Scanning electron microscopic photograph

Fig. 1. Scanning electron microscope photograph of DSA mthenium oxide coating, showing typical cracked surface.

FIGURE 3.3 Scanning electron microscope photograph of a PLC plate silica gel 60, layer... 

Fig. 1.42. Scanning electron-microscopic photographs of different freeze dried products.

Fig. 1.44. Scanning electron-microscopic photographs of a vial containing freeze dried trehalose solution, (a), collapsed product from the bottom of the product (b), shrunk product after 6 months of storage at +20 °C with a RM too high and stored at a too high a temperature (Fig. 6 from [ 1.29]).

Figure 6 Scanning electron microscope photograph of coded 0.75 pm line-space images obtained with the 2-methyl resorcinol-PDMSX copolymer ( = 4400 g/mole) containing (a) 20 wt % and (b) 30 wt % diazonaphthoquinone dissolution inhibitor.

Figure 7 Scanning electron microscope photographs of coded 0.5 (im line-space patterns obtained in the o-cresol novolac-PDMSX ( = 510 g/mole) based resist followed by O2 RIE pattern transfer.

Humpton and Ormsby (1976) presented scanning electron microscope photographs that show the range of morphologies adopted by the many members of the zeolite group of minerals. For more detail on the many intricate structures of natural and synthetic zeolites, see Breck (1974), Sand and Mumpton (1977), Flanigen (1977), or Barrer (1978). 

Figure 4.9. Scanning electron microscope photographs showing the roughening transition of 111) faces of a TiOj crystal and the formation of hollowed needle crystals as impurities are added [19]. Growth occurs by liquid phase epitaxy on a (001) substrate. Fe203 is added as an impurity in the following amounts (a) 0%. (b) 1.3 mol%,...

Figure 9-12 Scanning electron microscopic photographs of crystals for Example 9.3. Option 1, revealing the fibrous structure of the needle-like crystals.

Figure 360. Scanning electron microscope photographs of particles obtained by (a) spray drying and (b) fluid bed agglomeration at various magnifications. (Courtesy of Ciba-Geigy, Basle, Switzerland)...

Figure 361. Scanning electron microscope photograph of a particle obtained in the fluidized spray dryer/agglomerator. (Courtesy of Niro, Columbia, Md., USA)...

Figure 2. Scanning Electron Microscope photograph of FGMs with a kaolin rich second layer.

Photograph 2 Scanning electron microscope photograph of the titanium oxide-kaolin FGM... 

Fig. 4.9. Scanning electron microscopic photograph, gold-shadowed, of bacterial cells derived from corroded concrete. Bar = 1 pm...

Figure 5.1 (a) Schematic diagram of the cross section of a composite reverse osmosis membrane (b) scanning electron microscope photograph of the cross section of 8 composite reverse osmosis membrane. 

Figure 5. Scanning electron microscopic photographs of 2 circumstellar graphite grains (top) and a presolar SiC grain (bottom) isolated from meteorites. Photos courtesy of Sachiko Amari.

Figure 7. Scanning electron microscope photograph of polypropylene surface after 1-h exposure to flowing blood at 200 mL/min and rod rotation...

FIGURE 1.1 Scanning electron microscopic photographs of PHB fihns both before (0 wk, panels on the left) and after 20 weeks (panels on the right) of nonenzymatic hydrolysis in 0.01 N NaOH solution (scale bars, 10 pm) [39]. 

Figure 2. Scanning electron microscope photographs of red blood cells in Cooley s...

Scanning electron microscopic photographs of rabbit bronchial epithelium showed islands of lym-poepithehum varying from a few to a few hundred cells surrounded by a carpet of ciliated epithelium (Bienenstock and Johnston 1976). The flattened cells devoid of dlia consistently possessed small membrane projections, subsequently identified as microvilli by transmission electron microscopy. The lymphoepithelial cells generally contained mitochondria, but endoplasmic reticulum, pinocytotic vesicles, and phagosomes were not a feature. 

Figure 5.11 Photograph of ceramic unit and scanning electron microscope photograph of membrane surface...

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