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´ó¼Ò×îºÃôȫ²¿·Ò룬Èç¹ûʵÔÚ²»ÐУ¬¿ÉÒÔÉÙ·Ò뼸¶Î¡£½ð±ÒÕÕ¸ø²»Îó¡£ The failure of a similar addition reaction of hydrogen sulfide to the double bond of ¢òin benzene may be explained by the very low solubility of ¢òin benzene (0.1% in refluxing benzene). ¢ò would precipitate as fast as it was formed in benzene and thus could not react further with hydrogen sulfide; however, since ¢ò is soluble to a limited extent in benzene, a small amount of ¢ó would be expected to be found if the reaction was carried out with a large excess of benzene over a long period. Small amounts of ¢ó as well as ¢ö were identified in the infrared spectrum of the product obtained from a reaction carried out under these conditions. Mechanisms involving the formation of thioacetic acid or ethanethiol mere eliminated since no trace of these materials could be found in the reaction mixtures from ¢ñor ¢òand hydrogen sulfide in the presence of ethyl alcohol. Simple hydrolysis with water was also ruled out since ¢ò could be recrystallized without hydrolysis from hot water; however, there is some question concerning the stability of ¢òin a mixture of ethyl alcohol and water. In one experiment, ¢òmas decomposed and no identifiable products were obtained after ¢ò was stirred overnight in a mixture of alcohol and mater with a catalytic amount of triethylamine. A similar experiment showed that ¢òwas stable in ethyl alcohol alone. Another mechanism, involving first the alcoholysis of¢ñor ¢ò in the presence of hydrogen sulfide as catalyst, was considered. It was demonstrated that ¢õ and trace quantities of ethyl acetate were obtained from triethyl orthoacetate and hydrogen sulfide; thus all the observed by-products from the reaction of hydrogen sulfide and ethyl alcohol with¢ñor¢òcould be accounted for. However, ¢ñreacted with hydrogen sulfide in dimethylformamide solution to form dithiomaloiiamide (¢ö) ethyl thionoacetate (¢õ), and ethyl acetate. hlcohol, therefore, is not a necessary reactant in the cleavage, making the alcoholysis step unnecessary in explaining the mechanism for the formation of ¢ó from ¢ñin ethyl alcohol. Other reactions of ¢òwere studied and several compounds of this type were prepared and characterized. It was found that the alkoxy group was easily removed by mild hydrolysis. When ¢ò was dissolved at room temperature with 4 to 5% sodium hydroxide solution and then cold, dilute (10%) hydrochloric acid solution was added, 2-cyano-3- hydroxythiocrotonamide (¢ù) was formed. This same compound was also prepared by simply heating ¢òwith 10% hydrochloric acid solution at steam bath temperatures for approximately ten minutes. These reactions were generally applicable to 2-cyano-3-alkoxy-2-alkenthioamides. An attempt to prepare the mercapto derivative by replacing the 4% sodium hydroxide solution with dilute sodium hydrosulfide gave a product which had ai1 infrared spectrum consistent with the proposed structure ¢û. The replacement of the ethoxy group probably results from a 1,4-attack of the sodium hydroxide or hydrosulfide on the conjugated system involving the nitrile or thioamide group and the carboncarbon double bond followed by loss of sodium alkoxide. The mercapto derivative ¢û was less stable than the hydroxy derivative ¢ù and slowly decomposed during the analysis and on standing. The products of the decomposition were not identified. The hydroxy and mercapto derivatives (¢ù,¢ú, and ¢û) were acidic in aqueous solution. The hydroxy derivative ¢ù was titrated nith 0.5 N base and a neutralization equivalent of 146 (theor. 142) was obtained. It wab stable to further attack with hydrogen sulfide in ethyl alcohol even though it was quite soluble in the alcohol; therefore, the hydroxy derivative¢ù was ruled out as a possible intermediate in the formation of ¢ó from the reaction of hydrogen sulfide and ethyl alcohol with ¢ñor ¢ò. Attempts to form the corresponding hydroxy derivative from the reaction of ¢ñwith dilute base followed by addition of acid failed to yield the expected product. NMR studies did not verify the presence of the hydroxy proton in ¢ù; however, infrared studies of deuterated ¢ù confirmed the presence of the hydroxy group by an observed shift on deuteration from the normal absorption for v(OH) at 3.13¦Ì to 4.22 ¦Í for ¦Í(OD). The hydroxy bending vibration ¦Ä(OH) was observed at 7.0 ¦Ì. The presence of an isomeric ketonic structure was ruled out since there was no carbonyl absorption observed in the infrared spectrum. Also, ¢ù failed to form a 2,4-dinitrophenylhydrazine derivative in either alcoholic or aqueous solution. The presence of an isomeric epoxy structure was ruled out since an oxirane analysis of ¢ù was negative. The amide nitrogen of ¢ùwas also deuterated and the observed shifts to the longer wavelengths as a result of deuteration were from 2.97 ¦Ì [¦Ía- (NH)] and 3.03 ¦Ì [¦Ís(ND)] to 3.97 ¦Ì[¦Ía (ND)] and 4.10 ¦Ì[¦Ís(ND)]. There was also spectral evidence for considerable contribution from tautomeric structures ¢ü and ¢ú¢ó. The enol v(SH) absorption band at 3.8 ¦Ìvas shifted to 5.5 ¦Ì[¦Í(SD)] in the deuterated compound. A solid S-methyl derivative (methyl 2-cyano-3- hydroxythiocrotonimidate) of the enol structure of ¢ô was obtained by treating ¢òwith methyl iodide in 4% sodium hydroxide solution. The ethyl group of ¢ò was lost during this alkylation reaction. Upon mild oxidation of ¢ùwith iodine in potassium iodide, a disulfide, which was characterized as 3,3'-dithiobis [2- (l-hydroxyethylidene)-3-imino propionitrile](¢ú¢ô), was formed. It was surprising to find that if ¢ò was mildly oxidized in the same manner with iodine in potassium iodide the ethyl group was lost and the same product was formed. The absence of hydrogen iodide salt formation was demonstrated by a negative halogen analysis. The stability of ¢ú¢ô was somewhat surprising since simpler disulfides of this type are usually unstable; for example, 1,l'-dithiodiformamidine has not been obtained except in the form of a salt with hydrogen halides.[7] Recently 1,1 '-dithiobis-[N-phenylformamidineldihydrobromide dihydrate R as prepared from phenylthiourea.[8] It is also known that thioacetamide reacts with iodine in water to give oxidation products such as ammonium iodide, hydrogen iodide, and sulfur and that no disulfide is formed.[9] The additional resonance possibilities provided by the unsaturated, negatively substituted disulfide ¢ú¢ô probably accounts for its stability as compared with the marked unstable nature of the simpler members of this class of compounds. Reaction of¢òwith dimethylamine was found to yield 2-cyano-3-dimethy- lamino- thiocrotonamide, in which the alkoxy group of ¢ò is replaced with the dialkylamino group. The ethoxy group mas also replaced by anhydrous ammonia to form S-amino-2- cyanothiocrotonamide. These alkoxy replacement reactions are consistent with reported reactions of diethyl ethoxymethylenemalonate to form the aminomethylenemalonic ester.[10] Other derivatives of substituted methylenemalononitriles prepared were 2-cyano-3-phenyl- thioacrylamide, 2-cyano-3-(2-thienyl)thioacrylamide, and 2-cyano-3-(2-furyl) thioacrylamide. Acknowledgment.¡ªThe author is indebted to Dr. H. W. Coover and Dr. N. H. Shearer for helpful discussions and suggestions throughout this study. Thanks are also due Mr. M. V. Otis for infrared analyses, Dr. V. W. Goodlett for NMR studies, Mr. C. L.Harrison for gas chromatographic analyses, and Mr. J. S. Lewis for mass spectrometric analyses. [ Last edited by Ó¦Óû¯Ñ§ on 2009-5-17 at 23:51 ] |
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acknowledgmentÎÒ·ÒëһϠ×÷ÕߺܸÐлH. W. Coover²©Ê¿ºÍN. H. Shearer²©Ê¿£¬ÒòΪËûÃǹᴩ±¾Ñо¿È«³ÌÓÐÒæµÄÌÖÂۺͽ¨Ò顣ͬʱ¸ÐлM. V. OtisÏÈÉúµÄºìÍâ·ÖÎö£¬V. W. Goodlett²©Ê¿µÄºË´Å·ÖÎö£¬C. L. HarrisonÏÈÉúµÄÆøÏàÉ«Æ×·ÖÎö£¬ÒÔ¼°J. S. LewisÏÈÉúµÄÖÊÆ×·ÖÎö¡£ ½ð±Ò¾Í²»ÓÃÁË¡£ ÎÒÓÐʱ¼ä¾Í´ÓºóÍùÇ°·°É¡£ |
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Reaction of¢òwith dimethylamine was found to yield 2-cyano-3-dimethy- lamino- thiocrotonamide, in which the alkoxy group of ¢ò is replaced with the dialkylamino group. The ethoxy group mas also replaced by anhydrous ammonia to form S-amino-2- cyanothiocrotonamide. These alkoxy replacement reactions are consistent with reported reactions of diethyl ethoxymethylenemalonate to form the aminomethylenemalonic ester.[10] IIÓë¶þÒÒ°··´Ó¦Éú³É2-cyano-3-dimethy- lamino- thiocrotonamide£¬ÆäÖÐIIµÄÍéÑõ»ù±»¶þÍé»ù°±»ùÈ¡´ú¡£ÒÒÑõ»ùͬÑùÒ²±»ÎÞË®°±È¡´úÉú³ÉS-amino-2- cyanothiocrotonamide¡£ÕâЩÍéÑõ»ùÖû»·´Ó¦ÓëÒѱ¨µÀµÄdiethyl ethoxymethylenemalonateÉú³Éaminomethylenemalonic esterµÄ·´Ó¦ÏàÒ»Ö¡£ Other derivatives of substituted methylenemalononitriles prepared were 2-cyano-3-phenyl- thioacrylamide, 2-cyano-3-(2-thienyl)thioacrylamide, and 2-cyano-3-(2-furyl) thioacrylamide. ÆäËüÖƱ¸µ½µÄ±»È¡´úµÄmethylenemalononitrilesÑÜÉúÎïÓÐ 2-cyano-3-phenyl- thioacrylamide, 2-cyano-3-(2-thienyl)thioacrylamide, ºÍ2-cyano-3-(2-furyl) thioacrylamide¡£ [ Last edited by nsdcsj on 2009-5-18 at 12:31 ] |
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The stability of ¢ú¢ô was somewhat surprising since simpler disulfides of this type are usually unstable; for example, 1,l'-dithiodiformamidine has not been obtained except in the form of a salt with hydrogen halides.[7] Recently 1,1 '-dithiobis-[N-phenylformamidineldihydrobromide dihydrate R as prepared from phenylthiourea.[8] It is also known that thioacetamide reacts with iodine in water to give oxidation products such as ammonium iodide, hydrogen iodide, and sulfur and that no disulfide is formed.[9] The additional resonance possibilities provided by the unsaturated, negatively substituted disulfide ¢ú¢ô probably accounts for its stability as compared with the marked unstable nature of the simpler members of this class of compounds. ¢ú¢ôµÄÎȶ¨ÐÔºÜÈÃÈ˾ªÆæÒòΪ¼òµ¥µÄ´ËÀà¶þÁò»¯Îïͨ³£²»Îȶ¨¡£ÀýÈ磬³ýÁËÆäHClÑÎ[7]ÐÎʽÒÔÍ⣬²¢Ã»Óеõ½1,l'-dithiodiformamidine¡£×î½ü£¬´Ó±½ÁòëåÖƱ¸ÁË1,1 '-dithiobis-[N-phenylformamidineldihydrobromide dihydrate R[8].ÁíÍ⻹֪µÀÁò´úÒÒõ£°·ÓëI2/Ë®·´Ó¦Éú³ÉÑõ»¯²úÎïÀýÈçµâ»¯ï§£¬µâ»¯ÇâºÍÁò£¬Ã»ÓжþÁò»¯ÎïÐγɡ£[9]¸úͬϵµÄ¼òµ¥»¯ºÏÎïÏÔÖø²»Îȶ¨µÄÐÔÖÊÏà±È£¬²»±¥ºÍµÄ£¬µç¸ºÐÔµÄÈ¡´úµÄ¶þÁò»¯ÎïX IV¹¹³ÉµÄ¼Ó³É¹²ÕñÌåµÄÓ¦µ±È¡¾öÓÚ¸üºÃµÄÎȶ¨ÐÔ¡£ |
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9Â¥2009-05-18 14:53:02
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Òø³æ (СÓÐÃûÆø)
- Ó¦Öú: 2 (Ó׶ùÔ°)
- ½ð±Ò: 41.1
- É¢½ð: 308
- ºì»¨: 1
- Ìû×Ó: 228
- ÔÚÏß: 17.2Сʱ
- ³æºÅ: 647949
- ×¢²á: 2008-11-06
- ÐÔ±ð: MM
- רҵ: É«Æ×·ÖÎö
zap65535(½ð±Ò+0,VIP+0):¡£ 12-23 19:12
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»¹ÓÐÕ⼸¶Îû·ÒëŶ£¬¼ÓÓÍ°¡£¬Ð»Ð»ÁË¡£ An attempt to prepare the mercapto derivative by replacing the 4% sodium hydroxide solution with dilute sodium hydrosulfide gave a product which had ai1 infrared spectrum consistent with the proposed structure ¢û. The replacement of the ethoxy group probably results from a 1,4-attack of the sodium hydroxide or hydrosulfide on the conjugated system involving the nitrile or thioamide group and the carboncarbon double bond followed by loss of sodium alkoxide. The mercapto derivative ¢û was less stable than the hydroxy derivative ¢ù and slowly decomposed during the analysis and on standing. The products of the decomposition were not identified. The hydroxy and mercapto derivatives (¢ù,¢ú, and ¢û) were acidic in aqueous solution. The hydroxy derivative ¢ù was titrated nith 0.5 N base and a neutralization equivalent of 146 (theor. 142) was obtained. It wab stable to further attack with hydrogen sulfide in ethyl alcohol even though it was quite soluble in the alcohol; therefore, the hydroxy derivative¢ù was ruled out as a possible intermediate in the formation of ¢ó from the reaction of hydrogen sulfide and ethyl alcohol with ¢ñor ¢ò. Attempts to form the corresponding hydroxy derivative from the reaction of ¢ñwith dilute base followed by addition of acid failed to yield the expected product. NMR studies did not verify the presence of the hydroxy proton in ¢ù; however, infrared studies of deuterated ¢ù confirmed the presence of the hydroxy group by an observed shift on deuteration from the normal absorption for v(OH) at 3.13¦Ì to 4.22 ¦Í for ¦Í(OD). The hydroxy bending vibration ¦Ä(OH) was observed at 7.0 ¦Ì. The presence of an isomeric ketonic structure was ruled out since there was no carbonyl absorption observed in the infrared spectrum. Also, ¢ù failed to form a 2,4-dinitrophenylhydrazine derivative in either alcoholic or aqueous solution. The presence of an isomeric epoxy structure was ruled out since an oxirane analysis of ¢ù was negative. The amide nitrogen of ¢ùwas also deuterated and the observed shifts to the longer wavelengths as a result of deuteration were from 2.97 ¦Ì [¦Ía- (NH)] and 3.03 ¦Ì [¦Ís(ND)] to 3.97 ¦Ì[¦Ía (ND)] and 4.10 ¦Ì[¦Ís(ND)]. There was also spectral evidence for considerable contribution from tautomeric structures ¢ü and ¢ú¢ó. The enol v(SH) absorption band at 3.8 ¦Ìvas shifted to 5.5 ¦Ì[¦Í(SD)] in the deuterated compound. A solid S-methyl derivative (methyl 2-cyano-3- hydroxythiocrotonimidate) of the enol structure of ¢ô was obtained by treating ¢òwith methyl iodide in 4% sodium hydroxide solution. The ethyl group of ¢ò was lost during this alkylation reaction. Upon mild oxidation of ¢ùwith iodine in potassium iodide, a disulfide, which was characterized as 3,3'-dithiobis [2- (l-hydroxyethylidene)-3-imino propionitrile](¢ú¢ô), was formed. It was surprising to find that if ¢ò was mildly oxidized in the same manner with iodine in potassium iodide the ethyl group was lost and the same product was formed. The absence of hydrogen iodide salt formation was demonstrated by a negative halogen analysis. |
10Â¥2009-05-18 18:37:48
