Reactivity sodium borohydride

Common catalyst compositions contain oxides or ionic forms of platinum, nickel, copper, cobalt, or palladium which are often present as mixtures of more than one metal. Metal hydrides, such as lithium aluminum hydride [16853-85-3] or sodium borohydride [16940-66-2] can also be used to reduce aldehydes. Depending on additional functionahties that may be present in the aldehyde molecule, specialized reducing reagents such as trimethoxyalurninum hydride or alkylboranes (less reactive and more selective) may be used. Other less industrially significant reduction procedures such as the Clemmensen reduction or the modified Wolff-Kishner reduction exist as well. 

Recent papers by a manufacturer of sodium borohydride, NaBH (145,146), have demonstrated that excellent removal of metals and color of acid, direct, and reactive dyes for textiles and paper can be achieved with bisulfite-catalyzed borohydride reduction in combination with polymer flocculation. 

Manx- different reducing agents are effective, but the most common choice in the laboratory is sodium cyanoborohydride, NaBH3CN. Sodium cyanoboro-hydride is similar in reactivity to sodium borohydride (NaBH4) but is more stable in weak acid solution. 

Sulphoxides are reduced by the more powerful metal hydride reducing agents14, but the less reactive reagents such as sodium borohydride are ineffective. Recently, Yoon25 has... 

The highly strained and reactive 2iT-azirines have been extensively studied for various synthetic purposes, such as ring expansion reactions, cycloaddition reactions, preparation of functionalized amines and substituted aziridines. The older literature on azirines in synthesis has extensively been reviewed [69]. Concerning azirines with defined chirality only scarce information is available. Practically all reactions of azirines take place at the activated imine bond. Reduction with sodium borohydride leads to cz5-substituted aziridines as is shown in Scheme 48 [26,28]. 

Lewis acid strength and hardness of the lithium cation. Both LiBH4 and Ca(BH4)2 are more reactive than sodium borohydride. This enhanced reactivity is due to the greater Lewis acid strength of Li+ and Ca2+, compared with Na+. Both of these reagents can reduce esters and lactones efficiently. 

Sodium borohydride is sometimes used in conjunction with CeCl3 (Luche s reagent).70 The active reductants under these conditions are thought to be alkoxyborohydrides. Sodium cyanoborohydride is a useful derivative of sodium borohydride.71 The electron-attracting cyano substituent reduces reactivity and only iminium groups are rapidly reduced by this reagent. 

Unlike with sodium borohydride (see Section 11.01.5.2), pyrrolizin-3-one 2 reacts with lithium aluminohydride mainly as an amide. No conjugate addition occurs, and only the reductive lactam cleavage takes place to give stereoselectively the (Z)-allylie alcohol 77. Similarly, benzo-annulated pyrrolizin-3-one 17 gives the corresponding benzylic alcohol 78. The same reactivity was observed with organometallics such as methyllithium which gives exclusively the tertiary (Z)-allylic alcohol 79 (Scheme 7). 

Early use of the low-molecular-weight quaternary ammonium borohydrides in hydrocarbon solvents showed little advantage over the use of sodium borohydride in aqueous or alcoholic media. Although the ammonium salts in benzene appealed to be capable of effecting all the normal reductions exhibited by the sodium salt in water, they appeared to be generally less reactive. This is well illustrated by the recrystallization of tetra-n-butylammonium borohydride from acetone, if the operation is performed rapidly [5,6],... 

Kinetic studies established that tetra-n-butylammonium borohydride in dichloromethane was a very effective reducing agent and that, by using stoichiometric amounts of the ammonium salt under homogeneous conditions, the relative case of reduction of various classes of carbonyl compounds was the same as that recorded for the sodium salt in a hydroxylic solvent, i.e. acid chlorides aldehydes > ketones esters. However, the reactivities, ranging from rapid reduction of acid chlorides at -780 C to incomplete reduction of esters at four days at 250 C, indicated the greater selectivity of the ammonium salts, compared with sodium borohydride [9], particularly as, under these conditions, conjugated C=C double bonds are not reduced. 

A difference in the reactivities and selectivities between tetra-n-butylammonium borohydride and sodium borohydride in the reduction of conjugated ketones is well illustrated with A1-9 2-octalone (Scheme 11.3) [17], Reduction with the sodium salt in tetrahydrofuran is relatively slow and produces the allylic alcohol (1) and the saturated alcohol (2) in a 1.2 1 ratio whereas, in contrast, tetra-n-butylammonium borohydride produces the non-conjugated alcohol (3) (50%) and the saturated alcohol (2) (47%), with minor amounts of the ketone (4), and the allylic alcohol (1) [16]. It has been proposed that (3) results from an initial unprecedented formation of a dienolate anion and its subsequent reduction. 

The further reactivity of these complexes was then examined, and it was found that treatment of 148.a with sodium borohydride resulted in a quantitative and entirely selective reduction of the uncomplexed organic carbonyl functionality to give complex 149. 

Reactivity. Chemicals that react violently with air or water are considered hazardous examples are sodium metal, potassium metal, and phosphorus. Reactive materials also include strong oxidizers such as perchloric acid, and chemicals capable of detonation when subjected to an initiating source, such as solid, dry < 10% H2O picric acid, benzoyl peroxide, or sodium borohydride. Solutions of certain cyanide or sulfides that could generate toxic gases are also classified as reactive. The potential for finding such chemicals in a refinery is... 

An analogous series of reactions is involved when sodium borohydride is used as the reducing agent. Sodium borohydride is considerably less reactive than LAH, and reactions proceed much more slowly. This reagent may be used in alcoholic or even aqueous solution, so there are no particular hazards associated with its use. 

The difference in the reactivity of benzylic versus aromatic halogens makes it possible to reduce the former ones preferentially. Lithium aluminum hydride replaced only the benzylic bromine by hydrogen in 2-bromomethyl-3-chloro-naphthalene (yield 75%) [540]. Sodium borohydride in diglyme reduces, as a rule, benzylic halides but not aromatic halides (except for some iodo derivatives) [505, 541]. Lithium aluminum hydride hydrogenolyzes benzyl halides and aryl bromides and iodides. Aryl chlorides and especially fluorides are quite resistant [540,542], However, in polyfluorinated aromatics, because of the very low electron density of the ring, even fluorine was replaced by hydrogen using lithium aluminum hydride [543]. 

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