Finger-type structure

Figure 7. Photo-micrographs of the casting solution/precipitant interphase at (a) the beginning of the precipitation and after (b) 12 sec., (c) 2 f sec. and (d) 5 min. Series I giving a "finger"-type structure and series II giving a "sponge"-type structure.

Figure 1.14 Scanning electron micrograph of membrane cross sections with typical structures (a) symmetric microporous membrane without a "skin" (b) asymmetric membrane with a "finger"-type structure and a dense skin at the surface (c) asymmetric membrane with a "sponge"-type structure, a dense skin, and pore sizes increasing from the surface to the bottom side (d) symmetric membrane with a sponge structure, a dense skin and a uniform pore size distribution in the substructure.

Skin Type Membranes With "Sponge"- and "Finger -Like Structures. In... 

Skin Type Membranes With "Sponge"- and "Finger"-Like Structures. In skin-type membranes, the two characteristic structures shown in Figure 1.14 are obtained. One is a sponge-like structure and the other is a finger-like substructure underneath the skin. 

There is significant interest in zinc sulfide, selenide, and oxide materials and while extensive discussion is not appropriate here, a number of novel complexes that have been developed for their deposition characteristics of these important semiconductors will be highlighted in the context of the ligand types. Zinc has also been used in supramolecular building blocks as a structural element, much as in zinc finger proteins. In these cases the lack of redox chemistry is... 

Table 1.16 Polyhedral compressibility moduli in selected natural and synthetic compounds (adapted from Hazen and Finger, 1982). Data are expressed in megabars (IMbar = 10 bar). Str = type of structure. K = 1/Pr-. ...

In contrast to DNA, RNAs do not form extended double helices. In RNAs, the base pairs (see p.84) usually only extend over a few residues. For this reason, substructures often arise that have a finger shape or clover-leaf shape in two-dimensional representations. In these, the paired stem regions are linked by loops. Large RNAs such as ribosomal 16S-rRNA (center) contain numerous stem and loop regions of this type. These sections are again folded three-dimensionally—i.e., like proteins, RNAs have a tertiary structure (see p.86). However, tertiary structures are only known of small RNAs, mainly tRNAs. The diagrams in Fig. B and on p.86 show that the clover-leaf structure is not recognizable in a three-dimensional representation. 

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