Predictions alcohol

Predict Alcohols can undergo a chemical reaction to form carboxylic acids in the presence of potassium permanganate. If the alcohol used is ethanol, what would you predict to be the chemical formula of the acid produced ... 

Figure 1 compares data reduction using the modified UNIQUAC equation with that using the original UNIQUAC equation. The data are those of Boublikova and Lu (1969) for ethanol and n-octane. The dashed line indicates results obtained with the original equation (q = q for ethanol) and the continuous line shows results obtained with the modified equation. The original equation predicts a liquid-liquid miscibility gap, contrary to experiment. The modified UNIQUAC equation, however, represents the alcohol/n-octane system with good accuracy. 

An adequate prediction of multicomponent vapor-liquid equilibria requires an accurate description of the phase equilibria for the binary systems. We have reduced a large body of binary data including a variety of systems containing, for example, alcohols, ethers, ketones, organic acids, water, and hydrocarbons with the UNIQUAC equation. Experience has shown it to do as well as any of the other common models. V7hen all types of mixtures are considered, including partially miscible systems, the... 

Since (A) does not contain any other functional group in addition to the formyl group, one may predict that suitable reaction conditions could be found for all conversions into (A). Many other alternative target molecules can, of course, be formulated. The reduction of (H), for example, may require introduction of a protecting group, e.g. acetal formation. The industrial synthesis of (A) is based upon the oxidation of (E) since 3-methylbutanol (isoamyl alcohol) is a cheap distillation product from alcoholic fermentation ( fusel oils ). The second step of our simple antithetic analysis — systematic disconnection — will now be exemplified with all target molecules of the scheme above. For the sake of brevity we shall omit the syn-thons and indicate only the reagents and reaction conditions. 

The demand for amyl alcohols is expected to remain unchanged until 1993. Competition from other alcohols and limited appHcations limit growth in markets for amyl alcohols. U.S. demand was predicted to grow from 29 x 10 t in 1983 to 32 x Kf t by 1990 (152). In Europe, amyl alcohols account for over 80% of the demand for valeraldehyde (17,000 t in 1984). BASE and Hoechst AG produce both / -valeraldehyde and 2-methylbutyraldehyde from butenes by the oxo process (149). The demand for C-5 in Europe is also predicted not to grow substantially (150). Amyl alcohols are growing at a much lower rate than other oxo alcohols as shown in Table 7. 

The thermal glass-transition temperatures of poly(vinyl acetal)s can be determined by dynamic mechanical analysis, differential scanning calorimetry, and nmr techniques (31). The thermal glass-transition temperature of poly(vinyl acetal) resins prepared from aliphatic aldehydes can be estimated from empirical relationships such as equation 1 where OH and OAc are the weight percent of vinyl alcohol and vinyl acetate units and C is the number of carbons in the chain derived from the aldehyde. The symbols with subscripts are the corresponding values for a standard (s) resin with known parameters (32). The formula accurately predicts that resin T increases as vinyl alcohol content increases, and decreases as vinyl acetate content and aldehyde carbon chain length increases. 

Variables a andZ are specific constants reported by Tsonopoulos for some alcohols and water (e.g., methanol a = 0.0878, b = 0.0560 and water a = 0.0279, b = 0.0229). Tsonopoulos also gives specific prediction methods for haloalkanes and water pollutants. 

Comparison of Table 5.4 and 5.7 allows the prediction that aromatic oils will be plasticisers for natural rubber, that dibutyl phthalate will plasticise poly(methyl methacrylate), that tritolyl phosphate will plasticise nitrile rubbers, that dibenzyl ether will plasticise poly(vinylidene chloride) and that dimethyl phthalate will plasticise cellulose diacetate. These predictions are found to be correct. What is not predictable is that camphor should be an effective plasticiser for cellulose nitrate. It would seem that this crystalline material, which has to be dispersed into the polymer with the aid of liquids such as ethyl alcohol, is only compatible with the polymer because of some specific interaction between the carbonyl group present in the camphor with some group in the cellulose nitrate. 

It was found that the amount of chlorine that could be removed (84-87%) was in close agreement to that predicted by Flory on statistical grounds for structure Figure 12.10(a). It is of interest to note that similar statistical calculations are of relevance in the cyclisation of natural rubber and in the formation of the poly(vinyl acetals) and ketals from poly(vinyl alcohol). Since the classical work of Marvel it has been shown by diverse techniques that head-to-tail structures are almost invariably formed in addition polymerisations. 

Recently it has been shown that certain unsaturated ketones and alcohols are dehydrogenated extremely easily by DDQ. While the rapid dehydrogenation of the A ° -dien-3-one (73) is predictable (c/. A -3-ketones), the equally facile reaction of the 3-alcohol (75) is surprising. Presumably (73) is an intermediate in the conversion of (75), although oxidation of nonallylic alcohols normally requires higher temperatures. A -3-Ketones, A ° -3-ketones and A ( o) 3(x aicohols do not react at room temperature. ... 

Sn2 reactions with anionic nucleophiles fall into this class, and observations are generally in accord with the qualitative prediction. Unusual effects may be seen in solvents of low dielectric constant where ion pairing is extensive, and we have already commented on the enhanced nucleophilic reactivity of anionic nucleophiles in dipolar aprotic solvents owing to their relative desolvation in these solvents. Another important class of ion-molecule reaction is the hydroxide-catalyzed hydrolysis of neutral esters and amides. Because these reactions are carried out in hydroxy lie solvents, the general medium effect is confounded with the acid-base equilibria of the mixed solvent lyate species. (This same problem occurs with Sn2 reactions in hydroxylic solvents.) This equilibrium is established in alcohol-water mixtures ... 

Thus, the acidity oi a lactam is evidently not a reliable quantity for predicting the course of the methylation. The acidity gives information only as to the reaction velocity. In this connection the reaction course of isomethylreductone (6) is illuminating, " With diazomethane in ether containing 1 mole of water, the enolraethyl ether (7) is formed. However, if water is present only in traces, then the alcoholic hydroxyl group is selectively attacked to give 8. 

A Alkenes can be converted into alcohols by acid-catalyzed addition of water. Assuming that Vlarkovnikov s rule is valid, predict the major alcohol product from each of the following alkenes. 

Thomson Click Organic Interactive to use a web-based palette to predict products from a variety of reactions involving alcohols. 

Predict the product formed by nucleophilic addition of cyanide ion (CN ) to the carbonyl group of acetone, followed by protonalion to give an alcohol ... 

Predicting the Product of Reaction between a Ketone and an Alcohol... 

Aldehydes and ketones react with thiols to yield thioacetals just as they react with alcohols to yield acetals. Predict the product of the following reaction, and propose a mechanism ... 

---