Tag: M.W:100-200

In organic chemistry, atoms other than carbon and hydrogen are generally referred to as heteroatoms. The most common heteroatoms are nitrogen, oxygen and sulfur. Now I present to you an article called SPME-GC-MS analysis of volatile components in fruits of the frozen Ficus tikoua Bur., published in 2016, which mentions a compound: 616-14-8, mainly applied to SPME GC MS volatile component Ficus, Recommanded Product: 616-14-8.

This thesis developed an SPME-GC-MS method for the aroma components in Ficus tikoua Bur. fruit. At the same time, the solid-phase micro extraction conditions were optimized: extraction temperature was 50°C, the extraction time was 40 min, added 8 g of sodium chloride electrolyte solid extraction Frozen Ficus tikoua Bur. fruit was detected out of 152 kinds of volatile substances, substances detected in 99.03%of the total. The main aroma components were esters, accounting for 33.06%; alcs., accounting for 13.14%; alkanes, accounting for 13.18%; there ketones, aldehydes, acids and other substances. Higher levels of 10 kinds of aroma components were guaiacol (14.71%), cyclobutane carboxylic acid dodecyl ester (13.54%), n-tridecane (6.05%), 2-tridecanone (4.72%), cyclohexasiloxane (4.44%), cyclobutane carboxylic acid decyl ester (4.18%), Me nonyl ketone (3.62%), acetic acid (2.98%), cyclopentanecarboxylic acid thirteen ester (2.48%), 2-tetradecanol (2.31%) and so on.

Here is just a brief introduction to this compound(616-14-8)Recommanded Product: 616-14-8, more information about the compound(1-Iodo-2-methylbutane) is in the article, you can click the link below.

Reference:
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).COA of Formula: C5H11I. 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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Reference:
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 《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).Recommanded Product: 1-Iodo-2-methylbutane. 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,
Thiomorpholine | C4H9NS – PubChem

In general, if the atoms that make up the ring contain heteroatoms, such rings become heterocycles, and organic compounds containing heterocycles are called heterocyclic compounds. An article called Characteristic group frequencies of bromo- and iodoalkanes in the cesium bromide region, published in 1964, which mentions a compound: 616-14-8, Name is 1-Iodo-2-methylbutane, Molecular C5H11I, SDS of cas: 616-14-8.

The infrared spectra of 74 normal and branched bromo- and iodoalkanes were recorded and studied, 667-286 cm.-1 The number and position of the frequencies characteristic of the C–X stretching vibration are dependent on the rotational isomers present as well as the structure of the alkyl substituents in the vicinity of the C–X group. Conformational structures and representative spectra are presented along with correlation charts which list the C–X stretching vibration for various primary, secondary, and tertiary bromo- and iodoalkanes.

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Reference:
Thiomorpholine – Wikipedia,
Thiomorpholine | C4H9NS – PubChem

SDS of cas: 4531-54-8. The reaction of aromatic heterocyclic molecules with protons is called protonation. Aromatic heterocycles are more basic than benzene due to the participation of heteroatoms. Compound: 1-Methyl-4-nitro-1H-imidazol-5-amine, is researched, Molecular C4H6N4O2, CAS is 4531-54-8, about Development and validation of stability – indicating RP-HPLC chromatographic method by forced degradation studies for azathioprine by related substances. Author is Hiralben, S. Mehta; Shinghvi, Indrajeet; Raj, Hasumati A..

Simple, rapid and reproducible stability-indicating methods were established for quant. determination of azathioprine using a, phenomenex 250 mm × 4.9 mm C18, 5 μm, inertsil and UV detection at 240 nm. The isocratic elution was used to quantify the analyte and the mobile phase was acetate buffer: acetonitrile: methanol (30: 35: 35) was pumped at 1.0 mL/min. The method was linear between 10-300 μg/mL, statistically validated for its linearity, precision and accuracy. In this study, degradation behavior of azathioprine was studied by subjecting the drug to various ICH stress conditions. The intra and inter day variation was found to be less than 1% showing high precision of the assay method. It was found that the excipients in the com. tablet did not interfere with the method. Developed method can routinely use for the estimation of azathioprine related compounds from the dosage form and also for stability sample.

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Reference:
Thiomorpholine – Wikipedia,
Thiomorpholine | C4H9NS – PubChem

Recommanded Product: 1-Iodo-2-methylbutane. The protonation of heteroatoms in aromatic heterocycles can be divided into two categories: lone pairs of electrons are in the aromatic ring conjugated system; and lone pairs of electrons do not participate. Compound: 1-Iodo-2-methylbutane, is researched, Molecular C5H11I, CAS is 616-14-8, about Phenotype identification of tumor-associated macrophages in mice bearing lung carcinoma. Author is Zhang, Bi-cheng; Yang, Bo; Liu, Jian; Guan, Sha; Rao, Zhi-guo; Gao, Jian-fei.

Objective To identify the phenotype of tumor-associated macrophages (TAM) in mice bearing Lewis lung carcinoma (LLC). Methods LLC cells were planted in the dorsal necks of C57BL/6 mice s.c. The levels of Th1/Th2 cytokines in the transplantation tumors were tested by ELISA. Co-expression of CD68/macrophage mannose receptor (MMR) and CD68/inducible nitric oxide synthase (iNOS) of TAM was detected by double-labeled immunofluorescence staining. Phagocytic capacity of TAM was assessed by yeast phagocytosis assay. Results In the mice LLC transplantation tumors, Th2 cytokine shift was found in the microenvironment. The concentrations of IFN-γ and IL-12 were (2.19 ±> 0.34) ng/mL and (1635.92 ±> 754.86) ng/mL in transplantation tumors, lower than (5.49 ±> 1.04) ng/mL and (6161.48 ±>498.49) ng/mL in normal lung tissues (P <0.05). IL-4 and IL-10 were (29.31 ±> 14.47) ng/mL and (21.54 ±> 10.72) ng/mL in transplantation tumors, higher than (16.43 ±>6.31) ng/mL and (10.71 ±>2.02) ng/mL in normal lung tissues (P <0.05). The percentage of CD68/MMR(+) TAM in all the TAM was 69.7%-83.2%, while CD68/iNOS (+) was 16.8%-30.3%. The phagocytic rate and index of the transplantation tumors were (5.42 ±> 1.74)% and 0.08 ±>0.02, much lower than (23.63 ±> 5.81)% and 0.39 ±>0.14 in normal spleen tissues with statistical significance (P <0.01). Conclusion TAM in mice bearing LLC might be polarized to the alternative activation phenotype. In addition to the literature in the link below, there is a lot of literature about this compound(1-Iodo-2-methylbutane)Recommanded Product: 1-Iodo-2-methylbutane, illustrating the importance and wide applicability of this compound(616-14-8).

Reference:
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, Article, Chemical Communications (Cambridge, United Kingdom) called N-Heterocyclic olefins as efficient phase-transfer catalysts for base-promoted alkylation reactions, Author is Blumel, Marcus; Crocker, Reece D.; Harper, Jason B.; Enders, Dieter; Nguyen, Thanh V., which mentions a compound: 616-14-8, SMILESS is CCC(CI)C, Molecular C5H11I, Category: thiomorpholine.

N-Heterocyclic olefins (NHOs), e.g., I have very recently emerged as efficient promoters for several chem. reactions due to their strong Bronsted/Lewis basicities. The novel application of NHOs as efficient phase-transfer organocatalysts for synthetically important alkylation reactions on a wide range of substrates, further demonstrates the great potential of NHOs in organic chem has been reported.

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Reference:
Thiomorpholine – Wikipedia,
Thiomorpholine | C4H9NS – PubChem

Recommanded Product: 4531-54-8. Aromatic compounds can be divided into two categories: single heterocycles and fused heterocycles. Compound: 1-Methyl-4-nitro-1H-imidazol-5-amine, is researched, Molecular C4H6N4O2, CAS is 4531-54-8, about Synthesis of imidazo[4,5-b]pyrazine nucleosides. Author is Panzica, Raymond P.; Townsend, Leroy B..

5,6-Dimethyl-1-(β-D-ribofuranosyl)imidazo[4,5-b]pyrazine (I; R = β-D-ribofuranosyl) was prepared by glycosylation of the Me3Si derivative (I; R = Me3Si) (II), by fusion with 1-O-acetyl-2,3,5-tri-O-benzoyl-β-D-ribofuranose, or by cycloaddition of 4,5-diamino-1-(β-D-ribofuranosyl)-imidazole with biacetyl.

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Reference:
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 《Asymmetric reductions. VI. The action of the Grignard reagent from (+)-1-chloro-2-methylbutane on a series of alkyl tert-butyl ketones》. Authors are Foley, William M.; Welch, Frank J.; Combe, Edward M. La; Mosher, Harry S..The article about the compound:1-Iodo-2-methylbutanecas:616-14-8,SMILESS:CCC(CI)C).COA of Formula: C5H11I. Through the article, more information about this compound (cas:616-14-8) is conveyed.

cf. C.A. 51, 1828h. Title reactions were carried out with six ketones, and the % asymmetric reduction, i, was determined by comparing the observed rotation of each resulting carbinol with the maximum rotation of pure isomers obtained by resolution. The absolute configurations of the prepared carbinols were determined and R, [α]25D (neat), and i were as follows: Me, 0.63°, 13.4; iso-Pr, -0.38°, 4.6; Et, -2.94°, 10.7; Pr, -3.87°, 11.3; Bu, -3.78°, 11.0; and iso-Bu, -2.56°, 5.9. The results agreed with a reaction mechanism of Grignard reduction involving an intermediate cyclic six-membered transition state in which stereospecificity was controlled by steric interaction of the alkyl and tert-butyl groups of the ketones and the Me and Et groups of the Grignard reagent. The alkyl tert-butyl ketones were prepared by coupling the appropriate acid chloride, RCOCl, with the Grignard reagent from freshly distilled tert-BuCl in the presence of Cu2Cl2 to yield the following products (R, % yield based on Grignard reagent, b.p., and n25D given): Me, 33, 105.2°, 1.3974; Et, 89, 125.0-5.8°, 1.4049-51; Pr, 63, 145.0-5.8°, 1.4109-11; iso-Pr, 36, 135.2-6.7°, 1.4049-68; Bu, 69, 167.0-9.0°, 1.4149-59; and iso-Bu, 40, 155.5-7.0°, 1.4135-42. Only the Me and Pr tert-butylcarbinols were resolved in earlier work, and the resolution of the remaining four, by classical methods (Ingersoll, C.A. 38, 29257), is reported here. Racemic tert-BuCHEtOH (I), b. 136°, n20D 1.4235, was converted to the dl-acid phthalate, m. 88.0-8.3°. By procedures involving brucine and recrystallizations the (-)-acid phthalate (II) was obtained, m. 91.0-1.5°, [α]27D -3.75° (c 20.5, CHCl3), the rotation in CHCl3 being concentration dependent, 2.2° (c 1.5). (+)-I was regenerated from II, n20D 1.4230, α23D 27.40° (neat, l 1); acetate from (+)-I b38 74°, α24D 12.16° (neat, l 0.5), d23 0.856; benzoate from (-)-I b0.8 20°, α25D -3.19° (neat, l 0.5), n20D 1.4912, d23 0.957. Racemic tert-BuCH(OH)Pr-iso (III), b. 150.9-1.1°, n20D 1.4290-9, gave the dl-acid phthalate, m. 114.5-16.0°. The brucine salt was prepared and a less soluble form obtained, m. 173-5°, [α]28D -23°, which on hydrolysis gave an acid phthalate (IV), m. 100.5-3.0°, [α]25D 0.00°, which was hydrolyzed to (-)-III, α28D -7.22° (neat, l 1). Hydrolysis of the more soluble form of the brucine salt, [α]28D -16.1°, gave an acid phthalate (V), [α]28D 0.00°, which on hydrolysis gave (+)-III, α28D 7.22° (neat, l 1). The strychnine salt of IV was also prepared, [α]28D -25.7°, the acid phthalate regenerated, and converted to (-)-III, α28D -8.94° (neat, l 1), n20D 1.4300. The cinchonine salt of V was prepared, m. 144-7° (decomposition), [α]28D 106°, from which an acid phthalate was regenerated, m. 105.5-7.0°, and hydrolyzed to (+)-III, α28D 9.06° (neat, l 1). These latter values of -8.94° for (-)-III and 9.06° for (+)-III were considered best values. Also prepared were acetate of (+)-III, b155 130°, n21D 1.4166, α28D -1.44° (neat, l 1), and benzoate of (+)-III, b32 195°, n19D 1.4969, α25D -0.16° (neat, l 1). Racemic tert-BuCH(OH)Bu-iso (VI), b150 115-16°, n25D 1.4309, m. 17°, gave acid phthalate (VII), m. 83.5-4.5°. Strychnine was used in the resolution and eventually (+)-VII was obtained, m. 75.6-7.5°, [α]23D 8.7° (c 1.5, CHCl3), hydrolyzed to (+)-VI, m. 40-1°, α26D 57.5° (c 20.4, MeOH), and α23D 54.5° (neat, by extrapolation of rotation-concentration curve); acetate of (+)-VI b17 73°, α22D 15.15° (neat, l 0.5), n20D 1.4176, d22 0.852; benzoate of (+)-VI b0.6 88°, α25D 8.24° (neat, l 0.5), n20D 1.4870, d25 0.955. Racemic tert-BuCHBuOH (VIII), n20D 1.4320, was converted to acid phthalate (IX), m. 100.5-2.0°, and then to the strychnine salt. The regenerated (+)-IX was a glass, α23D 4.5° (c 2.8, CHCl3), which was saponified to (+)-VIII, n20D 1.4314, α24D 17.10° (neat, l 0.5). The (-)-phthalate from the more soluble fractions of strychnine salt gave (-)-VIII, α24D -16.39° (neat, l 0.5). The dl-tetrachlorophthalate of VIII was also prepared, m. 126-8°, converted to the strychnine salt, and the less soluble form, [α]25D -12°, hydrolyzed to (-)-acid tetrachlorophthalate, α22D -9.69°, which was saponified to (+)-VIII, α22D 13.70° (neat, l 0.5); 3,5-dinitrobenzoate (X) of (+)-VIII m. 107.5° (MeOH), α25D 10.0° (c 2.4, CHCl3); 3,5-dinitrobcnzoate of dl-VIII, m. 84.0-4.5°. X was saponified to (+)-VIII, b23 76°, α25D 17.12° (neat, l 0.5), n20D 1.4310, d26 0.823. The value for pure (+)-VIII was taken as α25D 34.24° (neat, l 1). From (-)-VIII, α25D -32.8° (neat, l 1), was prepared: acetate, b20 87°, α26D -11.25° (neat, l 0.5), n20D 1.4191, d26 0.851; benzoate, b0.5 98°, α25D -7.29° (neat, l 0.5), n20D 1.4887, d25 0.936; p-nitrobenzoate, b0.5 144-5°, α29D -12.50°, n25D 1.5070. Some work was done with the Grignard reagents of the following prepared compounds: (+)-1-bromo-2-methylbutane, b100 60.8°, n20D 1.4453, α24D 4.22° (neat, l 1), 84% optical purity, a 2nd preparation b100 57-8°, α26.6D 4.66°, 93% optical purity; and (+)-1-iodo-2-methytbutane, n20D 1.4955-69, α21D 8.65° (neat, l 1), 98.5% optical purity, 2nd preparation b53 70°, n20D 1.4969-72, α25D 16.8° (neat, l 2), optical purity 96.5%.

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Reference:
Thiomorpholine – Wikipedia,
Thiomorpholine | C4H9NS – PubChem

Castello, Gianrico published an article about the compound: 1-Iodo-2-methylbutane( cas:616-14-8,SMILESS:CCC(CI)C ).COA of Formula: C5H11I. Aromatic heterocyclic compounds can be classified according to the number of heteroatoms or the size of the ring. The authors also want to convey more information about this compound (cas:616-14-8) through the article.

Alkyl radicals formed in low-pressure radiofrequency plasmas were identified by gas chromatog. using I as a scavenger compound Iodine vapors, injected into the glowing plasma discharge, reacted with active radicals in the gas phase, yielding various saturated alkyl iodides, that were trapped by freezing in an organic solvent and analyzed on Apiezon L and Carbowax 20M columns. Analyses carried out at different temperatures permitted the retention times and indexes to be measured and the relative molar heats of solution to be calculated

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Reference:
Thiomorpholine – Wikipedia,
Thiomorpholine | C4H9NS – PubChem