High-resolution transmission electron microscopic images

Figure 9. (a) High-resolution transmission electron microscope image of an outer part of a nanocrystalline diamond particle and (b) enlargement of the left-hand side of (a). 

Fig. 9.4. High-resolution transmission electron microscope image of aerogel prepared AP-MgO. (Reprinted with permission from Richards, R. etal., J. Am. Chem. Soc. 2000, 122, 4921-4925, Fig. 2, copyright (2000) American Chemical Society.)...

Fig. 9.5. High-resolution transmission electron microscopic image of AP-MgAI204. The arrows indicate the MgO sandwiched between Boehmite planes. (Medine, G.M. et al J. Mater. Chem., 2004,14,757-763, Fig. 2. Reproduced by permission of the Royal Society of Chemistry.)...

Figure 6. Electron microscope images. (A) Vertically aligned multiwalled CNT arrays with length about 1 pm. (B) Collapsed CNT arrays after purification process. (C) CNT arrays with SOG after purification and tip opening process. (D) High-resolution transmission electron microscope image of an opened CNT end. From reference 69.

Figure 1. High-resolution transmission electron microscope image of goethite from weathered amphibole. Note the nanometer-scale porosity that separates oriented nanociystals. Similar aggregates were reported by Smith et al. (1983, 1987) in botiyoidal goethite (Banfield and Barker, unpublished data).

Figure 9. High-resolution transmission electron microscope image of most of the interior of an 4 nm diameter ZnS particle produced as the result of activity of sulfate-reducing bacteria. The image details show that the particle consists of a mixture of wurtzite and sphalerite-like regions. Unit cell axes are shown for the wurtzite region (Banfield et al., unpublished).

Fig. 11 (A) High-resolution transmission electron microscope image of a distorted SWNT and (B) a computer simulated model. This image shows the high flexibility of carbon nanotube. (View this art in color at www.dekker.com.)...

C. HRTEM simulates high-resolution transmission electron microscope images from crystals, interfaces, and defect structures. One can set up and interpret EM e meriments that investigate technologically important materials. 

Figure 16.2 High-resolution transmission electron microscope image of the atomic configuration in Ti3AlC2 MAX phase ceramic [32]. The beam direction is parallel to [l 120]. The atomic stacking sequence is also illustrated. In this material, every layer of three Ti planes horizontal rows of bright spots) is separated by an atomic layer of A1 horizoraal row of faint...

The transmission electron microscopy (TEM) images of a two-layer Tl-1223 film are shown in Fig. 7.12, which confirms the epitaxial nature of the annealed electrodeposited films. All films showed a significant amount of intergrowth, as shown by a high-resolution transmission electron microscopic (HRTEM) measurement in Figs. 7.12c and d of a representative two-layer... 

Fig. 9.2. High Resolution Transmission Electron Microscopic (HRTEM) image of Au nanoparticles stabilized by dodecanethiol ligand molecules after SMAD and digestive ripening procedure. (Reprinted from Stoeva, S. et al J. Phys. Chem. B, 2003,107,7441-7448, Fig. 11(c), by permission of the American Chemical Society, copyright 2002, American Chemical Society.)...

Fig. 6.24 Scanning electron microscope (A) and high resolution transmission electron microscope (B) images of PCL NPs.

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