Boron cross-link

Figure 9. Boron cross linking moiety depends on pH and temperature. (Reproduced with permission from ref. 35. Copyright 1976 Wiley and Sons.)...

FIGURE 2.84 Illustration of ion transport mechanism in GO-PVA and GO-B-VA alkaline gel electrolytes with low and high GO content. (Reprinted from Electrochimica Acta. 132, Huang, Y. F. et al.. Boron cross-linked graphene oxide/polyvinyl alcohol nanocomposite gel electrolyte for flexible solid-state electric donble layer capacitor with high performance, 103-111, Copyright 2014, with permission from Elsevier.)... 

The boron requirement and wall pectin content of many plants are correlated [54-56]. There is increasing evidence that a function of boron essential for normal plant growth and development is to covalently cross-link wall pectins (see Figure 5A). The structural organization of a boron cross-linked pectin network is likely to be a factor that contributes to the physical and biochemical properties of the wall because boron deficiency results in abnormal walls. For example, the results of recent studies provide evidence that the pore size of pectin-rich cell walls is determined in large part by borate ester cross-linking of RG-II [57]. 

Many polymers containing boron in the main chain have been prepared but most of them have either been of low molecular weight or intractable cross-linked structures. Some interest has been shown in the tri-3-aminoborazoles, which polymerise on heating (Figure 29.15f. ... 

Figure 43 The cross-linking reaction of the boron-containing Novolac resin (66) (obtained by the modification of the commercially available Novolac resin) with bis(benzo-l,3,2-dioxaborolanyl)oxide. (Adapted from ref. 91.)...

As an alternative method, poly(cyclodiborazane)s were prepared by the reaction of bis(silylimine)s with chlorodialkylboranes or with methyl dialkylborinates (scheme 18).32 This reaction proceeds via the condensation between V-silylimine and boron halide, eliminating trimethylsilyl halide followed by dimerization. However, the isolated polymer became insoluble after several hours of exposure under air, which resulted from the cross-linking reactions of unreacted trimethylsilyl groups to form trimerized hydrobenzamide derivatives. 

Generally, during hydroboration polymerization of dicyano compounds, the formation of the borazine structures that have a six-membered boron-nitrogen ring (scheme 19a) and dihydroborated end groups (scheme 19b) as a structural defect is unavoidable. The borazine cross-linked structures often cause the gelation, and dehydroboration causes a decrease in molecular weight. 

It is necessary to remember that as well as organic cross-links, elements such as boron, silicon and calcium cross-link all the major external proteins and saccharides even in the walls of prokaryotes. Many of the cross-linking binding sites are of oxidised side chains of biopolymers. As described in Section 8.10, certain of these elements form mineral deposits but now these minerals are frequently found inside the multi-cellular organisms. Here, we see a great difference between the chemo-types of plants and animals. The acidity of the extracellular fluids of plants differs from the neutral fluid of animals. It is not possible to precipitate calcium carbonates (shells) or phosphates (bones) in plants due to the weak acid character of these anions (see Table 8.12). Plants therefore precipitate silica and calcium... 

The case of boron as a network former cation is somewhat specific in that this element has no available d orbitals. However, a p orbital is available when the boron has a coordination number of 3, which allows stabilisation of an electronic doublet of the oxygen or sulphur introduced by the modifier. This oxygen or sulphur giving up a doublet to another boron atom increases the cross-linking by the formation of two BO4 tetrahedra. In hybridisation terms, the boron is altered from the sp configuration to the sp configuration. The coordination change of boron has been especially well observed by NMR (Bray and O Keefe, 1963 Muller-Warmuth and Eckert, 1982). 

Cyclic voltammograms of the COx/Cyt.c electrode corresponding to the bioelectrocatalyzed reduction of 02 (i), and to the reference system, where 02 is excluded (ii). (c) Assembly of an integrated LDH electrode for the bioelectrocatalyzed oxidation of lactate by the surface cross-linking of an affinity complex formed between LDH and different structures of a boronate-linked PQQ-NAD monolayer. Parts (a) and (b) Reproduced from Ref. 27 by permission of the Royal Society of Chemistry (RSC). Part (c) Reproduced with permission from Ref. 25. Copyright 2002 American Chemical Society. 

Substitution of hydrogen by fluorine in compounds with acidic a-hydrogens can be achieved with xenon difluoride and some catalysts. Thus, room-temperature fluorination of 1,3-diketones, e g. 20, with xenon difluoride in the presence of the insoluble cross-linked polysty-rene-4-vinylpyridine, either complexed with boron trifluoridc or Nafion-H, as catalyst, gives mono and difluoro products.27-28... 

Catalyzed aldol additions do not generally proceed with high diastereoselectivity at ambient temperature. Improved stereoselectivity can be achieved by using preformed, diastereomerically pure enolates at low temperatures (Entry 5, Table 7.2). This strategy enables the solid-phase preparation of stereochemically defined polyketides. On cross-linked polystyrene, the observed diastereoselectivity in the addition of boron enolates to aldehydes is the same as that in the homogeneous phase reaction [14,18]. 

Boron Mechanism. Boron functions as a flame retardant in both the condensed and vapor phases. Under flaming conditions boron and halogens form the corresponding trihalide. Because boron (rihalides are effective Lewis acids, they promote cross-linking, minimizing decomposition of the polymer into volatile flammable gases. These trihalides arc also volatile thus they vaporize into the (lame and release halogen which Ihen functions as a Maine inhibitor. 

Myers et al. reported that partially dehydrated APB is an effective intumescent flame retardant in thermoplastic polyurethane.77 APB at 5-10 phr loading in TPU can provide 7- to 10-fold improvement in burn-through test. It is believed that in the temperature range of 230°C-450°C, the dehydrated APB and its released boric oxide/boric acid may react with the diol and/or isocyanate, the decomposed fragments from TPU, to produce a highly cross-linked borate ester and possibly boron-nitrogen polymer that can reduce the rate of formation of flammable volatiles and result in intumescent char. 

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