1991
DOI: 10.1016/0739-6260(91)90003-i
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Quantitative analysis of knock-on and thermal damage of biological specimens by electron irradiation in transmission electron microscopy

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Cited by 6 publications
(5 citation statements)
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“…Cross-sections of previously irradiated areas showed alternate white and black bands suggesting zones with alternate lower and higher density; this could be explained by the local displacement of atoms of the embedding medium and cellular components (Kanaya et al, 1991). In addition, we showed that thinning is not symmetric and seems to be greater on one side of the section.…”
Section: Mod$cation Of the Sections Under The Beammentioning
confidence: 63%
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“…Cross-sections of previously irradiated areas showed alternate white and black bands suggesting zones with alternate lower and higher density; this could be explained by the local displacement of atoms of the embedding medium and cellular components (Kanaya et al, 1991). In addition, we showed that thinning is not symmetric and seems to be greater on one side of the section.…”
Section: Mod$cation Of the Sections Under The Beammentioning
confidence: 63%
“…Compared to CTEM, STEM possesses various basic advantages which are very useful for the visualization of objects through thick sections (Crewe & Groves, 1974;Reimer, 1989, Kanaya et al, 1991.…”
Section: General Considerationsmentioning
confidence: 99%
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“…For the knock-on effect, incident electrons transferring sufficient energy to an atom can displace it from its position. 45,46 On the basis of our experimental observations, we propose that the formation of h-SnTe from β-SnTe can be mainly caused by the knock-on effect of the high-energy electron beam. In the ROI, the electron beam irradiation breaks the SnTe 6 octahedra in β-SnTe, displaces the Sn atoms from the octahedral to the tetrahedral voids of Te in the crystal lattice, and results in the appearance of the stacking sequence of –Sn–Te–Te–Sn– in h-SnTe, as displayed in Fig.…”
Section: Resultsmentioning
confidence: 85%