Category: 616-14-8

Epoxy compounds usually have stronger nucleophilic ability, because the alkyl group on the oxygen atom makes the bond angle smaller, which makes the lone pair of electrons react more dissimilarly with the electron-deficient system. Compound: 1-Iodo-2-methylbutane, is researched, Molecular C5H11I, CAS is 616-14-8, about Aromatase inhibitors. Synthesis and evaluation of mammary tumor inhibiting activity of 3-alkylated 3-(4-aminophenyl)piperidine-2,6-diones.Product Details of 616-14-8.

Piperidinediones I (R = H, Me, Et, Pr, CHMe2, CH2CHMe2, CHMeEt, pentyl, isopentyl, CH2CHMeEt, sec-pentyl, hexyl, heptyl) were prepared by alkylating PhCH2CN, addition reaction of PhCHRCN with CH2:CHCN, hydrolysis and ring closure of NCCRPhCH2CH2CN, nitration, and reduction of the nitro group. In vitro I showed a stronger inhibition of human placental aromatase than aminoglutethimide (II). The most active derivative, I (R = isopentyl), showed a 93-fold stronger inhibition than II. I, except I (R = CHMe2, CH2CHMe2, CHMeEt) exhibited equal or lower inhibition of bovine adrenal desmolase than II. Many I showed a stronger inhibition of the plasma estradiol concentration of pregnant mare serum gonadotropin-primed rats than II. They inhibited the testosterone-stimulated tumor growth of ovariectomized 9,10-dimethyl-1,2-benzanthracene tumor-bearing rats more strongly than II. Being stronger and more selective inhibitors of the estrogen biosynthesis than II, some of the newly developed derivatives of II might be better candidates for the treatment of hormone-dependent human breast cancer.

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Thiomorpholine – Wikipedia,
Thiomorpholine | C4H9NS – PubChem

The reaction of an aromatic heterocycle with a proton is called a protonation. One of articles about this theory is 《Analysis of rotatory dispersions of configurationally related halides》. Authors are Levene, P. A.; Rothen, Alexandre; Marker, R. E..The article about the compound:1-Iodo-2-methylbutanecas:616-14-8,SMILESS:CCC(CI)C).Category: thiomorpholine. Through the article, more information about this compound (cas:616-14-8) is conveyed.

Rotatory dispersion curves of halides of the type HMeRC(CH2)nX (X = Cl, Br, I; R = alkyl group; n = 0, 1, 2 or 3) are analyzed in the visible and the ultraviolet regions. The 3 halogen atoms function similarly with respect to the character of this curve in compounds of identical structure. A periodicity in the sign of some of the partial contributions of the halogen atom occurs with increase in n. The course of the rotatory dispersion when n = 1 is anomalous. An attempt is made to apply results when n > 0 to the sign of rotation for compounds where n = 0. When X = COOH, CHO, CN, CHMe2, etc., no complete analogy exists between this group and the group where X is a halogen. [M]D25 maximum (homogeneous) is given for the 16 compounds where X = Br, n = 1, 2, 3, 4, and R = Et, Pr, Bu, pentyl, and for the compound HMeEtC(CH2)5Br. Absorption spectra are given for λ 2100-3300 for 5 iodides. Rotatory dispersion curves are given for the compounds HMeEtCCH2I, HMe(C6H13)CCH2I, HMeEtCCH2Br and HMeEtCCH2Cl. [M]D25 maximum, nD25, d425 (vacuum) and rotatory dispersions (numerical) are given for several other compounds in this series. Differences between the interpretation of the dispersions of the iodides given by the authors (C. A. 27, 951) and that given by Kuhn (C. A. 29, 7159.1) are due to substantial differences between their exptl. data.

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The preparation of ester heterocycles mostly uses heteroatoms as nucleophilic sites, which are achieved by intramolecular substitution or addition reactions. Compound: 1-Iodo-2-methylbutane( cas:616-14-8 ) is researched.SDS of cas: 616-14-8.Olah, George A.; Welch, John published the article 《Synthetic methods and reactions. XIII. Preparation of alkyl halides from alcohols with alkali halides in polyhydrogen fluoride/pyridine solution》 about this compound( cas:616-14-8 ) in Synthesis. Keywords: halide alkyl cycloalkyl adamantyl; benzyl halide; norbornyl halide. Let’s learn more about this compound (cas:616-14-8).

Thirty-nine RX (R = C4-8 alkyl, cyclopentyl, cyclohexyl, adamantyl, norbornyl, PhCH2; X = F, Cl, Br, I) were prepared by reaction of the corresponding ROH with MX (M = Na, K, NH4) in polyhydrogen fluoridepyridine. Thus, BuCH2OH was kept 1 hr with 70% HF-pyridine containing NaCl to give 89% BuCH2Cl.

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Thiomorpholine – Wikipedia,
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The reaction of an aromatic heterocycle with a proton is called a protonation. One of articles about this theory is 《Action of ionizing radiation on simple organic compounds》. Authors are Napier, K. H.; Green, J. H..The article about the compound:1-Iodo-2-methylbutanecas:616-14-8,SMILESS:CCC(CI)C).Category: thiomorpholine. Through the article, more information about this compound (cas:616-14-8) is conveyed.

I131 in a hydrocarbon was irradiated either with β-rays from a 500 mc. Sr90-Y90 source or with γ-rays from a 5 c. Cs137 source. The distribution of resulting iodinated products were analyzed by gas chromatography. From butane the following percentages of alkyl iodides were obtained: methyl, ethyl, n-propyl, sec-butyl, n-butyl (9, 20, 2, 47, 22, resp.). At some stages in the radiolysis, HI can be as high as 20%.

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Thiomorpholine – Wikipedia,
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The reaction of an aromatic heterocycle with a proton is called a protonation. One of articles about this theory is 《Walden inversion. XIII. The influence of substituting groups on optical rotation in the series of disubstituted acetic acids》. Authors are Levene, P. A.; Mikeska, L. A..The article about the compound:1-Iodo-2-methylbutanecas:616-14-8,SMILESS:CCC(CI)C).Formula: C5H11I. Through the article, more information about this compound (cas:616-14-8) is conveyed.

cf. C. A. 22, 1953. The conclusion that in the aliphatic series the carbinols and the structurally related halides rotate in opposite directions is substantiated by the study of a series of aliphatic substances derived from disubstituted acetic acids or their corresponding carbinols. Primary halides rotate in the opposite direction to the primary alcs. from which they were derived, while in passing from the corresponding thio to the sulfo derivative the change in rotation is in the same direction, though without change of sign. A decided uniformity was found in the effect on optical rotation of various substitutions of the CO2H group or of the alc. group of the corresponding carbinols, depending upon the position of the subsituting group in the polarity series, C = N > CO2Et > CO2H > CONH2 > COCl > CH2SO3H > CH2X > CH2SH > CH2OH > CH2NH2. The order in this series corresponds with the order of the same groups in polarity series determined by other methods. This relationship holds only for aliphatic substances containing only 1 asym. C atom and only 1 polar group. Active primary amyl alc. was halogenated without marked racemization, while in the rest of the series conversion to the halide from the carbinol by SOCl2, PCl5, HBr, HI, etc., as well as from the amine by NOCl2, led to complete racemization. Optically active halides were obtained in the latter case by the action of NOBr. d-Propylmethylacetic acid, [α]D25 5.58° (Et2O), with SOCl2 gave the d-chloride (I), b15 45-8°; [α]D25 4.06°. I, [α]D25 3.94° (Et2O), with concentrated aqueous NH4OH gave the d-amide, m. 78° (from H2O), [α]D25 5.79° (75% alc.). l-Amide, [α]D25-5.79° (75% alc.), distilled with P2O6 gave l-propylmethylacetonitrile (II), b2 30-2°, [α]D25-13.77°. II with Na-alc. gave d-2-propyl-2-methylethylamine (III), b4 28-30°, [α]D25 3.84°, whose HCl salt had [α]D25 1.51° (50% alc.), l-Propylmethylacetic acid, [α]D25-7.08° (Et2O), with HCl gas in alc. gave the Et ester, b4 78-80°, [α]D25-7.91°. d-Acid Et ester, [α]D25 5.67° (Et2O), with Na-alc. gave l-2-propyl-2-methylethanol (IV), b. 147-7.5°, [α]D25-1.23°. IV with PCl5 or NOCl gave dl-2-propyl-2-methylethyl chloride, b. 110-20°. III with NOBr gave l-2-propyl-2-methylethyl bromide, b10 55-65°, [α]D25-0.94° (Et2O). I with KHS gave d-propylmethylthiolacetic acid, b23 71-2°, [α]D25 7.49°. d-Butylmethylacetic acid (V), [α]D25 5.42° (Et2O), with SOCl2 gave the acid chloride (VI), b9 45-8°, [α]D25 5.06°. VI with NH4OH gave the amide (VII), m. 66° (from H2O), [α]D25 3.86° (75% alc.). VII distilled with P2O5 gave the nitrile (VIII), b9 43-50°, [α]D25 9.40°. In another experiment an amide, [α]D25-11.44°, gave a nitrile, [α]D25-27.09° (Et2O). VIII with Na-alc. gave l-2-butyl-2-methylethylamine, b15 49-54°, [α]D25-3.52° (Et2O), whose HCl salt had [α]D25-2.41° (H2O). V with HCl gas and alc. gave an Et ester, b9 58-62°, [α]D25 6.84°, which with Na-alc. gave d-2-butyl-2-methylethanol, b15 71-2°, [α]D25 2.47° (Et2O). d-Heptylmethylacetic acid (IX), b4 145-7°, [α]D25, whose Na salt, [α]D25 0.84° (H2O), was treated with SOCl2, yielding the acid chloride (X), b1 73-4°, [α]D25 4.89°. X with NH4OH gave the amide (XI), m. 78° (from 50% alc.), [α]D25 7.07° (95% alc.), XI with P2O5 gave the nitrile (XII), b7 85-94°, [α]D25 13.61°. XII with Na-alc. gave 1-2-heptyl-2-methylethylamine (XIII), b24, 103-5°, [α]D25-3.38°, whose HBr salt had [°]D25-4.61° (75% alc.), In another experiment an amine, [α]D25 6.05° (Et2O), was obtained from a nitrile, [α]D25 -15.10° (Et2O). An amine, [α]D25 6.05° (Et2O), was obtained from a HBr salt, [α]D25 5.91°. XIII with HBr (fuming) and NaNO2 gave d-2-heptyl-2-methylethyl bromide, b1 80-5°, [α]D25 2.18° (Et2O). l-Heptylmethylacetic acid, [α]D26 -8.72° (Et2O), with HCl gas and alc. gave the Et ester, b17 122-4°, [α]D25 -8.60°, which with Na-alc, gave d-2-heptyl-2-methylethanol, b0.4 80-2°, [α]D25 3.64°. d-Decylmethylacetic acid, b1 153°, [α]D25 8.47°, showed no rotation when neutralized with NaOH. l-Decylmethylacetic acid (XIV), [α]D25 -6.38° (Et2O), with SOCl2 gave the acid chloride (XV), b0.5 118-25°, [α]D25 -3.5°, which was hydrolyzed, yielding an acid, [α]D25 -5.78° (Et2O). XV with NH4OH gave the amide, m. 77° (from 50% alc.), [α]D25 -3.01° (95% alc.), which with P2O5 gave the nitrile, b0.5 108-10°, [α]D25 -10.87° (Et2O), which with Na-alc. gave d-2-decyl-2-methylethylamine (XVI), [α]D25 4.18°, whose HCl salt, m. 105-18°, [α]D25 3.17° (H2O). XIV with HCl gas and alc. gave an Et ester, b1 141°, [α]D25 -6.48°, which with Na-alc. gave l-2-decyl-2-methylethanol, b1.4 105°, [α]D25 2.34°, XVI with NOBr gave l-2-decyl-2-methylethyl bromide, b0.02 87-90°, [α]D25 -0.39. Primary l-amyl alc., [α]D25 -4.73° (Et2O), with HI gave d-2-ethyl-2-methylethyl iodide, b12 47-50°, [α]D25 3.92° (Et2O), which with KHS gave d-2-ethyl-2-methylethanethiol, b. 116-7°, [α]D25 2.99°. In another experiment an iodide, [α]D25 5.27° (Et2O), gave a mercaptan, [α]D25 6.92°, which with Ba(MnO4)2 gave d-2-ethyl-2-methylethanesulfonic acid, whose Ba salt had [α]D25 5.09° (H2O). A table of mol. rotations of the various derivatives, which do not necessarily agree with the exptl. figures, is appended. These values were calculated on the basis of the parent substance of the highest rotation. There is also a table of d.

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Reference:
Thiomorpholine – Wikipedia,
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Application In Synthesis of 1-Iodo-2-methylbutane. The fused heterocycle is formed by combining a benzene ring with a single heterocycle, or two or more single heterocycles. Compound: 1-Iodo-2-methylbutane, is researched, Molecular C5H11I, CAS is 616-14-8, about An extension of the linear relationship between molecular rotation and bond refraction. Author is Poh, Bo-Long.

For the empirical equations [M]D = mΣ RD + I; [M]D is the mol. rotation, ΣRD is the sum of bond refractions, and m and I are constants for a given series of compounds, a different treatment of the term ΣRD extends the usefulness of the equation to all types of substituents, not just monovalent and linear substituents.

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Thiomorpholine – Wikipedia,
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So far, in addition to halogen atoms, other non-metallic atoms can become part of the aromatic heterocycle, and the target ring system is still aromatic.Radulovic, Niko S.; Zivkovic Stosic, Milena Z. researched the compound: 1-Iodo-2-methylbutane( cas:616-14-8 ).Reference of 1-Iodo-2-methylbutane.They published the article 《Long-chain syn-1-phenylalkane-1,3-diyl diacetates, related phenylalkane derivatives, and sec-alcohols, all possessing dominantly iso-branched chain termini, and 2/3-methyl-branched fatty acids from Primula veris L. (Primulaceae) wax》 about this compound( cas:616-14-8 ) in Phytochemistry (Elsevier). Keywords: Primula veris phenylalkane derivative secondary alc branched fatty acid; 1-Phenylalkane-1,3-diones; 2-Methylalkanoic and 3-methylalkanoic acids; 3-Oxo-1-phenylalkan-1-yl acetates; Branched long-chain wax constituents; Primula veris L.; Primulaceae; sec-Alcohols; syn-1-Phenylalkane-1,3-diyl diacetates. We’ll tell you more about this compound (cas:616-14-8).

Herein, the results of the first study of non-flavonoid constituents of aboveground surface-wax washings of Primula veris L. (Primulaceae) are presented. Chromatog. of the washings yielded a minor fraction composed of n-, iso-, and anteiso-series of long-chained syn-1-phenylalkane-1,3-diyl diacetates, 3-oxo-1-phenylalkan-1-yl acetates, 1-phenylalkane-1,3-diones, 1-hydroxy-1-phenylalkan-3-ones, sec-alcs. (2- to 10-alkanols), and n-, iso-, anteiso-, 2-methylalkanoic and 3-methylalkanoic acids; 118 of these constituents represent up to now unreported natural compounds The structural/stereochem. elucidation was accomplished by the synthesis of authentic standards, derivatization reactions, the use of gas chromatog. retention data and detailed 1D and 2D-NMR analyses of the obtained complex chromatog. fraction. Primula veris produces unusually high amounts of branched long-chained metabolites (>60%) except for the fatty acids where the percentage of branched isomers is comparable to the ones with n-chains. Noteworthy is the fact that long-chained α- and β-Me substituted fatty acids were detected herein for the first time in the kingdom Plantae.

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Thiomorpholine – Wikipedia,
Thiomorpholine | C4H9NS – PubChem

Most of the compounds have physiologically active properties, and their biological properties are often attributed to the heteroatoms contained in their molecules, and most of these heteroatoms also appear in cyclic structures. A Journal, Organometallics called Secondary to normal alkyl group rearrangements in octahedral iridium(III) complexes. 1. Monoalkyl derivatives, Author is Bennett, Martin A.; Crisp, Geoffrey T., which mentions a compound: 616-14-8, SMILESS is CCC(CI)C, Molecular C5H11I, Recommanded Product: 1-Iodo-2-methylbutane.

sec-Alkyliridium(III) complexes IrYIR(CO)L2 (R = sec-alkyl; Y = Cl, I; L = PMe3, PMe2Ph), formed by oxidative addition of sec-alkyl iodides to IrY(CO)L2, rearrange cleanly by a first-order process to the n-alkyl isomers on dissolution in CH2Cl2 containing protic solvents. The order of efficacy of these solvents in promoting alkyl group rearrangement is CF3CO2H >> CH3OH >> C2H5OH > CH3CO2H ∼ PrOH > (CH3)2CHOH, while in the more strongly coordinating medium of THF the order is H2O >> CH3OH. These orders correlate with the anion-solvating ability of the solvents and, together with the observed retardation by added iodide ion, suggest that the rate-determining step in the rearrangement is dissociation of iodide ion trans to the sec-alkyl group. Rapid, reversible β-hydride elimination in the resulting cation and stereospecific return of iodide ion trans to the resulting n-alkyl group complete the process. The rearrangement is promoted by increasing bulk, both of the alkyl group, up to a certain limit, and of the tertiary phosphine (PMe2Ph > PMe3). Treatment of IrClI{CH(CH3)2}(CO)(PMe2Ph)2 with AgBF4 in MeCN induces immediate alkyl group rearrangement to give the n-propyliridium(III) salt [IrClPr(CO)(NCMe)(PMe2Ph)2]BF4. Studies of analogous CD2CH3 compounds suggest that they, and presumably other n-alkyliridium(III) complexes, undergo reversible β-hydride elimination more slowly than the sec-alkyl complexes. The D labels in the isobutyl-d2 complex IrClI{CD2CH(CH3)2}(CO)(PMe3)2 scramble over all the alkyl C atoms when the compound is heated in CD2Cl2/CD3OD, indicating that a tert-butyliridium(III) species is accessible. Surprisingly, the complexes IrClI{CH2CH(CH3)CH2CH3}(CO)(PMe3)2 and IrClI{CH2CH2CH(CH3)2}(CO)(PMe3)2 do not interconvert under the same conditions, implying that a tert-pentylirdium(III) species cannot be formed. The results are compared with alkyl group rearrangements that occur in other transition-metal systems, especially those promoted by dissociation of Ph3P in (η-C5H5)FeR(CO)(PPh3).

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Thiomorpholine – Wikipedia,
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The reaction of an aromatic heterocycle with a proton is called a protonation. One of articles about this theory is 《Primary active amyl halides》. Authors are Whitmore, Frank C.; Olewine, J. Harris.The article about the compound:1-Iodo-2-methylbutanecas:616-14-8,SMILESS:CCC(CI)C).HPLC of Formula: 616-14-8. Through the article, more information about this compound (cas:616-14-8) is conveyed.

Primary active AmOH (I) with SOCl2 in C5H5N give 77% of the AmCl, b140 50.5-1°, nD20 1.4125, n420 0.8852, [α]D28.5 1.66°. I and PBr3 at 5-15° give 29% of the AmBr, b140 69.6°, nD20 1.4450, d420 1.2239, [α]D25 3.75°. I and BzCl give 80% of the benzoate, b20 140.2°, nD20 1.4948, d420 0.9913, [α]D28 6.09°; with MeMgI this yields 17.5% of the AmI, b20 47.1°, nD20 1.4969, d42 1.5227, [α]D28 4.84°. Data are given for the constants of I after regeneration from the chloride or bromide through the Grignard reagents; the total racemization in the steps I → AmCl or AmBr → Grignard reagent → I is not over 10%.

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Thiomorpholine – Wikipedia,
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Recommanded Product: 616-14-8. The mechanism of aromatic electrophilic substitution of aromatic heterocycles is consistent with that of benzene. Compound: 1-Iodo-2-methylbutane, is researched, Molecular C5H11I, CAS is 616-14-8, about Gas chromatography of alkyl iodides. II. Influence of structure on retention time and sensitivity to electron capture detector. Author is Castello, Gianrico; D’Amato, Giuseppina.

The retention times and indexes observed for 34 alkyl iodides during electron-capture gas-liquid chromatog. on a 15% tricresyl phosphate/Chromosorb W (DMCS-treated)column are examined as functions of the number of C atoms, the I position, and the number and position of branchings in the alkyl iodide mols. The relative molar response of the electron-capture detector is useful for detector standardizations since it depends only on the standing current.

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Reference:
Thiomorpholine – Wikipedia,
Thiomorpholine | C4H9NS – PubChem