Butyl dicarboxylic acid

Fig. 5.16. (a) Depression of various reagents on wolframate flotation 1—citric acid, 2— tartaric acid, 3—oxalic acid, 4—EDTA, 5—succinic acid, 6—lactic acid, (b) Depression of various reagents on flotation of Fe " " activated quartz 1—tartaric acid, 2—citric acid, 3— EDTA, 4—oxalic acid, 5—succinic acid, 6— butyl dicarboxylic acid, 7—lactic acid, 8—acetic acid. 

Regioselectivity of C—C double bond formation can also be achieved in the reductiv or oxidative elimination of two functional groups from adjacent carbon atoms. Well estab llshed methods in synthesis include the reductive cleavage of cyclic thionocarbonates derivec from glycols (E.J. Corey, 1968 C W. Hartmann, 1972), the reduction of epoxides with Zn/Nal or of dihalides with metals, organometallic compounds, or Nal/acetone (seep.lS6f), and the oxidative decarboxylation of 1,2-dicarboxylic acids (C.A. Grob, 1958 S. Masamune, 1966 R.A. Sheldon, 1972) or their r-butyl peresters (E.N. Cain, 1969). 

The FCC is to food-additive chemicals what the USP—NF is to dmgs. In fact, many chemicals that are used in dmgs also are food additives (qv) and thus may have monographs in both the USP—NF and in the FCC. Examples of food-additive chemicals are ascorbic acid [50-81-7] (see Vitamins), butylated hydroxytoluene [128-37-0] (BHT) (see Antioxidants), calcium chloride [10043-52-4] (see Calcium compounds), ethyl vanillin [121-32-4] (see Vanillin), ferrous fumarate [7705-12-6] and ferrous sulfate [7720-78-7] (see Iron compounds), niacin [59-67-6] sodium chloride [7647-14-5] sodium hydroxide [1310-73-2] (see lkaliand cm ORiNE products), sodium phosphate dibasic [7558-79-4] (see Phosphoric acids and phosphates), spearmint oil [8008-79-5] (see Oils, essential), tartaric acid [133-37-9] (see Hydroxy dicarboxylic acids), tragacanth [9000-65-1] (see Gums), and vitamin A [11103-57-4]. 

Plasticizers can be classified according to their chemical nature. The most important classes of plasticizers used in rubber adhesives are phthalates, polymeric plasticizers, and esters. The group phthalate plasticizers constitutes the biggest and most widely used plasticizers. The linear alkyl phthalates impart improved low-temperature performance and have reduced volatility. Most of the polymeric plasticizers are saturated polyesters obtained by reaction of a diol with a dicarboxylic acid. The most common diols are propanediol, 1,3- and 1,4-butanediol, and 1,6-hexanediol. Adipic, phthalic and sebacic acids are common carboxylic acids used in the manufacture of polymeric plasticizers. Some poly-hydroxybutyrates are used in rubber adhesive formulations. Both the molecular weight and the chemical nature determine the performance of the polymeric plasticizers. Increasing the molecular weight reduces the volatility of the plasticizer but reduces the plasticizing efficiency and low-temperature properties. Typical esters used as plasticizers are n-butyl acetate and cellulose acetobutyrate. 

The nature of the base, CmHijN, varies. When produced from pure Mupinine, m.p. 68-9°, it furnishes on oxidation only 3-methylpyridine-2-carboxylic acid (XV) and pyridine-2 3-dicarboxylic acid. If, however, lupinine, m.p. 63-3°, is used, the resulting pyridine base on oxidation furnishes in addition 2-n-butylpyridine-6-carboxylic acid (XVI) and 6-methylpyridine-2-carboxylic acid (XVII). The conclusion is drawn that lupinine, m.p. 63-3°, is a mixture of 1-lupinine (XI) with aZlolupinine (XII), each of these components furnishing its own lupinane (XIII and XIV), and that these two lupinanes contribute to the final degradation product, the tertiary pyridine base, CioHuN, the two isomerides 2-w-Ijutyl-3-inethylpyridine (XVIII) and 2-w-butyl-6-raethylpyridine (XIX) respectively. These interrelationships are shown by the following scheme —... 

The cyclization of 1,19-dideoxybilene-i-dicarboxylic acid esters has been widely used for the synthesis of porphyrins. In this case, the use of tert-butyl esters which can be hydrolyzed with trifluoroacetic acid prior to the cyclization step is necessary. The cyclization step also requires trifluoroacetic acid and orthoformates. However, attempts to prepare porphyrins with /f-acceptor substituents can give rise to problems with side products and yields. 

Benzene-o-dicarboxylic acid, di-rrbutyl ester, see Di-n-butyl phthalate... 

Dinitrocubane (28) has been synthesized by Eaton and co-workers via two routes both starting from cubane-l,4-dicarboxylic acid (25). The first of these routes uses diphenylphos-phoryl azide in the presence of a base and tert-butyl alcohol to effect direct conversion of the carboxylic acid (25) to the tert-butylcarbamate (26). Hydrolysis of (26) with mineral acid, followed by direct oxidation of the diamine (27) with m-CPBA, yields 1,4-diiutrocubane (28). Initial attempts to convert cubane-l,4-dicarboxylic acid (25) to 1,4-diaminocubane (27) via a Curtins rearrangement of the corresponding diacylazide (29) were abandoned due to the extremely explosive nature of the latter. However, subsequent experiments showed that treatment of the acid chloride of cubane-l,4-dicarboxylic acid with trimethylsilyl azide allows the formation of the diisocyanate (30) without prior isolation of the dangerous diacylazide (29) from solution. Oxidation of the diisocyanate (30) to 1,4-dinitrocubane (28) was achieved with dimethyldioxirane in wet acetone. Dimethyldioxirane is also reported to oxidize both the diamine (27) and its hydrochloride salt to 1,4-dinitrocubane (28) in excellent yield. ... 

The reaction of a pyridazine, 5 dicarboxylic acid derivative with hydrazine remains a favored approach for the preparation of pyridazino[4,5-4 pyridazines <2000TL2863, 2002JCCS217>, and di- /t-butyl hydrazodicarboxylate has been used as a hydrazine substitute in the presence of perhydro derivatives, as illustrated in Equation (6) <1993JPC13408>. 

Light-induced reaction of bicyclo[2.1.1]hexane-l,4-dicarboxylic acid with rcr/-butyl hypoiodite gave l,4-diiodobicyclo[2.1.1]hexane (4) in 60% yield.23... 

Condensation monomers having the benzimidazolin-2-one ring system have found utility as modifiers in polyester synthesis. In particular, halogenated diols (73) and dicarboxylic acids (74) may be incorporated (78MI11100) into polyethylene terephthalate) or poly(butyl-ene terephthalate) at fairly low levels to impart flame retardancy. This can be accomplished without adverse effects upon other polymer properties. 

Preparation and Solubility of Polyesters. A number of polyesters were prepared from several diols and dicarboxylic acid esters to determine the effect of structure on the solubility in typical solvents used in lacquers. The data in Table I show that solubility in the solvents decreased in the following order toluene > methyl ethyl ketone > butyl acetate. Polymers that were soluble in all three solvents are examples 9-14. 

Reference has already been made to the partial decarboxylation of pyrazinedicarboxylic acids.219 Both pyrazine itself,232 and 2,3-dimethylpyrazine,207 are conveniently prepared by decarboxylation of the appropriate dicarboxylic acids. The decarboxylation of pyrazine-2,3-dicarboxylic acid is carried out by heating in din-butyl phthalate and gives pyrazine in 90% yield. The 2,3-dicarboxylic acid forms an anhydride in the normal way. Pyrolysis of the anhydride at 800°/0.05 mm through a silica tube gives in 80% yield an approximately 1 1 mixture of maleonitrile and fumaronitrile (Scheme 19). 2,3-Dehydropyrazine is thought to be an intermediate in this reaction and a strong peak of m/e 78, corresponding to the dehydropyrazine ion, is observed in the mass spectrum of the anhydride.233... 

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