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Nitric acid reagent

Oxidant -, 005 M periodic acid Base -. 5 M ammonium hydroxide Acid -. 75 M nitric acid Reagent Flow Rates Oxidant and Base -, 8 ml/min Acid - ml/min... [Pg.200]

With a micropipette or dropper, add 0.1 ml of nitric acid, reagent grade to the silver composition in the bottle. [Pg.4]

Fuming (yellow) nitric acid, reagent grade... [Pg.105]

Nitric acid, reagent purity, (1. g/ml), tested for freedom from lead with dithizone... [Pg.350]

This mechanism illustrates two HNO3 molecules reacting to generate the nitronium ion as when using the anhydrous nitric acid reagent. Sulfuric acid is often used to enhance the production of N02" as shown here ... [Pg.375]

CAUTION The nitric acid reagent is highly corrosive. Prevent contact with eyes, skin, and clothing. A spill is neutralized using solid sodium carbonate or bicarbonate. [Pg.377]

This reaction consists of the condensation of two molecular equivalents of a 1,3 diketone (or a J3-keto-ester) with one equivalent of an aldehyde and one of ammonia. Thus the interaction of ethyl acetoacetate and acetaldehyde and ammonia affords the 1,4-dihy dro-pyridine derivative (1), which when boiled with dilute nitric acid readily undergoes dehydrogenation and aromatisation" to gb e the diethyl ester of collidine (or 2,4,6-trimethyl-pyridine-3,5 dicarboxylic acid (II)). For the initial condensation the solid aldehyde-ammonia can conveniently be used in place of the separate reagents. [Pg.295]

It is preferable to use Tollen s ammoniacal silver nitrate reagent, which is prepared as follows Dissolve 3 g. of silver nitrate in 30 ml. of water (solution A) and 3 g. of sodium hydroxide in 30 ml. of water (solution B). When the reagent is requir, mix equal volumes (say, 1 ml.) of solutions A and JB in a clean test-tube, and add dilute ammonia solution drop by drop until the silver oxide is just dissolved. Great care must be taken in the preparation and use of this reagent, which must not be heated. Only a small volume should be prepared just before use, any residue washed down the sink with a large quantity of water, and the test-tubes rinsed with dilute nitric acid. [Pg.330]

Phosphorus. The presence of phosphorus may be indicated by a smell of phosphine during the sodium fusion. Treat 1 ml. of the fusion solution with 3 ml. of eoneentrated nitric acid and boil for one minute. Cool and add an equal volume of ammonium molybdate reagent. Warm the mixture to 40-50°, and allow to stand. If phosphorus is present, a yellow erystalline precipitate of ammonium phosphomolybdate wUl separate. [Pg.1043]

Place 2 ml. of the periodic acid reagent in a small test tube, add one drop (no more—otherwise the silver iodate, if formed, will fail to precipitate) of concentrated nitric acid, and shake well. Add one drop or a small crystal of the compound to be tested, shake the mixture for 15-20 seconds, and then add 1-2 drops of 3 per cent, silver nitrate solution. The instantaneous formation of a white precipitate of silver iodate is a positive test. Failure to form a precipitate, or the appearance of a brown precipitate which redissolves on shaking, constitutes a negative test. [Pg.1070]

Accepting, for the moment without further evidence, that the nitro-nium ion formed by heterolysis of nitric acid is the active reagent in the solutions imder discussion, it remains to consider briefly why nitration in such solutions depends on the concentrations of nitric acid to such high powers (fig. 3.1), and why different solvents behave so differently (table 3.2). [Pg.38]

Nitration using this reagent was first investigated, by Francis. He showed that benzene and some of its homologues bromobenzene, benzonitrile, benzoyl chloride, benzaldehyde and some related compounds, and phenol were mono-nitrated in solutions of benzoyl nitrate in carbon tetrachloride anilines would not react cleanly and a series of naphthols yielded dinitro compounds. Further work on the orientation of substitution associated this reagent with higher proportions of o-substitution than that brought about by nitric acid this point is discussed below ( 5.3.4). [Pg.77]

Because of the chemical similarity between benzoyl nitrate and the acetyl nitrate which is formed in solutions of nitric acid in acetic anhydride, it is tempting to draw analogies between the mechanisms of nitration in such solutions and in solutions of benzoyl nitrate in carbon tetrachloride. Similarities do exist, such as the production by these reagents of higher proportions of o-substituted products from some substrates than are produced by nitronium ions, as already mentioned and further discussed below. Further, in solutions in carbon tetrachloride of acetyl nitrate or benzoyl nitrate, the addition of acetic anhydride and benzoic anhydride respectively reduces the rate of reaction, implying that dinitrogen pentoxide may also be involved in nitration in acetic anhydride. However, for solutions in which acetic anhydride is also the solvent, the analogy should be drawn with caution, for in many ways the conditions are not comparable. Thus, carbon tetrachloride is a non-polar solvent, in which, as has been shown above,... [Pg.78]

Characteristics of the system as nitrating reagents Wibaut, who introduced the competitive method for determining reactivities (his experiments with toluene, benzene and chlorobenzene were performed under heterogeneous conditions and were not successful), pointed out that solutions of nitric acid in acetic anhydride are useful in making comparisons of reactivities because aromatic compounds are soluble in them. ... [Pg.82]

Certain features of the addition of acetyl nitrate to olefins in acetic anhydride may be relevant to the mechanism of aromatic nitration by this reagent. The rapid reaction results in predominantly cw-addition to yield a mixture of the y -nitro-acetate and y5-nitro-nitrate. The reaction was facilitated by the addition of sulphuric acid, in which case the 3rield of / -nitro-nitrate was reduced, whereas the addition of sodium nitrate favoured the formation of this compound over that of the acetate. As already mentioned ( 5.3. i), a solution of nitric acid (c. i 6 mol 1 ) in acetic anhydride prepared at — 10 °C would yield 95-97 % of the nitric acid by precipitation with urea, whereas from a similar solution prepared at 20-25 °C and cooled rapidly to —10 °C only 30% of the acid could be recovered. The difference between these values was attributed to the formation of acetyl nitrate. A solution prepared at room... [Pg.83]

Later experiments do not allow a clear choice between these alternatives. The high proportion of o-isomer formed when nitration is effected with acetyl nitrate in acetic anhydride is confirmed by the results of expts. 10-14 (table 5.5). The use of fuming, rather than pure nitric acid, in the preparation of the reagent, which may lead to nitration... [Pg.94]

Expts. I, 3, 5, 7, 9, II. Descriptions of these experiments are not always explicit, but the reagent was prepared from fuming nitric acid (d 1-5, 0 009 mol) and acetic anhydride (o-oi mol) a small quantity of urea was added before nitration. [Pg.100]

Sonnenschein s reagent (alkaloid detection) a nitric acid solution of ammonium molybdate is treated with phosphoric acid. The precipitate so produced is washed and boiled with aqua regia... [Pg.1196]

See other pages where Nitric acid reagent is mentioned: [Pg.358]    [Pg.363]    [Pg.740]    [Pg.134]    [Pg.637]    [Pg.144]    [Pg.117]    [Pg.161]    [Pg.279]    [Pg.358]    [Pg.363]    [Pg.740]    [Pg.134]    [Pg.637]    [Pg.144]    [Pg.117]    [Pg.161]    [Pg.279]    [Pg.239]    [Pg.472]    [Pg.1061]    [Pg.1]    [Pg.12]    [Pg.63]    [Pg.76]    [Pg.99]    [Pg.100]    [Pg.100]    [Pg.101]    [Pg.200]    [Pg.201]    [Pg.214]    [Pg.224]    [Pg.470]    [Pg.515]    [Pg.435]   
See also in sourсe #XX -- [ Pg.24 ]



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Acidic reagents

Hydrochloride-nitric acid reagent

Nitric acid reagent, hydroxylamine

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