Titanium addition with

Niobium is important as an alloy addition in steels (see Steel). This use consumes over 90% of the niobium produced. Niobium is also vital as an alloying element in superalloys for aircraft turbine engines. Other uses, mainly in aerospace appHcations, take advantage of its heat resistance when alloyed singly or with groups of elements such as titanium, tirconium, hafnium, or tungsten. Niobium alloyed with titanium or with tin is also important in the superconductor industry (see High temperature alloys Refractories). 

Precipitation of a hydrated titanium oxide by mixing aqueous solutions of titanium chloride with alkaU forms the precipitation seeds, which are used to initiate precipitation in the Mecklenburg (50) variant of the sulfate process for the production of pigmentary titanium dioxide. Hydrolysis of aqueous solutions of titanium chloride is also used for the preparation of high purity (>99.999%) titanium dioxide for electroceramic appHcations (see Ceramics). In addition, hydrated titanium dioxide is used as a pure starting material for the manufacture of other titanium compounds. 

In titanium acylates, the carboxylate ligands are unidentate, not bidentate, as shown by ir studies (333,334). The ligands are generally prepared from the hahde and silver acylate (335). The ben2oate is available also from a curious oxidative addition with ben2oyl peroxide (335—338) ... 

T.T.S curves as those in Fig. 3.21 can be developed for material cooled very rapidly following solution treatment but the C curve range is a OO-550°C and the nose is at very short times. Freedom from sensitisation in welding can be obtained by ensuring extremely low carbon (and nitrogen) but such levels are not commercially feasible. Stabilisation by niobium and titarium is feasible, but higher ratios are needed than with austenitic steels. With most of the super ferritic group a combination of a practical low carbon level and titanium addition is used. 

Almost 15 years ago Sakurai and Hosomi, in pioneering work, showed that intermolecular addition of an allylsilane to a,j6-unsaturated ketones in the presence of titanium(IV) chloride as the Lewis acid gave the desired 1,4-addition products1 4. In the case of 4,4a,5,6,7,8-hexahy-dro-2(3//)-naphthalenone, reaction was shown to proceed by 1,4-addition with exclusive production of the ris-fused product in high chemical yield. 

The titanium reagent also dimethylates aromatic aldehydes." Triethylaluminum reacts with aldehydes, however, to give the mono-ethyl alcohol, and in the presence of a chiral additive the reaction proceeds with good asymmetric induction." A complex of Me3Ti-MeLi has been shown to be selective for 1,2 addition with conjugated ketones, in the presence of nonconjugated ketones." ... 

Ketone-aldehyde additions have been effected using TiCl4 in toluene.24 These reactions exhibit the same stereoselectivity trends as other titanium-mediated additions. With unsymmetrical ketones, this procedure gives the product from the more-substituted enolate.25... 

As is the case for aldol addition, chiral auxiliaries and catalysts can be used to control stereoselectivity in conjugate addition reactions. Oxazolidinone chiral auxiliaries have been used in both the nucleophilic and electrophilic components under Lewis acid-catalyzed conditions. (V-Acyloxazolidinones can be converted to nucleophilic titanium enolates with TiCl3(0-/-Pr).320... 

Enantioselective reactions involving q1 -allyltitanocenes are almost unknown. An attempt to realize an asymmetric transfer of the allyl group has been reported by Reetz [40], who employed a chiral titanium precursor with two different Cp groups and a stereo-genic center at the metal (CpCptBu(C6F5)Cl) [41]. However, the addition of the derived al-lyltitanium reagent to aldehydes was found to proceed with a low chiral induction (ee up to 11%) in this case. 

Scheme 13.26. Highly enantioselective homoaldol addition with a chiral titanium N-allylurea reagent.

A modified procedure suitable for intramolecular reductive coupling is achieved using low-valence titanium prepared by reduction of titanium trichloride with a zinc-copper couple followed by the extremely slow addition of ketone to the refluxing reaction mixture (0.0003 mol over a 9-hour period by use of a motor-driven syringe pump) [S60. ... 

In the search for substitutes, other considerations than just sulfide stability have to be considered. These include the possible interference of the newly introduced element with other steel porperties, the plasticity of the new sulfides, the physical alloyability of the additive and, of course, the cost effectiveness of the additive. Zirconium and titanium interfere with other properties of the steel because of the excessive stability of their nitrides. Figure 9, and carbides. Figure 10. Although considerable usage of these two elements has played a part in sulfide substitution — over 500 metric tons of nuclear zircalloy scrap were used in — it appears that their role will progressively fade away primarily because of poor low temperature impact properties of steels treated with Zr and Ti. 

Simple diastereoselectivity comes into play when allenylmetal compounds are added to aldehydes, since adducts such as 1 a/b contain both an axis and a center of asymmetry. Hence, diastereomeric mixtures are produced. When chiral aldehydes are used in such reactions, the diastereoselectivity also depends on the relative rate by which the enantiomers of the racemic allenylmetallic species interconvert, i.e., relative to the rate of addition to the chiral aldehyde. Apart from reactions of allenyllithium and -titanium reagents with aldehydes90-94, few such intermolecular, simple diastereoselective reactions yielding allenes have been reported. 

Reaction of the bis(allyl) titanium complexes 16 and 18 with aldehydes occurs in a step-wise fashion with intermediate formation of the corresponding mono (allyl) titanium complex containing the alcoholate derived from 4 and 5 as a ligand at the Ti atom. Then the mono(allyl)titanium complexes combine with a second molecule of the aldehyde. Both the bis (allyl) titanium complexes and the mixed mono(allyl)titanium complexes react with the aldehydes at low temperatures with high regio- and diastereoselectivities. Interestingly, control experiments revealed that for the reaction of the bis (allyl) titanium complexes with the aldehyde to occur the presence of Ti(OiPr)4 is required, and for that of the intermediate mono(allyl)titanium complexes the addition of ClTi(OiPr)3 is mandatory (vide infra). 

The Orsay group found serendipitously that methyl p-tolyl sulfide was oxidized to methyl p-toly 1 sulfoxide with high enantiomeric purity (80-90% ee) when the Sharpless reagent was modified by addition of 1 mole equiv. of water [16,17]. The story of this discovery was described in a review [19], Sharpless conditions gave racemic sulfoxide and sulfone. Careful optimization of the stoichiometry of the titanium complex in the oxidation of p-tolyl sulfide led to the selection of Ti(0iPr)4/(7 ,7 )-DET/H20 (1 2 1) combination as the standard system [ 17]. In the beginning of their investigations, the standard conditions implied a stoichiometric amount of the chiral titanium complex with respect to the prochiral sulfide [16,17,20-23]. Later, proper conditions were found, which decreased the amount of the titanium complex without too much alteration of the enantioselectivity [24,25],... 

Prior to true subsurface bone spectroscopy, Penel and coworkers obtained bone Raman spectra using a titanium chamber with a fused silica window placed in the calvaria of New Zealand rabbits [2]. With this apparatus they were able to study both bone tissue and implanted hydroxyapatite and P-tricalcium phosphate over a 8-month period. In addition to bone spectra, hemoglobin spectra were obtained close to blood vessels. 

C-M bond addition, for C-C bond formation, 10, 403-491 iridium additions, 10, 456 nickel additions, 10, 463 niobium additions, 10, 427 osmium additions, 10, 445 palladium additions, 10, 468 rhodium additions, 10, 455 ruthenium additions, 10, 444 Sc and Y additions, 10, 405 tantalum additions, 10, 429 titanium additions, 10, 421 vanadium additions, 10, 426 zirconium additions, 10, 424 Carbon-oxygen bond formation via alkyne hydration, 10, 678 for aryl and alkenyl ethers, 10, 650 via cobalt-mediated propargylic etherification, 10, 665 Cu-mediated, with borons, 9, 219 cycloetherification, 10, 673 etherification, 10, 669, 10, 685 via hydro- and alkylative alkoxylation, 10, 683 via inter- andd intramolecular hydroalkoxylation, 10, 672 via metal vinylidenes, 10, 676 via SnI and S Z processes, 10, 684 via transition metal rc-arene complexes, 10, 685 via transition metal-mediated etherification, overview,... 

Polyethylene-Wock-poly(clhylcnc-co-norbornene) (PE-fo-P(E-co-NBl ) block copolymer was successfully synthesized by a titanium complex with two non-symmetric bidentate /J-cnaminokclonalo ligands [136,137]. Bis(pyrrolide-imine)titanium complex also has the ability to produce the PE-fo-P(E-co-NBE) block copolymer. PE-fo-PS was synthesized via sequential monomer addition during homogeneous polymerization with bis(phenoxy-imine)metal catalysts [138]. 

A number of other acyclic Z and E lithium enolates were quenched similarly. In all cases the stereochemistry at the enol double bond was retained, as shown by subsequent conversion into the corresponding silyl enol ether. Upon reacting the titanium enolates with aldehydes, very clean aldol addition occured (>90% conversion at —78 °C). Generally, erythro-selectivity was observed irrespective of the geometry of the enolate. Equations 64 and 65 are typical25). 

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