Schematic representation of polymer

Fig. 1.—Schematic representation of polymer chains in crystalline poly-(hexamethylene adipamide). Layer structure resulting from association of polar groups is indicated by transverse parallel lines. (From Baker and Fuller, J. Am.

Fig. 34.—Schematic representation of polymer molecules in dilute solution.

Fig. 1 Schematic representation of polymers with controlled topology, composition, and functionality synthesized using copper-catalyzed ATRP...

Figure 6.1 General schematic representation of polymer-mediated assembly of nanoparticles (a) functionalization of nanoparticles through place-exchange method, (b) incorporation of complementary functional group to polymers, and (c) self-assembly of nanoparticles through electrostatic or hydrogen bonding interactions.

Figure 2.3. Schematic representation of polymer chains in microporous and macroporous polymers.

Figure 5.2 Schematic representation of polymer dissolution and drug release from enteric-coated tablets.

Fig. 2 Schematic representation of polymer-CD IC formation, the coalescence process, and the coalesced polymer...

Fig. 16 a-d Schematic representation of polymer nanoreactors, a Cross section of triblock copolymer vesicle, b Polymersome with encapsulated enzyme and membrane-embedded channel protein. In the case described in the text, the substrate entering the vesicle is ampicillin, and the product of the hydrolysis is ampicillinoic acid, c Polymersome with embedded ionophores allowing Ca2+ ions to enter the vesicle ere they react with phosphate ions to form calcium phosphate crystals, d The LamB protein serves as a receptor to the 1 phage virus which can inject its DNA through the channel into the polymersome [259]. Reproduced with permission of The Royal Society of Chemistry... 

SCHEME 13.7 Schematic representation of polymer surface coating process by photoinduced grafting onto technique. 

FIGURE 3.32 Schematic representation of polymer flow through a die orifice. 

Figure 5.3. Schematic representation of polymer and plasticizer points of interaction [Adapted, by permission, from Moorshead T C, Advances in PVC Compounding and Processing, Ed. M. Kaufman Sons, London, 1962, p. 24.]...

Figure 3.4 Schematic representations of polymer microstructures accessible through controlled radical polymerization techniques.

Figure 1. Schematic representations of polymer-surfactant complexes described in the text. In the block copolymer-surfactant complex (Type 5), the dark lines represent the polar blocks of the polymer molecule whereas the lighter lines represent the non-polar blocks.

FIGURE 14.6 Schematic representation of polymer layer overlap. 

Schematic representation of polymer/polymer and polymer/solvent contacts in solu-... 

Figure 22 Schematic representation of polymer-polymer aral polymer—substrate interactions. Xs liic net energy difference between the proce

Figure 7 Schematic representation of polymer-mediated layer-by-layer assembly of a two-dimensional array using 4-nm FePt nanoparticles and PEI. Step 1 PEI polymer deposition Step 2 FePt nanoparticle deposition.

FIGURE 11.2 Schematic representation of polymers with different composition. (Adx >ted... 

Figure 10.6 Schematic representation of polymer preparation using catechol-modified and polymerizable monomers (A) and using a polymer-bound initiator to form a block copotymer (B). In the presence of bi-functional crosslinkers, potymerization forms a three-dimensional pol3mier network containing catechol (C). R represents the side chain of the monomers used to copotymerize with the catechol-functionalized monomers.

Fig. S.S. Schematic representation of polymer formation inside vinyl chloride drops.

Polymers can exist in the crystalline and amorphous regions, and the crystallinity of polymeric fibers is one of the most important aspects of polymer science. Crystallinity is a measure of the percentage of crystalline regions in the polymer with respect to amorphous region. Rgure 1.8 is a schematic representation of polymer chains in the crystalline and amorphous regions. 

Figure 75. Schematic representations of polymers formed via the linkiiig of chromium tris(dithiocarbamate) units by Cu, , moieties.

Figure 8.2 Schematic representation of polymer brush formation varying with the density of the polymer attached to the smface.

Figure 7. Schematic representation of polymer adsorbed on a substrate and the possible interactions that can preserve molecular continuity from the adsorbed layer to bulk regions of the adhesive material ...

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