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Layers scratch

To 2 ml. of the ester in a test-tube add slightly more than the same volume of a cold saturated aqueous copper acetate solution. The blue colour of the latter turns immediately to a pale green. Now shake the tube vigorously in order to produce an emulsion of the ester in the aqueous layer. Scratch the sides of the tube with a rod, and shake vigorously as before. Crystallisation may be delayed for about 5 minutes, but, when once started, rapidly gives a copious precipitate... [Pg.268]

Figure 8.9 Proposed schematic model of layers scratched and damaged by mechanical polishing with 0.5-pm-diameter diamond abrasives. Figure 8.9 Proposed schematic model of layers scratched and damaged by mechanical polishing with 0.5-pm-diameter diamond abrasives.
At ordinary temperatures, beryllium resists oxidation in air, although its ability to scratch glass is probably due to the formation of a thin layer of the oxide. [Pg.11]

Dielectric Film Deposition. Dielectric films are found in all VLSI circuits to provide insulation between conducting layers, as diffusion and ion implantation (qv) masks, for diffusion from doped oxides, to cap doped films to prevent outdiffusion, and for passivating devices as a measure of protection against external contamination, moisture, and scratches. Properties that define the nature and function of dielectric films are the dielectric constant, the process temperature, and specific fabrication characteristics such as step coverage, gap-filling capabihties, density stress, contamination, thickness uniformity, deposition rate, and moisture resistance (2). Several processes are used to deposit dielectric films including atmospheric pressure CVD (APCVD), low pressure CVD (LPCVD), or plasma-enhanced CVD (PECVD) (see Plasma technology). [Pg.347]

If scratches and breaks occur in the zinc layers by accidental damage - which is certain to occur when the sheets are erected - then the zinc will cathodically protect the iron (see Fig. 24.4) in exactly the way that pipelines are protected using zinc anodes. This explains the long postponement of rusting. But the coating is only about 0.15 mm thick, so after about 30 years most of the zinc has gone, rusting suddenly becomes chronic, and the roof fails. [Pg.234]

At first sight, the answer would seem to be to increase the thickness of the zinc layer. This is not easily done, however, because the hot dipping process used for galvanising is not sufficiently adjustable and electroplating the zinc onto the steel sheet increases the production cost considerably. Painting the sheet (for example, with a bituminous paint) helps to reduce the loss of zinc considerably, but at the same time should vastly decrease the area available for the cathodic protection of the steel and if a scratch penetrates both the paint and the zinc, the exposed steel may corrode through much more quickly than before. [Pg.235]

The mixture was filtered, the ethyl acetate layer separated and washed with three 100 ml portions of water, dried over Na2S04, filtered and treated with 30 ml of sodium 2-ethyl-hexanoate in n-butanol (34 ml = 0.1 mol). The oil which settled out was scratched to induce crystallization. After stirring for 20 minutes the product, sodium 7-(a-bromoacet-amido)cephalosporanate, was scraped from the sides of the flask and collected. The filter cake was washed with several portions of acetone, air dried, and dried in vacuo over P Os. The yield was 22.5 g and decomposed at 193°C. [Pg.288]

Items of plant fabricated from stainless steels should be inspected before first use and after any maintenance work or unplanned shutdown. All materials that rely for their corrosion resistance on the presence of an oxide or similar passive layer are susceptible to localized attack where that layer is absent or damaged. Damage is most commonly caused by scratching, metallic contamination (nearby grinding or touching with ferrous tools), embedding of grit and weld spatter. [Pg.901]

Salt solutions When a zinc sheet is immersed in a solution of a salt, such as potassium chloride or potassium sulphate, corrosion usually starts at a number of points on the surface of the metal, probably where there are defects or impurities present. From these it spreads downwards in streams, if the plate is vertical. Corrosion will start at a scratch or abrasion made on the surface but it is observed that it does not necessarily occur at all such places. In the case of potassium chloride (or sodium chloride) the corrosion spreads downwards and outwards to cover a parabolic area. Evans explains this in terms of the dissolution of the protective layer of zinc oxide by zinc chloride to form a basic zinc chloride which remains in solution. [Pg.821]

Hardness It is not possible to obtain a reliable figure for the hardness of anodic coatings with either the indentation or scratch methods, because of the influence of the relatively soft metal beneath the anodic film, and the presence of a soft outer layer on thick films. On Moh s Scale, the hardness of normal anodic films lies between 7 and 8, i.e. between quartz and topaz. [Pg.693]

The uses of CVD silicon dioxide films are numerous and include insulation between conductive layers, diffusion masks, and ion-implantation masks for the diffusion of doped oxides, passivation against abrasion, scratches, and the penetration of impurities and moisture. Indeed, Si02 has been called the pivotal material of IC s.1 1 Several CVD reactions are presently used in the production of Si02 films, each having somewhat different characteristics. These reactions are described in Ch. 11. [Pg.373]

Sputtering i s presently the maj or thin-film process for the production of deicing coatings. The coating is satisfactory from an optical standpoint although transmission could still be improved, but it has poor scratch resistance and must be sandwiched between the two layers of safety glass. The CVD oxides films shown in Table 16.1 are particularly attractive since they are inherently abrasion resistant and could be used on the outer surface of the glass. [Pg.411]

Figure 35 shows the optical microscopic images of the first crack point on the sample surface. The scratch scar of monolayer Sample 1 has the feature of brittleness. However, there is an obvious crack along the scratch scar of Sample 2 before the coating delamination. This indicates that mono-layer Sample 2 has the feature of ductility, and the adhesion between the film and the substrate is poor. However, there is no obvious crack before the delamination in the scratch scars of other samples. The feature of multilayer Samples 3 and 4 is different from monolayer Samples 1 and 2. There are no obvious cracks in the scratch scars of Samples 5 and 6, except several small cracks along the edge of the scars. These... [Pg.203]

Hard layer and soft layer combined together can reduce the intrinsic stress of the whole coating [17,18,22-27]. Samples 4, 5, and 6 have higher critical load than that of monolayer A and B. For Samples 5 and 6, no obvious crack occurs during the scratch test. Sample 5 has the highest hardness and reduced elastic modulus among the multilayer samples, and the interfaces in Sample 5 also contribute to scratch resistance. So it has the best micromechanical properties here. [Pg.204]

Sample 6 has the highest critical cracking load among the samples. The main reason is that there are layers A(2 A)/B(3 A)/... A/B and the hardness of the whole multilayer is not too high. Previous study on multilayers showed that the interfaces of multilayers have a great contribution to the multilayers scratch resistance [28]. [Pg.204]

Fig. 49—Depth of scratching scar versus thickness of Fe-N layer, (1-250 yiiN 2-1,250 /itN). Fig. 49—Depth of scratching scar versus thickness of Fe-N layer, (1-250 yiiN 2-1,250 /itN).
Figure 47 shows the typical microscratch scars of a part of the samples under different normal forces. The difference can be found from the scar under 250 /rN. Only a shallow scratch scar is visible on the surface of Fe-N (5 nm)/Ti-N (2 nm) (Fig. 46), but the scars are deeper for other samples except the single crystal silicon wafer (Fig. 47). If the normal force was over 250 /rN, the diamond tip penetrated into and plowed the sample surface. Figure 48 shows the relationship between the lateral force and the thickness of the Fe-N layer under 1,250 /rN. It is found that the lateral force increases with the thickness of the Fe-N layer. For comparison, the lateral force of Fe-N, Ti-N, him and Si (111) wafer under... Figure 47 shows the typical microscratch scars of a part of the samples under different normal forces. The difference can be found from the scar under 250 /rN. Only a shallow scratch scar is visible on the surface of Fe-N (5 nm)/Ti-N (2 nm) (Fig. 46), but the scars are deeper for other samples except the single crystal silicon wafer (Fig. 47). If the normal force was over 250 /rN, the diamond tip penetrated into and plowed the sample surface. Figure 48 shows the relationship between the lateral force and the thickness of the Fe-N layer under 1,250 /rN. It is found that the lateral force increases with the thickness of the Fe-N layer. For comparison, the lateral force of Fe-N, Ti-N, him and Si (111) wafer under...
The friction coefficient is lower for the multilayers than for the Fe-N single layer. This is because the multilayers have a smaller grain size than the Fe-N single layer [37]. For multilayers, the forces applied on the tip are complex during the scratching process. The reason why the lateral force increases with the thickness of the Fe-N layer is mainly because the scratch scar increases with the thickness of the Fe-N layer (Fig. 49). It is the same reason why the lateral force of the Fe-N single layer is larger than that of Fe-N multilayers. [Pg.208]

Figure 4.12 Fluorescence image of PMMA brush layer (a) and schematic drawing of the brush chain (b). The dark region (a) corresponds to the substrate surface exposed by scratching off the brush layer. The filled and open circles indicate the points where the fluorescence anisotropy decay was acquired. Figure 4.12 Fluorescence image of PMMA brush layer (a) and schematic drawing of the brush chain (b). The dark region (a) corresponds to the substrate surface exposed by scratching off the brush layer. The filled and open circles indicate the points where the fluorescence anisotropy decay was acquired.
The five layers of the cornea contain no blood vessels but are nourished by tears, oxygen, and aqueous humor. Minor corneal abrasions heal quickly. Moderate abrasions take 24 to 72 hours to heal. Deep scratches may scar the cornea and require corneal transplant if vision is impaired. Do not use eye patches to treat corneal abrasion, as they decrease oxygen delivery, increase pain, and increase the chance of infection.3... [Pg.936]


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See also in sourсe #XX -- [ Pg.200 , Pg.201 , Pg.202 , Pg.203 , Pg.204 , Pg.205 , Pg.206 , Pg.207 ]




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SCRATCHING

Scratch, scratches

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