Silanol internal

Several side reactions or post-cuting reactions are possible. Disproportionation reactions involving terminal hydride groups have been reported (169). Excess SiH may undergo hydrolysis and further reaction between silanols can occur (170—172). Isomerization of a terminal olefin to a less reactive internal olefin has been noted (169). Viaylsilane/hydride interchange reactions have been observed (165). 

ISOC reaction was employed to synthesize substituted tetrahydrofurans 172 fused to isoxazolines (Scheme 21) [44b]. The silyl nitronates 170 resulted via the nitro ethers 169 from base-mediated Michael addition of allyl alcohols 168 to nitro olefins 167. Cycloaddition of 170 followed by elimination of silanol provided 172. Reactions were conducted in stepwise and one-pot tandem fashion (see Table 16). A terminal olefinic Me substituent increased the rate of cycloaddition (Entry 3), while an internal olefinic Me substituent decreased it (Entry 4). 

The main calorimetric studies on adsorption of water and ammonia on TS-1 and silicalite-1 have been reported by Bobs et al. [64,83,84,86], while other contributions came from the Auroux group [92] and Janchen et al. [93]. Cor-ma s group has investigated the interaction of water on zeolite [39]. The most important conclusion from the available literature is that calorimetric data require a very careful analysis, as probe molecules interact both with the silanols of the internal hydroxyl nests (see Sect. 3.8) and with Ti(lV) species. 

From the data reported in Fig. 8, it clearly emerges that the acidity of the silicalite-l/H20 and of the TS-I/H2O systems are remarkably different (compare open and full circles in Fig. 8). This difference can be explained as follows TS-1 has two main acidic sites, Ti(IV) Lewis sites and silanols, mainly located in the internal defective nests (see Sect. 3.8), while only the latter are present in silicalite-1. Addition of H2O2 to siUcaUte-l does not modify the titration curve (compare open circles with open squares in Fig. 8). This means that no additional acidic sites appear in the siUcaUte-l system upon adding H2O2, i.e., that hydrogen peroxide molecules coordinated to internal silanol do not modify their acidity. Conversely, addition of H2O2 to TS-1 moves the whole titration curve toward lower pH values, (compare full circles with full... 

A review of the properties of silica as applied to reversed phase separations summarizes a number of issues that have been debated for many years.71 The review categorizes unmodified silanols as free, geminal, vicinal, and internal. The pK, values of silanols average about 7.1, but some silanols may have pK, values as low as 3. As reported in Chapter 4, heavy metal... 

Above 3700 cm 1 bands in this area are due to internal and external silanols. Those OH are not very acids but can interact a little with the probe molecule. 

Linear combination of atomic orbitals (LCAO) method, 16 736 Linear condensation, in silanol polycondensation, 22 557-558 Linear congruential generator (LCG), 26 1002-1003 Linear copolymers, 7 610t Linear density, 19 742 of fibers, 11 166, 182 Linear dielectrics, 11 91 Linear elastic fracture mechanics (LEFM), 1 509-510 16 184 20 350 Linear ethoxylates, 23 537 Linear ethylene copolymers, 20 179-180 Linear-flow reactor (LFR) polymerization process, 23 394, 395, 396 Linear free energy relationship (LFER) methods, 16 753, 754 Linear higher a-olefins, 20 429 Linear internal olefins (LIOs), 17 724 Linear ion traps, 15 662 Linear kinetics, 9 612 Linear low density polyethylene (LLDPE), 10 596 17 724-725 20 179-211 24 267, 268. See also LLDPE entries a-olefin content in, 20 185-186 analytical and test methods for,... 

The columns are usually made from glass which is silanized to remove polar silanol Si-OH groups from its surface that can contribute to the peak tailing of the peaks of polar analytes. These columns have internal diameters of 2-5 mm. The columns are packed with particles of a solid support which are coated with the liquid stationary phase. The most commonly used support is diatomaceous earth (mainly calcium silicate). This material is usually acid washed to remove mineral impurities and then silanized as shown in Figure 11.4 to remove the polar Si-OH groups on the surface of the support, which can lead to tailing of the analyte peak. 

Organically modified MCM-41 can be prepared directly by using alkoxysilanes or organosiloxanes in the synthesis mixture thus coating the internal wall of the pores with functional groups. An example of a condensation reaction of an alcohol with the surface silanol groups to modify the pore wall is shown in Figure 7.22. 

In conU ast to the internal surface reversed-phases described above, Kima-ta s internal surface reversed-phases are synthesized without use of enzymes. These Ci, Cg, Cig, and phenylethyl-modified porous silica supports are treated with HCI at 100 C for 5 h to cleave preferentially the ester bonds at the external surface (127). Hydrolysis inside the pores is extfemely slow because of hydrolysis products that are enriched in the pores, low wettability, and the presence of air bubbles. The generated silanol groups are reacted with 3-glycidoxypropyl-trimethoxysilane, which is then hydrolyzed to hydrophilic diol groups. Several variations of Kimata s supports with different hydrophobicity exist, so these phases can be used for analyzing a broad spectrum of analytes. 

Since the target of the study is the anchoring of the chromophores at the internal surface exclusively, a pre-silylation of the external surface is carried out, based on the experience of a preferred reactivity of the external silanol groups for this process. The selective silylation can result from (i) diffusion limitation and (ii) various nature of silanol groups on internal and external surface. With respect to the size of Ph2SiCl2 it can be supposed that there is a difference in inner and outer surface. 

---