Citations:latices


 * 1) Plural form of latex.
 * 2) * 1898: IDEAL (Project), Annals of Botany, pp166{1} & 170{2} & {3}
 * {1}A microscopic examination of any of these latices…
 * {2}Unfortunately few latices have as yet been examined for their proteid constituents, chiefly on account of the difficulty of obtaining them in their natural condition in European laboratories, owing to their coagulating and undergoing decomposition during the journey from the tropics1.
 * {3}These coagula on forming gather up the rubber-particles (and probably starch-grains also, in the case of starch-containing latices) in the same way as the white-of-egg gathers…
 * 1) * 1928: Chemical Society Division of Rubber Chemistry, Rubber Chemistry and Technology, pp18{1} & 540{2}
 * {1}To this end, rubber and balata were prepared fresh from the corresponding latices, in the hope that in this way products would be obtained with the least possible changes having taken place20.
 * {2}Technically the synthetic latices occurring as the intermediate products in the manufacture of the massive synthetics are most interesting.
 * 1) * 1949: American Chemical Society – Rubber Division, Rubber Chemistry and Technology, p914
 * The three creams separated from the three degraded latices did not coagulate when heated in the presence of zinc oxide.
 * 1) * 1991: Ernest W. Flick, Water Soluble Resins: An Industrial Guide, p782
 * This class of nitrile latices also demonstrates good washability, high abrasion resistance, excellent long term aging, adhesion to hydrophilic materials and compatibility with polar resins such as copolymers of vinyl chloride and vinylidine chloride.
 * 1) * 2001: Christopher Aspell Finch & Henry Warson, Applications of Synthetic Resin Latices, pXIII (Preface)
 * The many advances that have been made both in the development of polymer emulsions (described more correctly as latices, by analogy with natural rubber latices) and their application in various industries merit a new trilogy under the title Applications of Synthetic Resin Latices.
 * 1) * 2006: Lars Börger & Walter Mächtle, Analytical Ultracentrifugation of Polymers and Nanoparticles, p183
 * To now study “harder” latices with systematically increasing Tg, we synthesized such “harder” latices by replacing, in our starting mother latex, parts p of the “soft” monomer n-BA by the “hard” monomer methyl methacrylate (MMA). Thus, the seven new mother latices have the copolymer composition (78–p) n-BA/20 MMA/2 MAMA/p MMA, with p = 0, 10, 20, 30, 40, 50, and 60 wt%.
 * [¶] Figure 6.19 shows the particle size distribution curves of these seven “harder” mother latices. All seven latices have narrow, unimodal, and nearly identical particle size distributions. The corresponding results of the density gradient measurements on these latices are summarized in the schematic diagram in the center of Fig. 6.20. The monomer composition of the corresponding latices is listed on the left-hand side; the corresponding Tg is specified on the right-hand side. All latices in Fig. 6.20 show narrow turbidity bands, implying they all are chemically homogenous.