: 23 January 2020
DOI: 10.31399/asm.tb.stemsem.9781627082921
EISBN: 978-1-62708-292-1
Series: ASM Technical Books
Publisher: ASM International
Published: 01 November 2019
DOI: 10.31399/asm.tb.mfadr7.t91110461
EISBN: 978-1-62708-247-1
... Abstract The ultimate goal of the failure analysis process is to find physical evidence that can identify the root cause of the failure. Transmission electron microscopy (TEM) has emerged as a powerful tool to characterize subtle defects. This article discusses the sample preparation procedures...
Abstract
The ultimate goal of the failure analysis process is to find physical evidence that can identify the root cause of the failure. Transmission electron microscopy (TEM) has emerged as a powerful tool to characterize subtle defects. This article discusses the sample preparation procedures based on focused ion beam milling used for TEM sample preparation. It describes the principles behind commonly used imaging modes in semiconductor failure analysis and how these operation modes can be utilized to selectively maximize signal from specific beam-specimen interactions to generate useful information about the defect. Various elemental analysis techniques, namely energy dispersive spectroscopy, electron energy loss spectroscopy, and energy-filtered TEM, are described using examples encountered in failure analysis. The origin of different image contrast mechanisms, their interpretation, and analytical techniques for composition analysis are discussed. The article also provides information on the use of off-axis electron holography technique in failure analysis.
Image
Published: 01 November 2019
Figure 28 Transmission of Si improves with wafer thinning Note that transmission for 10 20 cm −3 material through 100 microns is less than a percent. Calculated from empirical formulas given by A. Falk in [7] .
More
Image
Published: 01 June 2008
Fig. 9.8 Transmission electron micrographs of aluminum-copper precipitation sequence. GP, Guinier-Preston. Source: Ref 5
More
Image
in Overview of Wafer-level Electrical Failure Analysis Process for Accelerated Yield Engineering
> Microelectronics Failure Analysis: Desk Reference
Published: 01 November 2019
Figure 16 Transmission electron images showing voiding in (a) second via interconnect (cross section) and (b) third metal layers (top view).
More
Image
Published: 01 November 2019
Figure 27 Transmission of P-Doped Silicon falls dramatically with increasing carrier concentration. Calculated from empirical formulas given by A. Falk [7] .
More
Image
Published: 01 November 2007
Fig. 14.23 Transmission electron micrograph showing fine, coherent γ″ (Ni 3 Nb) precipitates formed in the grain matrix of alloy 625 at 650 °C (1200 °F) for 24 h. Source: Ref 13
More
Image
Published: 01 November 2007
Fig. 14.24 Transmission electron micrograph showing a dark-field image of fine, Ni 2 (Cr,Mo) ordered phases formed in the grain matrix of Ni-16Cr-15Mo-3Fe alloy at 540 °C (1005 °F) for 16,000 h. Source: Ref 14
More
Image
Published: 01 November 2007
Fig. 14.25 Transmission electron micrograph showing a dark-field image of fine, coherent γ′ (Ni 3 Al) precipitates formed in the grain matrix of alloy 214 (Ni-16Cr-4.5Al-3Fe-Y) at 800 °C (1470 °F) for 8 h. Source: Ref 15
More
Image
Published: 01 November 2007
Fig. 14.26 Transmission electron micrograph showing a dark-field image of fine, coherent γ′ (Ni 3 Al) precipitates formed in the grain matrix of alloy 601 at about 590 °C (1100 °F) for 2.5 years. Original magnification: 97,000×. Source: Ref 16
More
Image
Published: 01 November 2007
Fig. 14.40 Transmission electron micrograph showing long-range ordered phases [Ni 2 (Cr,Mo)] in a dark field image using a 〈220〉 reflection in alloy S after 8000 h at 540 °C (1000 °F). Source: Ref 47
More
Image
Published: 01 October 2012
Fig. 1.8 Main transmission housing for a heavy lift helicopter that was sand cast in WE43B magnesium alloy having a T6 temper. Casting weight = 93 kg (206 lb). Courtesy of Fansteel Wellman Dynamics. Source: Ref 1.3
More
Image
Published: 01 October 2012
Fig. 3.12 Magnesium alloy sand castings. (a) Main transmission housing for a heavy lift helicopter that was sand cast in WE43B magnesium alloy having a T6 temper. Casting weight = 206 lb (93 kg). Courtesy of Fansteel Wellman Dynamics. (b) Gearbox housing for a military fighter aircraft
More
Image
Published: 01 December 2004
Fig. 9 Dislocations. (a) Transmission electron micrograph of type 304 stainless steel showing dislocation pileups at an annealing twin boundary. (b) Schematic representation of dislocations on a slip plane
More
Image
Published: 01 December 1996
Fig. 5-54 Transmission electron micrographs showing retained austenite stringers between the martensite laths. (From J.P Materkowski and G. Krauss, Met. Trans ., Vol 10A, p 1643 (1979), Ref 25 )
More
Image
Published: 01 December 1996
Fig. 8-41 Transmission electron micrograph (dark field) showing fine Nb carbonitrides (white) in a 0.15% Nb steel. (From G. Gauthier and A.B. LeBon, MicroAlloying 75 , Union Carbide Corporation, New York, p 73 (1975), Ref 18 )
More
Image
Published: 01 September 2008
Fig. 7(a, b) Compressor transmission shaft with a fracture propagating from the acute-angled keyway. Source: Ref 13
More
Image
in The Expanded Metallographic Laboratory
> Metallographer’s Guide: Practices and Procedures for Irons and Steels
Published: 01 March 2002
Fig. 6.8 A transmission electron microscope
More
1