laboratory method of preparing alcohol

Laboratory method of preparing alcohol

Hydrolysis of Alkyl Halides

This is a nucleophilic substitution reaction.

R-X + KOH_aq → R-OH

The method is not satisfactory as olefins are also formed as by-products. However better yields is obtained by using moist Ag₂O or aqueous K₂CO₃. Tertiary butyl halides mainly gives alkene due to dehydrohalogenation.

Hydration of Alkenes

This is electrophilic addition of H₂O to alkenes.

Mechanism of Hydration of alkenes:

Protonation of alkene to form carbocation by electrophilic

Nucleophilic attack of water on carbocation.

Deprotonation to form an alcohol.

Except ethyl alcohol no other primary alcohol can be obtained by this method, however hydroboration of terminal alkenes give primary alcohols.

Oxymercuration and Demercuration of Alkanes

Alkenes react with mercuric acetate in presence of H₂O and tetra hydrofuran to give alkyl mercury compounds.

Examples:

Hydroboration Oxidation

From Grignard Reagents

All the three types of monohydric alcohols (primary, secondary and tertiary alcohols) are obtained by the use of Grignard reagents and carbonyl compounds. The addition of RMgX on carbonyl compounds followed with hydrolysis yields alcohols.

The Grignard reagent : an organometallic compound

When a solution of an alkyl halide in dry ethyl ether, (C₂H₅)O, is allowed to stand over turnings of metallic magnesium a vigorous reaction takes place: the solution turns cloudy, begins to boil, and the magnesium Metal gradually disappears. The resulting solution is known as a Grignard reagent, after Victor Grignard (of the University of Lyons) who received the Nobel prize in 1912 for its discovery. It is one of the most useful and versatile reagents known to the organic chemist.

CH₃I + Mg CH₃MgI

H₃CH₂Br + Mg CH₃CH₂MgBr

Ethyl bromide Ethylmagnesium bromide

The Grignard reagent has the general formula R MgX, and the general name alkylmagnesium halide. The carbon-magnesium bond is covalent but highly polar, with carbon pulling electrons from electropositive magnesium; the magnesium halogen bond is essentially ionic. R^–Mg⁺X

Since magnesium becomes bonded to the same carbon that previously held halogen, the alkyl group remains intact during the preparation of the reagent. Thus n-propyl chloride yields n-propylmagnesium chloride, and isopropyl chloride yields isopropylmagnesium chloride.

CH₃CH₂CH₂Cl + Mg CH₃CH₂CH₂MgCl

n-Propyl chloride n-Propylmagnesium chloride

CH₃CHClCH₃ + Mg CH₃CHMgClCH₃

Isopropyl chloride Isopropylmagnesium chloride

The Grignard reagent is the best-known member of a broad class of substances, called organometallic compounds, in which carbon is bonded to a metal: lithium potassium, sodium, zinc, mercury, lead, thallium-almost any metal known. Each kind of organometallic compound has, of course, its own set of properties, and its particular uses depend on these. But whatever the metal, it is less elctronegative than carbon, and the carbon-metal bond-like one in the Grignard reagent – is highly polar. Although the organic group is not a full-fledged carbanion–an anion in which carbon carries negative charge–it nevertheless has considerable carbanion character. As we shall see, organometallic compounds owe their enormous usefulness chiefly to one common quality: they can serve as a source from which carbon is readily transferred with its electrons.

The Grignard reagent is highly reactive. It reacts with numerous inorganic compounds including water, carbon dioxide, and Oxygen, and with most kinds of organic compounds; in many of these cases the reaction provides the best way to make a particular class of organic compounds.

The reaction with water to form an alkane is typical of the behaviour of the Grignard reagent–and many of the more reactive organometallic compounds–toward acids. In view of the marked carbanion character of the alkyl group, we may consider the Grignard reagent to be the magnesium salt, R MgX, of the extremely weak acid,

R–H. The reaction

R MgX + HOH → R–H + Mg(OH)X

Stronger Weaker

acid acid

is simply the displacement of the weaker acid, R–H, from its salt by the stronger acid, HOH.

R MgX + NH₃ → R–H + Mg(NH₂)X

Stronger Weaker

acid acid

An alkane is such a weak acid that it is displaced from the Grignard reagent by compounds that we might ordinarily consider to be very weak acids themselves, or possibly not acids at all. Any compound containing hydrogen attached to oxygen or nitrogen is tremendously more acidic than an alkane, and therefore can decompose the Grignard reagent: for example, ammonia or methyl alcohol.

RMgX + CH₃OH → R–H + Mg(OCH₃)X

Stronger Weaker

acid acid

Grignard Synthesis of Alcohols

The Grignard reagent, we recall, has the formula RMgX, and is prepared by the reaction of metallic magnesium with the appropriate organic halide. This halide can be alkyl (1^o, 2^o, 3^o), allylic, aryl alkyl (e.g., benzyl), or aryl (phenyl) or substituted phenyl. The halogen may be –Cl, –Br or –I, (Arylmagnesium chlorides must be made in the cyclic ether tetrahydrofuran instead of ethyl ether.)

Aldehydes and ketones resemble each other closely in most of their reactions. Like the carbon-carbon double bond, the carbonyl group is unsaturated, and like the carbon-carbon bond, it undergoes addition. One of its typical reactions is addition of the Grignard reagent.

Since the electrons of the carbonyl double bond hold together atoms of quite different electronegativity, we would not expect the electrons to be equally shared; in particular, the mobile p cloud should be pulled strongly towards the more electronegative atom, oxygen. Whatever the mechanism involved, addition of an unsymmetrical reagent is oriented so that the nucleophilic (basic) portion attaches itself to carbon, and the electrophilic (acidic) portion attaches itself to oxygen.

The carbon-magnesium bond of the Grignard reagent is a highly polar bond, carbon being negative relative to electropositive magnesium. It is not surprising, then, that in the addition to carbonyl compounds, the organic group becomes attached to carbon and magnesium to oxygen. The product is the magnesium

salt of the weakly acidic alcohol and is easily converted into the alcohol itself by the addition of the stronger acid, water. Since the Mg(OH)X thus formed is a gelatinous material difficult to handle, dilute mineral acid (HCl, H₂SO₄) is commonly used instead of water, so that water-soluble magnesium salts are formed.

Products of the Grignard Synthesis

The class of alcohol that is obtained from a Grignard synthesis depends upon the type of carbonyl compoud used: formaldehyde, HCHO, yields primary alcohols; other aldehydes, RCHO, yield secondary alcohols; and ketones, R₂CO, yield tertiary alcohols.

This relationship arises directly from our definitions of aldehydes and ketones, and our definitions of primary, secondary, and tertiary alcohols. The number of hydrogens attached to the carbonyl carbon defines the carbonyl compound as formaldehyde, higher aldehyde or ketone. The carbonyl carbon is the one that finally bears the –OH group in the product; here the number of hydrogen defines the alcohol as primary, secondary, or tertiary.

For example:

A related synthesis utilized ethylene oxide to make primary alcohols containing two more carbons than the Grignard reagent.

Here, too, the organic group becomes attached to carbon and magnesium to oxygen, this time with the breaking of a carbon-oxygen s bond in the highly strained three-membered ring. For example:

Reduction of Carbonyl Compounds

Aldehydes can be reduced to primary alcohols, and ketones to secondary alcohols, either by catalytic hydrogenation or by use of chemical reducing agents like lithium aluminum hydride, LiAlH₄. Such reduction is useful for the preparation of certain alcohols that are less available than the corresponding carbonyl compounds, in particular carbonyl compounds that can be obtained by the aldol condensation. For example

Reduction of ketones gives secondary alcohol.

Note : tertiary alcohols can be obtained by this method.

Sodium borohydride, NaBH₄, does not reduce carbon-carbon double Bonds, not even those conjugated with carbonyl groups, and in thus useful for the reduction of such unsaturated carbonyl compounds to unsaturated alcohols.Let us look a little more closely at reduction by metal hydrides. Alcohols are formed from carbonyl compounds, smoothly and in high yield, by the action of such compounds as lithium aluminum hydride, LiAlH₄. Here again, we see

Nucleophilic addition : this time the nucleophile is hydrogen transferred with a pair of electrons-as a hydride ion, H:^––from the metal to carbonyl carbon:

Reduction of acids to alcohols: Lithium aluminum hydride, LiAlH₄, is one of the few reagents that can reduce an acid to an alcohol; the inital product is an alkoxide from which the alcohol is liberated by hydrolysis:

4RCOOH + 3LiAlH₄ → 4RCH₂OH 1^oalcohol

Because of the excellent yields it gives, LiAlH₄ is widely used in the laboratory for the reduction of not only acids but many other classes of compounds. As an alternative to direct reduction, acids are often converted into alcohols by a two-step process: esterification, and reduction of the ester.

Reduction of esters: Like many organic compounds, esters can be reduced in two ways: (A) by catalytic hydrogenation using molecular hydrogen, or (B) chemical reduction. In either case, the ester is cleaved to yield (in addition to the alcohol or phenol from which it was derived) a primary alcohol corresponding to the acid portion of the ester.

RCOOR’ RCH₂OH + R’OH

Ester 1^oalcohol

Hydrogenolysis (cleavage by hydrogen) of an ester requires more severe conditions than simple hydrogenation of (addition of hydrogen to) a carbon-carbon double bond. High pressures and elevated temperatures are required: the Catalyst used most often is a mixture of oxides known as copper chromite, of approximately the composition CuO.CuCr₂O₄. For example:

CH₃(CH₂)₁₀COOCH₃ CH₃(CH₂)₁₀CH₂OH + CH₃OH

(Methyl dodecanoate) (1-Dodecanol)

Chemical reduction is carried out by use of sodium metal and alcohol, or more usually by use of lithium aluminium hydride

By the reduction of acids and their Derivatives :

RCOOH RCH₂OH

(RCO₂)O RCH₂OH

RCOCI RCH₂OH

RCOOR’ RCH₂OH + R’OH

Note : If C₂H₅OH + Na is used as reducing agent, the reduction is known as Bouveault-Blane reaction.

By the action of nitrous acid on primary amines :

R-NH₂ + HNO₂ → R-OH + N₂ + H₂O

However under similar conditions CH₃NH₂ gives CH₃-O-N=O or CH₃OCH₃

CH₃NH₂ + 2HNO₂ → CH₃-O-N=O + 2H₂O + N₂

or 2CH₃NH₂ + 2HNO₂ → CH₃OCH₃ + 2N₂ + 3H₂O

Preparation of Methanol: Methanol can also be prepared as

Hydroxylation of Alkenes

By Fermentation-2/”>Fermentation :

Fermentation is the slow decomposition of complex organic compounds into simpler organic compounds by the activity of ENZYMES. Enzymes are complex, nitrogenous (proteins), non living macro Molecules of high molecular weight derived from living organisms. These are also known as biological catalysts.

Fermentation process is generally accompanied with evolution of gases like CO₂ & CH₄ and are exothermic in nature.

The alcoholic fermentation involves conversion of sugar into ethyl alcohol by yeast.

The starting material for alcoholic fermentation is starch (potato, rice, barley, maize). The source of starch depends upon its availability in that country. In India, alcoholic fermentation is made by molasses i.e. the dark coloured syrupy liquid left after crystallization of sugar from sugar cane juice. Molasses contains about 50% sugar left after crystallization of sugar from cane juice.

Conditions Favourable for Fermentation

1.Optimum temperature range for fermentation s 25-30^oC. At higher temperature enzymes are coagulated.

2.Certain inorganic substances, (NH₄)₂SO₄, phosphate etc are added as food for ferment cells.

3.Solution to be fermented should be dilute.

4.Substances like boric acid, mercury slats etc. should not be present as they retard fermentation.

5.Proper aeration should be maintained in fermentation.

Note : The name fermentation has been derived from Latin word ferver meaning to boil, because during fermentation there is lot of frothing due to evolution of CO₂ and this gives the appearance of boiling liquid.

Distillation is a process of separating a mixture of liquids into its component parts by boiling and then condensing the vapors. The boiling point of a liquid is the temperature at which the vapor pressure of the liquid equals the external pressure surrounding the liquid. When a liquid is boiled, the molecules at the surface of the liquid have enough energy to escape into the vapor phase. The vapor molecules then rise into the air and cool, condensing back into a liquid. The liquid that condenses is called the distillate.

Fermentation is a metabolic process that produces alcohol and carbon dioxide from sugars. The process is carried out by yeast, which is a type of fungus. Yeast cells convert sugars into alcohol and carbon dioxide by a process called glycolysis. Glycolysis is a series of chemical reactions that break down glucose into pyruvate. Pyruvate is then converted into alcohol and carbon dioxide by a series of other chemical reactions.

Distillation apparatus is a piece of equipment used to separate a mixture of liquids into its component parts by boiling and then condensing the vapors. The distillation apparatus consists of a still, a condenser, and a receiver. The still is the vessel in which the mixture is boiled. The condenser is a tube that cools the vapors, causing them to condense back into a liquid. The receiver is the vessel that collects the distillate.

Fermentation apparatus is a piece of equipment used to carry out the fermentation process. The fermentation apparatus consists of a fermentation vessel, a fermentation medium, and a yeast culture. The fermentation vessel is the container in which the fermentation process takes place. The fermentation medium is the substance in which the yeast cells grow and multiply. The yeast culture is a Population of yeast cells that are used to carry out the fermentation process.

Alcohol content is the Percentage of alcohol in a liquid. The alcohol content of a liquid is determined by the amount of alcohol in the liquid, expressed as a percentage of the total volume of the liquid. The alcohol content of a liquid can be determined by a variety of methods, including distillation, gas chromatography, and spectrophotometry.

Safety precautions are measures that are taken to prevent accidents or injuries. Safety precautions are important when working with any type of equipment, including distillation apparatus and fermentation apparatus. Some important safety precautions to take when working with distillation apparatus and fermentation apparatus include:

Always wear safety goggles when working with distillation apparatus and fermentation apparatus.
Always wear gloves when working with distillation apparatus and fermentation apparatus.
Always work in a well-ventilated area when working with distillation apparatus and fermentation apparatus.
Always dispose of waste properly when working with distillation apparatus and fermentation apparatus.

Disposal of waste is the process of getting rid of waste in a safe and environmentally friendly way. There are a variety of ways to dispose of waste, including:

Recycling
Composting
Landfilling
Incineration

The best way to dispose of waste depends on the type of waste and the local regulations. It is important to check with the local authorities to find out the best way to dispose of waste in your area.

Conclusion

Distillation and fermentation are two important processes that are used to produce alcohol. Distillation is a process of separating a mixture of liquids into its component parts by boiling and then condensing the vapors. Fermentation is a metabolic process that produces alcohol and carbon dioxide from sugars. The distillation apparatus and fermentation apparatus are pieces of equipment that are used to carry out the distillation and fermentation processes, respectively. Safety precautions are important when working with distillation apparatus and fermentation apparatus. Waste should be disposed of properly to protect the Environment.

What is alcohol?

Alcohol is a chemical compound that is found in many different drinks, including beer, wine, and liquor. It is also used in many different products, such as hand sanitizer and gasoline. Alcohol is a depressant, which means that it slows down the central nervous system. This can lead to a number of effects, including impaired judgment, coordination, and reaction time. Alcohol can also be addictive.

How is alcohol made?

Alcohol is made through a process called fermentation. This process involves yeast converting sugar into alcohol and carbon dioxide. Fermentation can be done with a variety of different ingredients, including grains, fruits, and vegetables.

What are the different types of alcohol?

There are many different types of alcohol, but the most common are beer, wine, and liquor. Beer is made from fermented grains, wine is made from fermented grapes, and liquor is made from fermented grains or fruits.

What are the effects of alcohol?

Alcohol can have a number of different effects on the body, including:

Impaired judgment
Impaired coordination
Impaired reaction time
Drowsiness
Slurred speech
Nausea
Vomiting
Hangover

What are the risks of drinking alcohol?

There are a number of risks associated with drinking alcohol, including:

Alcohol poisoning
Accidents
Violence
Unintended pregnancy
Sexual assault
Liver damage
Heart disease
Cancer
Death

How much alcohol is safe to drink?

The amount of alcohol that is safe to drink varies from person to person. However, it is generally recommended that Women drink no more than one drink per day and men drink no more than two drinks per day.

What are the benefits of drinking alcohol?

There are a few potential benefits of drinking alcohol, including:

Reduced risk of heart disease
Reduced risk of stroke
Reduced risk of type 2 diabetes
Increased bone density
Improved cognitive function

However, it is important to note that these benefits are only seen in people who drink moderate amounts of alcohol. Drinking too much alcohol can have serious Health risks.

How can I reduce my risk of alcohol-related problems?

There are a number of things you can do to reduce your risk of alcohol-related problems, including:

Drinking in moderation
Not drinking and driving
Not drinking if you are pregnant
Not drinking if you are taking certain medications
Not drinking if you have a history of alcohol abuse
Talking to your doctor about your drinking

Where can I get more information about alcohol?

You can get more information about alcohol from a number of sources, including:

Your doctor
The National Institute on Alcohol Abuse and Alcoholism (NIAAA)
The Substance Abuse and Mental Health Services Administration (SAMHSA)
The Centers for Disease Control and Prevention (CDC)

Sure, here are some MCQs about alcohol without mentioning the laboratory method of preparing it:

Alcohol is a:
(A) depressant
(B) stimulant
(C) hallucinogen
(D) none of the above
Alcohol is produced by the fermentation of:
(A) grapes
(B) barley
(C) wheat
(D) all of the above
Alcohol is absorbed into the bloodstream through the:
(A) stomach
(B) small intestine
(C) large intestine
(D) all of the above
Alcohol is metabolized by the liver at a rate of:
(A) 1 drink per hour
(B) 2 drinks per hour
(C) 3 drinks per hour
(D) 4 drinks per hour
The effects of alcohol on the body include:
(A) impaired judgment
(B) coordination
(C) reaction time
(D) all of the above
Alcohol can cause a number of health problems, including:
(A) liver damage
(B) heart disease
(C) cancer
(D) all of the above
The legal limit for blood alcohol content (BAC) in the United States is:
(A) 0.08%
(B) 0.05%
(C) 0.02%
(D) 0.01%
If you are caught driving with a BAC of 0.08% or higher, you will likely be:
(A) arrested
(B) fined
(C) both arrested and fined
(D) none of the above
The best way to avoid the negative effects of alcohol is to:
(A) drink in moderation
(B) not drink at all
(C) drink only on special occasions
(D) all of the above
If you are concerned about your drinking, you should talk to your doctor.