Amines, chloro

The reaction can be applied to simple epoxides if polyhydrogen fluoride-pyridine is the reagent. The epoxide-to-fluorohydrin conversion has also been carried out with Sip4 and a tertiary amine.Chloro-, bromo-, and iodohydrins can also be... 

Amine Chloro-(2.2-dichloro-trilluoro-etliyl)-(licptufluoro-propyl)- ElOb, 647 (R1- NCI2 + C1FC-CF,)... 

The literature available from the end of the last report (June 1988) to December 1989 is covered in this chapter. The general chemistry of chromium is reviewed in two continuing series and other reviews on the use of [(TPP)Cr(V)(0)(X)] and amine chloro or fluoro chromates as oxidizing agents have appeared. 

This compound is similar in type to the sodium acet-bromoamide, CHjCONNaBr, which is an intermediate compound in Hofmann s amine synthesis (p. 127). If a weak acid (such as acetic acid) is now added to the solution of the chloro-sodio-amide, the latter compound reacts with the hypo-chlorous acid giving the sulphon-dichloro amide, which being insoluble in water, rapidly separates ... 

In a 500 ml. flask, fitted with a reflux condenser, place 53 g. of 1-chloro-methylnaphthalene (Section IV.23), 84 g, of hexamethylenetetramine and 250 ml. of 1 1 acetic acid [CAUTION 1-Chloromethylnaphtha-lene and, to a lesser degree, a-naphthaldehyde have lachrymatory and vesicant properties adequate precautions should therefore be taken to avoid contact with these substances.] Heat the mixture under reflux for 2 hours it becomes homogeneous after about 15 minutes and then an oil commences to separate. Add 100 ml. of concentrated hydrochloric acid and reflux for a further 15 minutes this will hydrolyse any SchifiF s bases which may be formed from amine and aldehyde present and will also convert any amines into the ether-insoluble hydrochlorides. Cool, and extract the mixture with 150 ml. of ether. Wash the ether layer with three 50 ml. portions of water, then cautiously with 50 ml. of 10 per cent, sodium carbonate solution, followed by 50 ml. of water. Dry the ethereal solution with anhydrous magnesium sulphate, remove the ether by distillation on a steam bath, and distil the residue under reduced pressure. Collect the a-naphthaldehyde at 160-162718 mm. the yield is 38 g. 

Similar difficulties arise in the nitrations of 2-chloro-4-nitroaniline and /)-nitroaniline. Consideration of the rate profiles and orientation of nitration ( 8.2.5) these compounds suggests that nitration involves the free bases. However, the concentrations of the latter are so small as to imply that if they are involved reaction between the amines and the nitronium ion must occur upon encounter that being so, the observed activation energies appear to be too high. The activation energy for the simple nitration of the free base in the case of/>-nitroaniline was calculated from the following equation ... 

A suspension of sodium amide in 500 ml of anhydrous liquid artmonia was prepared from 18 g of sodium (see Chapter II, Exp. 11). To the suspension was added in 10 min with swirling a mixture of 0.30 mol of 1-chloro-l-ethynylcyclohexane (see VIII-2, Exp. 27) and 50 ml of diethyl ether. The reaction was very vigorous and a thick suspension was formed. The greater part of the ammonia was evaporated by placing the flask in a water bath at 50°C. After addition of 500 ml of ice-water the product was extracted three times with diethyl ether. The ethereal extracts were dried over anhydrous KjCOj and subsequently concentrated in a water-pum vacuum. Distillation of the residue afforded the amine, b.p. 54°C/15 mmHg, n 1.4345, in 87% yield. 

Ilvespaa (98) has demonstrated that, using some amines, the 2-chloro-5-nitrothiazole undergoes an opening reaction in a competitive reaction parallel to the normal substitution process. This confirms the sensitivity of position 4 to nucleophilic attack when a nitro group is present in position 5 (Scheme 16). 

Chloro(tris[2-(dimethylamino)ethyl]amine) palladium(II) [66632-97-1]... 

Nickel and Cobalt. Often present with copper in sulfuric acid leach Hquors are nickel [7440-02-0] and cobalt [7440-48-4]. Extraction using an organophosphoric acid such as D2EHPA at a moderate (3 to 4) pH can readily take out the nickel and cobalt together, leaving the copper in the aqueous phase, but the cobalt—nickel separation is more difficult (274). In the case of chloride leach Hquors, separation of cobalt from nickel is inherently simpler because cobalt, unlike nickel, has a strong tendency to form anionic chloro-complexes. Thus cobalt can be separated by amine extractants, provided the chloride content of the aqueous phase is carefully controUed. A successhil example of this approach is the Falcon-bridge process developed in Norway (274). 

Chloro-2,4,6-trifluoropyrimidine [697-83-6] has gained commercial importance for the production of fiber-reactive dyes (465,466). It can be manufactured by partial fluoriaation of 2,3,5,6-tetrachloropyrimidine [1780-40-1] with anhydrous hydrogen fluoride (autoclave or vapor phase) (467) or sodium fluoride (autoclave, 300°C) (468). 5-Chloro-2,4,6-trifluoropyrimidine is condensed with amine chromophores to provide the... 

Some hydantoias are very useful carriers of the nitrogen mustard moiety bis (P-chloroethyl)amine, and are useful ia several tumors and multiagent therapy regimens (128,129). Besides that, some 3-(2-chloro-ethyl)hydantoiQS (32) (130) and oxyranyLmethyUiydantoias, eg,... 

Chlorine dioxide is usually used in aqueous solution. It is a weaker oxidant than hypochlorite. Unlike chlorine it does not react with water to form hypochlorite or with amines to form A/-chloro compounds. Thus chlorine dioxide is easily removed from solutions by passing air through the solution or its headspace. Chlorine dioxide solutions decompose by equation 12 ... 

Dichloropyridazine 1-Oxide produces both isomers with alkoxides. However, the ratio is dependent on the size of the alkoxy group. In the reaction with sodium methoxide 80% of 6-chloro-3-methoxypyridazine 1-oxide and 7.5% of 3-chloro-6-methoxypyridazine 1-oxide are formed. Similar results are also obtained with sodium ethoxide, while sodium propoxide affords only 6-chloro-3-propoxypyridazine 1-oxide. Amines react similarly, while only chlorine at the 3-position can be substituted with an azido group to give 3-azido-6-chloropyridazine 1-oxide. 

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