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Glass scanning electron micrograph

Isotropic Etching, Fig. 5 Micro channel obtained after isotropic etching in glass (scanning electron micrograph, scale bar 0.3 mm, IPHT Jena)... [Pg.1469]

Figure 5. Scanning electron micrograph of tensile fractured surface of 30% glass reinforced MA-modified PP (unstabi1ised, 1C1-HF22). Figure 5. Scanning electron micrograph of tensile fractured surface of 30% glass reinforced MA-modified PP (unstabi1ised, 1C1-HF22).
The polymer and glass microspheres employed in the pressure-sensitive release of chemicals range in size from 1 pm to 1 mm in diameter. (For comparison, a human hair is typically 80-100 pm in diameter.A scanning electron micrograph illustrating the morphology of the particles appears in color Fig. 14.2.1. ... [Pg.212]

Figure 3.1. Scanning electron micrograph of the cross-section of a porous glass membrane with symmetric microstructurc (courtesy of Asahi Glass). Figure 3.1. Scanning electron micrograph of the cross-section of a porous glass membrane with symmetric microstructurc (courtesy of Asahi Glass).
Fig. 1.9 Scanning electron micrograph (x750) of a macroporous film showing A, superficially smooth surface originally in contact with glass slide B, surface layer cleaved away (serendipit-ously) to show rough porous interior C) rough porous interior, edge view (bar = 10 pm). Fig. 1.9 Scanning electron micrograph (x750) of a macroporous film showing A, superficially smooth surface originally in contact with glass slide B, surface layer cleaved away (serendipit-ously) to show rough porous interior C) rough porous interior, edge view (bar = 10 pm).
Figure 5.8 Scanning electron micrograph of glass spheres before pressurizing (left) and after pressurizing to 200 bar. Figure 5.8 Scanning electron micrograph of glass spheres before pressurizing (left) and after pressurizing to 200 bar.
Fig. 6. Scanning electron micrograph picture of borosilicate glass (LAWA33, see Table 1) reacted with solution at an elevated temperature. The hexagonal phase is herschelite, (Na, K)AlSi206-3H20. Fig. 6. Scanning electron micrograph picture of borosilicate glass (LAWA33, see Table 1) reacted with solution at an elevated temperature. The hexagonal phase is herschelite, (Na, K)AlSi206-3H20.
Figure 22 shows scanning electron micrographs of the composite membrane. The gel was chemically fixed on the porous glass by a radical polymerization. In the photograph, the gel layer of about 5 pm in thickness can be observed on the surface of the porous glass. [Pg.228]

Fig. 22. Scanning electron micrograph of a NIPA gel and porous glass composite membrane... Fig. 22. Scanning electron micrograph of a NIPA gel and porous glass composite membrane...
Figure 8 Scanning electron micrograph of silica-gel thin layer formed on the inner wall of capillary tubing. There are three parts in the photo. The right part is a section of fused-silica capillary glass body, and the center is a cross-sectional view of a section of silica-gel thin layer foamed on the inner wall, thickness ca. 0.3 pm. On the surface of the silica-gel layer, two-thirds of the photo, there are a lot of holes. From the photo, the silica-gel layer has a nano-cell structure. Figure 8 Scanning electron micrograph of silica-gel thin layer formed on the inner wall of capillary tubing. There are three parts in the photo. The right part is a section of fused-silica capillary glass body, and the center is a cross-sectional view of a section of silica-gel thin layer foamed on the inner wall, thickness ca. 0.3 pm. On the surface of the silica-gel layer, two-thirds of the photo, there are a lot of holes. From the photo, the silica-gel layer has a nano-cell structure.
Fig. 6 Scanning electron micrograph of a cross-section of a nickel coating on glass (magnification 13,000x ) showing the dense nature of the coating. Coating thickness is approx 100 nm. Fig. 6 Scanning electron micrograph of a cross-section of a nickel coating on glass (magnification 13,000x ) showing the dense nature of the coating. Coating thickness is approx 100 nm.
Scanning electron micrographs given in Fig. 3 clearly show a homogeneous texture of the corresponding meso- or macroporous glass membranes. [Pg.351]

Figure 7. Scanning electron micrograph of a mesoporous Ti02 film supported on conducting glass. The predominant facets of the ana-tase crystals have the (101) orientation. Figure 7. Scanning electron micrograph of a mesoporous Ti02 film supported on conducting glass. The predominant facets of the ana-tase crystals have the (101) orientation.
Fig. 12 Scanning electron micrographs of failed surfaces of an E-glass/epoxy composite. Fig. 12 Scanning electron micrographs of failed surfaces of an E-glass/epoxy composite.
Figure 9. Scanning electron micrographs of Epon 828 resin cured with Versamid 140 (network comprising 25% glass beads by volume etched for 7 hr)... Figure 9. Scanning electron micrographs of Epon 828 resin cured with Versamid 140 (network comprising 25% glass beads by volume etched for 7 hr)...
Fig. 17 Scanning electron micrograph of pulse laser-ablated barium borosilicate glass. 7=300 fs, 2=620 nm, F0=2.5 J creT2, N= 5, detail... Fig. 17 Scanning electron micrograph of pulse laser-ablated barium borosilicate glass. 7=300 fs, 2=620 nm, F0=2.5 J creT2, N= 5, detail...
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