Electron microscope, 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 4. Electron microscope photograph of an osteoclast on the surface of living bone.

In Fig. 7, electron microscope photographs of two different types of high-po-rosity bioceramics are shown. The bone material on the left has 250- j. pore size with a background of micropores [Fig. 7(a)], The specimen on the right-hand side has 400- i pores with a background of 250-p pores as well as displaying micro-porosity within the pores [Fig. 7( >)]. We are also able to regulate the size and distribution of porosity in our bioceramic materials. 

Transmission electron microscope photograph of 2-methyl re-sorcinol-PDMSX copolymers using (a) 4400 g/mole PDMSX and (b) 510 g/mole PDMSX. 

Transmission electron microscope photograph of poly (hydroxy-styrene)-PDMSX copolymer. 

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). 

Figures 10.1.3a and 10.1.3b show the SEM and TEM (transmission electron microscope) photographs of the resultant carbon sample, respectively. The SEM photograph indicates the formation of tubular carbon, whose diameter is almost equal to the channel diameter (230 nm) of the anodic oxide film template. Each tube ramifies into several thin tubes near the end. This branchlike structure originates from a similar branching in pore structure of the commercial anodic oxide film near its surface. A more clear view of the structure of the carbon samples is given by...

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 9-4 Electron micrograph (x40,000) of two linked (catenated) cyclic mitochondrial DNA molecules from a culture of human cells. The DNA was stained with uranyl acetate, then shadowed with platinum and palladium atoms in high vacuum to make the molecules easily visible in the electron microscope. (Photograph supplied by Dr. B, S. Hudson and the late Dr. J. Vinograd.)...

To what extent are the ordered structures observable in the electron microscopic photographs of the polymer films cast from solution influenced by the substrate Any significant influence can be excluded for the following reasons ... 

These data have been verified by electron microscope photographs Fig. 11 shows an example for a catalyst reduced at 500° C. Clearly, the carrier forms a large porous structure, in which the small nickel crystals find a place. 

Figure 4. Electron microscope photographs of PVC particles at various stages of conversion. Each photograph is 1.25fi wide...

Fig. 9a,b. Transmission electron microscope photograph of MIP nanoparticles prepared by miniemulsion polymerization a control polymer prepared in absence of template b polymer prepared in presence of template l-BFA [30]... 

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