Mechanism of Amination of Halobenzenes 601 1.3855, was used as solvent. Sodium iodide, reagent grade, was dried overnight at 105°before use. The nitrate esters, prepared by nitration of the bromohydrins, were kindly furnished by Dr. Boris Franzus.Reaction Rate Studies.-The reactions were run and the rates calculated substantially as described by Young.20 No salt corrections20 were made, nor did any appear necessary.In runs below 90°, the solutions were prepared at the reaction temperature in volumetric flasks and run in ground-glass stoppered volumetric flasks. At higher temperatures sealed tubes were used; as well as in some runs at 88°. The principal advantage of the use of «-propyl alcohol over methyl alcohol resides in its lower volatility.The order of the reactions may be noted from tire constancy of the rate constants with variation of reagent concentration (Table I).Reaction of Iodine with Solvents.-An acetone solution, 0.005 M in iodine and 0.21 M in sodium iodide, lost about 50% of its iodine in 70 hours at 62.4°. A solution (in 99% aq. methanol), 0.025 M in iodine and 0.265 M in sodium iodide lost less than 2% of its iodine in 200 hours at 62.4°. A solution (in «-propyl alcohol), 0.065 M in iodine and 0.26 M in sodium iodide, lost less than 1% of its iodine in 200 hours at 62.4°.
Fig. 3. This is a schematic representation based O I I [ivcrage R, values appearing iii 7 differerit rlironiatographic runs. I t is evident that the various antimycin A components were obtained in cliroiiiatographically homogeneous form. Further, from these results blastmycin appeared to consist mainly of antimycin A3 with minor contamination by the A4 component.Paper chromatogranis of the various antimycin complex preparations are also given in Fig. 3 . I t is apparent that the four antimycin preparations all contained at least the ill, An and A 3 components, although in somewhat varying proportions. Yirosin was similar in Composition but also contained a significant proportion of antimycin Aq. The other preparations may also have contained small amounts of A 4 as it certainly was present in the Harada sample but yet was not detected by the chromatogram.Infrared spectra of various preparations as shown in Fig 4 reveal extremely close similarity both of the individual components A1 and A3 to each other and to blastmycin and virosin. Antimycin A2 and the antimycin complex also gave essentially the same infrared spectrum. The differences are too slight to be of much aid in establishing differences in the chemical structure. Evi-dently, the components differ from each othcr only in the alkyl side chains of the neutral portioii of the molecule.3 Such a relationship is also suggested by the molecular formulas of AI, AB and A3 which differ among themselves only by the ey uivalen t of one to three methylene groups, The ultraviolet spectra of the individual components also were essentially identical.The infrared tracing of blastmycin offers further evidence of its very close similarity with antimycin; furthermore, its melting point was close to that of antimycin AB and the mixed melting point showed no depression. These data taken together with the above paper chromatographic results establish quite conclusively that the major coniponent of blastmycin is identical with antimycin AB and indicate that the minor component very probably is antimycin Ad.All three of the isolated antimycin A components showed neutral equivalents appreciably lower than theory for their most probable molecular formulas. This discrepancy may be attributable to partial cleavage of the alkali-sensitive bond of the antimycin A structure.13 The investigation of these and other aspects of the chemistry of antimycin A is being continued.Investigation of the extent of isotope-position rearrangement in carbonium ion-type reactions of I4C-labeled cyclopropylcarbinyl derivatives has revealed that the three methylene groups of the starting material achieve a striking degree of equivalence between reactants and products. These results, taken in conjunction with the abnormally large solvolytic reactivities oE cyclopropylcarbinyl and cyclobutyl halides and sulfonate esters, can best be accounted for by assuming rapid but not instantaneous equilibration of three isxneric rion-classical unsymmetrical "bicyclobutonium" ion intermediates.Considerable interest att...
The purpose of this review is to illustrate a variety of tracer applications by specific examples in the areas of structural determinations, reaction mechanisms, reactivity studies, and kinetic isotope effects.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
customersupport@researchsolutions.com
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.