titanium tetrachloride

In the past titanium tetrachloride has also been used to create naval smokescreens.

Inside, titanium tetrachloride was introduced, producing bright white smoke.

The titanium tetrachloride smoke is irritant and unpleasant to breathe.

Chemical smoke devices may use titanium tetrachloride to produce smoke.

Used together with titanium tetrachloride, aluminium hydride can add across double bonds.

It is expected that three quarters of the titanium tetrachloride can be recovered, reducing raw materials costs by £600,000 a year.

It is prepared by treating titanium tetrachloride with isopropanol.

Titanium tetrachloride or organo titanates can also be used.

The catalyst is titanium tetrachloride and the workup is acidic.

Spillage of titanium tetrachloride occurred when a heat treatment furnace was been serviced by the European manufacturer.

Therefore navies turned to various chemicals, such as titanium tetrachloride, that produce a white, low-lying cloud.

Titanium tetrachloride is the inorganic compound with the formula TiCl.

Titanium tetrachloride is a versatile reagent that forms diverse derivatives including those illustrated below.

In this process, the feedstock is chlorinated at 1000 C with carbon and chlorine gas, giving titanium tetrachloride.

Kroll devised ways of reducing titanium tetrachloride (TiCl) into its metal form.

For example, flower-like morphologies were obtain by treating a solution of sulfur in 1-octadecene with titanium tetrachloride.

Titanium butoxide is produced by reacting titanium tetrachloride with butanol.

The titanium tetrachloride is purified by distillation.

With this background, Kroll developed both new reductants and new apparatus for the reduction of titanium tetrachloride.

It's titanium tetrachloride.

A particularly effective dense white smoke is produced by exposing titanium tetrachloride to the atmosphere, but this is both toxic and corrosive.

Titanium tetrachloride was found to reduce with hydrogen at high temperatures to give hydrides that can be thermally processed to the pure metal.

This chlorination step transformed the films into carbide-derived carbon layers while releasing titanium tetrachloride (TiCl4).

It can be more easily synthesized from titanium tetrachloride, but this product is typically less pure that that obtained from the elements.

By replacing the titanium tetrachloride with titanium tetraiodide, he obtained polybutadiene with 90-95% cis-1,4-structures.