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Transmission electron microscopy
2003This chapter focuses on the direct beam and elastically scattered beams which form different contrast images and electron diffraction patterns. In respect that the contact loading affects only a very small volume of material and, compared with all other techniques, the transmission electron microscopy (TEM) is the instrument of choice due to its ...
Daibin Ge, Yury Gogotsi
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Transmission Electron Microscopy [PDF]
We wrote it to be read by, and taught to, senior undergraduates and starting graduate students, rather than studied in a research laboratory. We wrote it using the same style and sentence construction that we have used in countless classroom lectures, rather than how we have written our countless (and much-less read) formal scientificpapers.
David B. Williams, C. Barry Carter
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Transmission Electron Microscopy of Bone
2011This chapter describes procedures to process mineralized tissues obtained from different sources for transmission electron microscopy (TEM). Methods for fixation, resin embedding, staining of semi-thin sections and ultrathin sections are presented. In addition, attention will be paid to processing of cultured bone explants for TEM analysis.
Everts, V. +3 more
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Transmission Electron Microscopy
2019Electron microscopy is a versatile scientific technique used in the investigation and characterization of materials science, biology, and life science. The principle of electron microscopy is similar to optical microscopy but uses electrons to illuminate and magnify specimens instead of light.
Swaminathan Subramanian, Raghaw S. Rai
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Transmission electron microscopy
2013Transmission electron microscopy (TEM) is a significant tool in demonstrating the ultrastructure of cells and tissues both in normal and disease states. In particular, TEM can be crucial in the diagnosis of various renal pathologies, the recognition of subcellular structural defects or the deposition of extracellular material (e.g.
Anthony E. Woods, John W. Stirling
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Transmission Electron Microscopy
2014This chapter will introduce the analyst to scanning/transmission electron microscopy (STEM/TEM). Basic concepts required for understanding scanning/transmission electron microscopy will be given. Simple introduction of TEM instrumentation, specimen preparation, and basic TEM operation will be discussed from the perspective of the instrument user ...
Agustín Fernández Larios +1 more
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Transmission electron microscopy of yeast
Microscopy Research and Technique, 2000The challenges of sample preparation can limit a researcher's selection of transmission electron microcopy (TEM) for analysis of yeast. However, with the exception of thin sectioning, preparation of well-fixed and infiltrated samples of yeast cells is achievable by any reasonably equipped laboratory.
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Nanomeasurements in Transmission Electron Microscopy
Microscopy and Microanalysis, 2000Abstract Nanomaterials have attracted a great deal of research interest recently. The small size of nanostructures constrains the applications of well-established testing and measurement techniques, thus new methods and approaches must be developed for ...
Wang, Z. L. (Zhong Lin) +2 more
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Electron Transmission Microscopy of NiAl [PDF]
AbstractAn electron transmission study of the β‐phase of NiAl was made in annealed and deformed samples with the purpose of looking for antiphase boundary (APB), networks, and super‐dislocations and to observe other configurations of the deformed state.
J. O. Brittain +2 more
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Cathodoluminescence in transmission electron microscopy
Journal of Microscopy, 2006SummaryWe describe a cathodoluminescence spectrometer that is attached to an analytical transmission electron microscope. After a brief consideration of the set‐up and the peculiarities of recording spectra and of mapping defect distributions in panchromatic and monochromatic cathodoluminescence, we discuss two examples of applications.
M. Albrecht, H. Scheel, Horst P. Strunk
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