Dilute aqueous acid

SchifT s bases A -Arylimides, Ar-N = CR2, prepared by reaction of aromatic amines with aliphatic or aromatic aldehydes and ketones. They are crystalline, weakly basic compounds which give hydrochlorides in non-aqueous solvents. With dilute aqueous acids the parent amine and carbonyl compounds are regenerated. Reduction with sodium and alcohol gives... 

Nickel is a moderately lustrous, silvery metal, and is extensively used in alloys (for example coinage, stainless steel) and for plating where a durable resistant surface is required. It is also used as an industrial catalyst, for example in the hydrogenation of unsaturated organic compounds. It is attacked by dilute aqueous acids but not by alkalis it combines readily with many non-metals on heating. 

On standing in dilute aqueous acid compound A is smoothly converted to mevalonolactone... 

Ester hydrolysis is the most studied and best understood of all nucleophilic acyl sub stitutions Esters are fairly stable in neutral aqueous media but are cleaved when heated with water m the presence of strong acids or bases The hydrolysis of esters m dilute aqueous acid is the reverse of the Eischer esterification (Sections 15 8 and 19 14)... 

D Altrosan is converted to D altrose by dilute aqueous acid Suggest a reasonable mecha nism for this reaction... 

Under acidic conditions, furfuryl alcohol polymerizes to black polymers, which eventually become crosslinked and insoluble in the reaction medium. The reaction can be very violent and extreme care must be taken when furfuryl alcohol is mixed with any strong Lewis acid or Brn nstad acid. Copolymer resins are formed with phenoHc compounds, formaldehyde and/or other aldehydes. In dilute aqueous acid, the predominant reaction is a ring opening hydrolysis to form levulinic acid [123-76-2] (52). In acidic alcohoHc media, levulinic esters are formed. The mechanism for this unusual reaction in which the hydroxymethyl group of furfuryl alcohol is converted to the terminal methyl group of levulinic acid has recendy been elucidated (53). 

Silver difluoride [7783-95-1], AgF2, is a black crystalline powder. It has been classified as a hard fluorinating agent (3) which Hberates iodine from KI solutions and o2one from dilute aqueous acid solutions on heating. It spontaneously oxidizes xenon gas to Xe(II) in anhydrous hydrogen fluoride solutions (20). 

Soybean concentrate production involves the removal of soluble carbohydrates, peptides, phytates, ash, and substances contributing undesirable flavors from defatted flakes after solvent extraction of the oil. Typical concentrate production processes include moist heat treatment to insolubilize proteins, followed by aqueous extraction of soluble constituents aqueous alcohol extraction and dilute aqueous acid extraction at pH 4.5. 

The submitters report that both l,4-diazabicyclo[2.2.2]octane and triethylamine have been used to catalyze this decomposition. Tri-ethylamine was less satisfactory as a catalyst because of its relatively rapid reaction with the solvent, carbon tetrachloride, to form triethylamine hydrochloride and because of difficulty encountered in separating triethylamine from the dicarbonate pi oduct. The 1,4-diazabicyclo-[2.2.2]octane was efficiently separated from the dicarbonate product by the procedure described in which the crude product was washed with very dilute aqueous acid. 

The gas is remarkably unreactive (like CF4) being unaffected by water or dilute aqueous acid or alkali at elevated temperatures it acts as a fluorinating agent and with Cu, As, Sb or Bi in a flow reactor it yields N2F4 (2NF3 - -2Cu N2F4 -I- 2CuF). As perhaps expected (p. 198) NF3 shows little tendency to act as a... 

The most prominent chemical property of HOF is its instability. It decomposes spontaneously (sometimes explosively) to HF and O2 with a half-life of ca. 30 min in a Teflon apparatus at room temperature and lOOmmHg. It reacts rapidly with water to produce HF, H2O2 and O2 in dilute aqueous acid H2O2 is the predominant product whereas in alkaline solution O2 is the principal O-containing product. The kinetics of these processes have been studied and, by use of 0-enriched H2O2, it has... 

The first step of the Combes reaction has been reported to occur by merely mixing an aniline and diketone in an alcoholic solvent, or neat, with slight warming. Dilute aqueous acid (2 M HCl), AcOH, ZnCh as well as CaCl2, or other types of drying agents have been used to promote the first step. 

Another use for this solvent is exemplified by 1,4,5,8-tetraazanaph-thalene, the anhydrous species of which has a predicted i Ka value of — 2.7 (the observed pA in water is + 2.51). The spectrum obtained in anhydrous dichloroacetic acid is almost identical with that of the predominantly anhydrous neutral species determined in water, but quite different from the spectrum measured in dilute aqueous acid. Moreover, addition of water to the anhydrous dichloroacetic acid solution of this base caused the fine structure present in the spectrum of the neutral species to disappear and the band due to the hydrated cation (i.e. the spectrum obtained in water at pH 0.5) to appear. Addition of water to dichloroacetic acid solutions has been used to show that the cations of 3- and 8-nitro-l,6-naphthyridine20 are hydrated in aqueous acid at pH 0.5. 

Treibs and Kolm have reported that, in the complete absence of oxygen and in the dark, pyrrole dissolves in 1.05 equivalents of 0.75 lY aqueous HCl—the clear solution is stable for several hours at room temperature and on basification gives unchanged pyrrole in high yield. (This was difficult to achieve, for the authors state that only two out of four experiments succeeded.) It is very difficult to understand how pyrrole, with an extremely low pKa of the order of zero, can dissolve in 1 equivalent of dilute aqueous acid (1.4 gm pyrrole in 32 ml of aqueous acid). Treibs concludes that protonated pyrrole is stable in solution, and that it is extremely susceptible to autoxida-... 

Epoxides are cleaved by treatment with acid just as other ethers are, but under much milder conditions because of ring strain. As we saw in Section 7.8, dilute aqueous acid at room temperature is sufficient to cause the hydrolysis of epoxides to 1,2-diols, also called vicinal glycols. (The word vicinal means "adjacent/ and a glycol is a diol.) The epoxide cleavage takes place by SK2-like backside attack of a nucleophile on the protonated epoxide, giving a trans- 1,2-dio) as product. 

Anion-catalyzed phase transfer catalysis in a dichloromethane-aqueous sulfuric acid two-phase system was successfully applied to the diazotization of pen-tafluoroaniline by Iwamoto et al. (1983 a, 1984). If this compound is diazotized in dilute aqueous acid, tetrafluoro-l,4-quinone diazide is obtained, indicating that the diazotization proper is followed by a hydroxy-de-fluorination (Brooke et al., 1965). 

If an aromatic o-diamine such as 1,2-diaminobenzene (2.24) is diazotized in dilute aqueous acid, the 2-aminobenzene-l-diazonium ion formed first (2.25) undergoes a rapid intramolecular N-azo coupling reaction to give 1,2,3-benzotri-azole (2.26). Both amino groups of 2.24 can, however, be diazotized in concentrated acid (Scheme 2-18), forming the bis-diazonium ion 2.27. 1,3- and 1,4-diamines must also be bisdiazotized in concentrated acids in order to avoid inter-molecular N- or C-coupling. 

These results indicate that, during thermolyses of fructose-containing saccharides, di-D-fructose dianhydrides are formed readily, but subsequent isomerization is extremely slow—even in the presence of added acid. However, under these conditions, the protonating power of any acid is moot. At the high temperatures used, residual water would be driven off rapidly, unless the reaction vessel is pressurized therefore, reaction occurs in the anhydrous melt. It is presumably protonation of one of the ring oxygen atoms in the dianhydrides that constitutes the first step in isomerization, followed by scission of a C-O bond to yield one of the oxocarbenium ion intermediates postulated in Refs. 31 and 80. Such ions have also been postulated as intermediates in the isomerization of spiroketals to a more-stable product. This latter isomerization can be extremely facile 104 dilute aqueous acid,120 or non-aqueous Lewis-acid conditions121 have been used to effect such transformations. 

The chemistry of Co(III) in dilute aqueous acidic solution is complicated by (/) oxidation of the solvent, it) complex formation with counter-ions, Hi) hydrolysis and iv) apparently extensive dimerisation. These phenomena are discussed further in the section on oxidation of water. 

The THP group can be removed by dilute aqueous acid. The chemistry involved in both the introduction and deprotection stages is the reversible acid-catalyzed formation and hydrolysis of an acetal (see Part A, Section 7.1). 

The tert-butyl protecting group can be removed easily by treating the ether with dilute aqueous acid. 

Beryllium. Be metal is relatively unreactive at room temperature it does not react with water and steam even at red heat and it does not oxidize in air below 600°C. Powdered beryllium burns in air brilliantly on ignition forming BeO and Be3N2. It reacts with the halogens and dissolves easily in dilute aqueous acid solutions. It is passivated by cold concentrate HN03. The Be compounds, especially as dusts or smokes, are extremely toxic (possibly due to the ability of Be11 to displace Mg11 from Mg-activated enzymes). 

Solid lithium aluminium hydride can be solublized in non-polar organic solvents with benzyltriethylammonium chloride. Initially, the catalytic effect of the lithium cation in the reduction of carbonyl compounds was emphasized [l-3], but this has since been refuted. A more recent evaluation of the use of quaternary ammonium aluminium hydrides shows that the purity of the lithium aluminium hydride and the dryness of the solvent are critical, but it has also been noted that trace amounts of water in the solid liquid system are beneficial to the reaction [4]. The quaternary ammonium aluminium hydrides have greater hydrolytic stability than the lithium salt the tetramethylammonium aluminium hydride is hydrolysed slowly in dilute aqueous acid and more lipophilic ammonium salts are more stable [4, 5]. 

---