Cyclohexanol 1-benzyl

Riboflavin forms fine yellow to orange-yeUow needles with a bitter taste from 2 N acetic acid, alcohol, water, or pyridine. It melts with decomposition at 278—279°C (darkens at ca 240°C). The solubihty of riboflavin in water is 10—13 mg/100 mL at 25—27.5°C, and in absolute ethanol 4.5 mg/100 mL at 27.5°C it is slightly soluble in amyl alcohol, cyclohexanol, benzyl alcohol, amyl acetate, and phenol, but insoluble in ether, chloroform, acetone, and benzene. It is very soluble in dilute alkah, but these solutions are unstable. Various polymorphic crystalline forms of riboflavin exhibit variations in physical properties. In aqueous nicotinamide solution at pH 5, solubihty increases from 0.1 to 2.5% as the nicotinamide concentration increases from 5 to 50% (9). 

Butyl alcohol, ethylene glycol monoethyl ether, cyclohexanol, benzyl alcohol, diethylene glycol monobutyl ether, and dibutyl phthalate... 

Senol, A. Vapor liquid equilibria of the systems ethyl ethanoate + 2-methyl-2-butanol, 2-methyl-l-propanol + 3-methyl-l-butanol, and cyclohexanol + benzyl alcohol at 101.32 kPa, J. Chem. Eng. Data, 43(5) 763-769, 1998. 

Hammad and Muller (1998) studied the effect of addition of alcohol with different hydrophilicity, such as ethanol, propanol, butanol, pentanol, cyclohexanol, benzyl alcohol as well as 2-phenylethano on clonazepam solubility in MM. Addition of alcohols with ascending lipophilicity beginning with ethanol, propanol, and upto butanol, insigniLcantly affected clonazepam solubility in MM. Addition of pentanol cyclohexanol, benzyl alcohol, or 2-phenylethanol increased the solubility to different degrees. The increase in the lipophilicity of alcohol increased its afLnity to the micellar phase and hence a higher concentration of the alcohol in the micellar phase is expected. 

Many important industrial chemicals are classified as harmful, e.g., the organic compounds toluene, glycols, cyclohexanol, benzyl alcohol, benzaldehyde, maleic anhydride, isobutyric acid, the inorganic compounds iodine, brownstone (manganese dioxide), dimercury dichloride (calomel), vanadium pentoxide, and many compounds of copper and cobalt (see Fig. 3.4). 

Butanol Pentanol Cyclohexanol Benzyl alcohol Aromas ... 

Pentanol, Cyclohexanol, Benzyl Alcohol, 1-Phenylethanol, and Methanol 1-Pentanol, cyclohexanol, benzyl alcohol, and 1-phenylethanol can be oxidized to the corresponding carbonyls in a continuous gas-solid reactor with commercial anatase Ti02 particles at about 463 K in moderate yield (37 %) but with high selectivity (>95 %) [2]. Methanol gives methyl formate at room temperature with a selectivity of 87-91 %, whereas formaldehyde, CO, and CO2 are detected as minor products [5]. 

Alcohols. Methanol, ethanol, n propanol, propan-i-ol.n-butanol, glycol, glycerol, benzyl alcohol, cyclohexanol. 

Physical Properties. All colourless liquids, completely miscible with water, except benzyl alcohol and cyclohexanol, which are slightly soluble. Pure glycol and glycerol have high viscosity, which falls as the hygroscopic liquids absorb water from the air. 

Water with aniline, benzene, benzyl alcohol, carbon disulfide, carbon tetrachloride, chloroform, cyclohexane, cyclohexanol, cyclohexanone, diethyl ether, ethyl acetate, isoamyl alcohol, methyl ethyl ketone, nitromethane, tributyl phosphate or toluene. 

Secondary alcohols such as cyclohexanol or 2-butanol also react on heating for 20-120 min at 80 °C with TCS 14 in the presence of BiCl3 to give the chloro compounds cyclohexyl chloride 784 and 2-chlorobutane in 93 and 90% yield, respectively, HCl, and HMDSO 7 [11, 12]. Benzyl alcohol is transformed likewise by Me3SiCl 14 after 120 min. at 80 °C into benzyl chloride in quantitative yield. Analogously, esters such as 2-acetoxypropane 785 are also converted by TCS 14 in 100% yield into chloro compounds such as 786 and trimethylsilyl acetate 142. The yS-lactone 787 gives rise to 788... 

Finally, reaction of primary, secondary, or tertiary alcohols 11 with Me3SiCl 14 in the presence of equivalent amounts of DMSO leads via 789 and 790 to the chloro compounds 791 [13]. n-Pentanol, benzyl alcohol, yS-phenylefhanol or tert-butanol are readily converted, after 10 min reaction time, into their chloro compounds, in 89-95% yield, yet cyclohexanol affords after reflux for 4 h cyclohexyl chloride 784 in only 6% yield [13] (Scheme 6.5). 1,4-Butanediol is cyclized to tetrahydrofuran (THF) [13a], whereas other primary alcohols are converted in 90-95% yield into formaldehyde acetals on heating with TCS 14 and DMSO in benzene [13b] (cf also the preparation of formaldehyde di(n-butyl)acetal 1280 in Section 8.2.1). 

Production of considerable amounts of cyclohexanol and cyclohexanone as well as benzaldehyde and benzoic acid in the oxidation of benzyl cyclohexyl ether shows the primary radical to be CgHjCHOCeHjj. Abstraction from aliphatic C-H bonds cannot occur in the case of diphenyl ether which is oxidised rapidly, and removal of a 7t-electron is likely. 

Another recent patent (22) and related patent application (31) cover incorporation and use of many active metals into Si-TUD-1. Some active materials were incorporated simultaneously (e.g., NiW, NiMo, and Ga/Zn/Sn). The various catalysts have been used for many organic reactions [TUD-1 variants are shown in brackets] Alkylation of naphthalene with 1-hexadecene [Al-Si] Friedel-Crafts benzylation of benzene [Fe-Si, Ga-Si, Sn-Si and Ti-Si, see apphcation 2 above] oligomerization of 1-decene [Al-Si] selective oxidation of ethylbenzene to acetophenone [Cr-Si, Mo-Si] and selective oxidation of cyclohexanol to cyclohexanone [Mo-Si], A dehydrogenation process (32) has been described using an immobilized pincer catalyst on a TUD-1 substrate. Previously these catalysts were homogeneous, which often caused problems in separation and recycle. Several other reactions were described, including acylation, hydrogenation, and ammoxidation. 

With the more active RNi cathode, the electrohydrogenation is much less selective and hydrogenolysis of the benzylic C-O bond of 26 occurs to an appreciable extent to give / -aminophcnethyl alcohol (28) and cyclohexanol (30) in 70% yield (30% yield of aminodioxolane 28) after 8.9 F/mol (15). The hydrogenolysis of the benzylic C-O bond gives the intermediate hemiketal 27 which cleaves to p-aminophenethyl alcohol (30) and cyclohexanone (29) (Scheme 9). Cyclohexanone is electiohydrogenated further to cyclohexanol (30). 

A further attempt has been made to develop a predictive model for chirality transfer achieved through alkylation reactions of ester enolates which feature chiral auxiliaries. " Hippurate esters (30) derived from (lI , 25 )-trani-2-(p-substituted phenyl)cyclohexanols were found, on reaction with benzyl bromide, to give (31) with predominantly the S configuration at the alkylation centre but with no correlation between the degree of stereoselectivity (20-98%) and the electron density on the aromatic ring. 

Varieties of primary and secondary alcohols are selectively oxidized to aldehyde or carbonyl compounds in moderate to excellent yields as summarized in Table 3. As can be seen, /(-substituted benzyl alcohols (e.g., -Cl, -CH3, -OCH3, and -NO2) yielded > 90% of product conversion in 3-4 h of reaction time with TOP in the range of 84-155 h (entries 2-5, Table 3), Heterocyclic alcohols with sulfur- and nitrogen-containing compoimds are found to show the best catalytic yield with TOP of 1517 and 902 h for (pyrindin-2-yl)methanol and (thiophene-2-yl) methanol, respectively (entries 9 and 10, Table 3). Some of aliphatic primary alcohols (long chain alcohols) and secondary alcohols (cyclohexanol, its methyl substituted derivatives and norboman-2-ol) are also selectively oxidized by the membrane catalyst (entries 11-14 and 15-17, Table 3) with TOP values in the window of 8-... 

Kinetic studies of hexacyanoferrate(III) oxidations have included the much-studied reaction with iodide and oxidation of the TICI2 anion, of hydrazine and hydrazinium, and of phenylhydrazine and 4-bromophenylhydrazine. These last reactions proceed by outer-sphere mechanisms, and conform to Marcus s theory. Catalyzed [Fe(CN)g] oxidations have included chlororuthenium-catalyzed oxidation of cyclohexanol, ruthenium(III)-catalyzed oxidation of 2-aminoethanol and of 3-aminopropanol, ruthenium(VI)-catalyzed oxidation of lactate, tartrate, and glycolate, and osmium(VIII)-catalyzed oxidation of benzyl alcohol and benzylamine. ... 

The application of ionic liquids as a reaction medium for the copper-catalyzed aerobic oxidation of primary alcohols was reported recently by various groups, in attempts to recycle the relatively expensive oxidant TEMPO [150,151]. A TEMPO/CuCl-based system was employed using [bmim]PF6 (bmim = l-butyl-3-methylimodazolium) as the ionic liquid. At 65 °C a variety of allylic, benzylic, aliphatic primary and secondary alcohols were converted to the respective aldehydes or ketones, with good selectiv-ities [150]. A three-component catalytic system comprised of Cu(C104)2, dimethylaminopyridine (DMAP) and acetamido-TEMPO in the ionic liquid [bmpy]Pp6 (bmpy = l-butyl-4-methylpyridinium) was also applied for the oxidation of benzylic and allylic alcohols as well as selected primary alcohols. Possible recycling of the catalyst system for up to five runs was demonstrated, albeit with significant loss of activity and yields. No reactivity was observed with 1-phenylethanol and cyclohexanol [151]. 

Very recently, Hu et al. claimed to have discovered a convenient procedure for the aerobic oxidation of primary and secondary alcohols utilizing a TEMPO based catalyst system free of any transition metal co-catalyst (21). These authors employed a mixture of TEMPO (1 mol%), sodium nitrite (4-8 mol%) and bromine (4 mol%) as an active catalyst system. The oxidation took place at temperatures between 80-100 °C and at air pressure of 4 bars. However, this process was only successful with activated alcohols. With benzyl alcohol, quantitative conversion to benzaldehyde was achieved after a 1-2 hour reaction. With non-activated aliphatic alcohols (such as 1-octanol) or cyclic alcohols (cyclohexanol), the air pressure needed to be raised to 9 bar and a 4-5 hour of reaction was necessary to reach complete conversion. Unfortunately, this new oxidation procedure also depends on the use of dichloromethane as a solvent. In addition, the elemental bromine used as a cocatalyst is rather difficult to handle on a technical scale because of its high vapor pressure, toxicity and severe corrosion problems. Other disadvantages of this system are the rather low substrate concentration in the solvent and the observed formation of bromination by-products. 

The data in Table 2 show the potential of the Na2B407 based catalyst system tested over large number of representative alcohols. The primary alcohols were oxidized to the corresponding aldehydes at complete conversion of the alcohol and at 90-93% selectivity. The only by-products observed were the corresponding acid and minor amounts of the symmetrical ester (Entry 2, 3). Benzyl alcohol was quantitatively converted to benzaldehyde. The secondary alcohols, 4-methyl cyclohexanol and 4-methylpentanol were converted to the corresponding ketones at room temperature. 

The discovery of 1 -aryl-1 -dimethylamino-cyclohexanes resulted from a surrey of compounds in which aromatic and basic features, both critical structural requirements of opioid analgesics, but usually separated by two or three carbon atoms, are linked to the same quaternary carbon. The synthesis of these compounds yielded a series of highly potent opioids (e.g. 1-Benzyl-4-(4-bromo-phenyl)-4-dimethylamino-cyclohexanol), however none of them are in clinical use (Lednicer et al., 1981). 

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