CBSE Class 12 Chemistry Notes Chapter 11 Alcohols, Phenols and Ethers

These alcohol phenol and ethers class 12 notes provide a complete and simple explanation of Chapter 11 from CBSE Class 12 Chemistry. The chapter focuses on three major groups of organic compounds—alcohols, phenols, and ethers—their structures, preparation, properties, and important reactions. These alcohols phenols and ethers class 12 notes are designed to help students revise quickly and understand the logic behind each concept.

Alcohols are organic compounds containing one or more hydroxyl (–OH) groups attached to a carbon atom. Their classification (primary, secondary, tertiary) is explained clearly in these alcohol phenol ether class 12 notes. The notes also describe their physical properties influenced by hydrogen bonding, along with preparation methods such as hydration of alkenes, reduction processes, and Grignard reactions. Key chemical reactions like oxidation, dehydration, and substitution are also covered.

Phenols, which contain an –OH group attached directly to an aromatic ring, are more acidic than alcohols due to resonance stabilization. These alcohol phenol and ether notes class 12 highlight important reactions such as electrophilic substitution, Kolbe’s reaction, coupling reactions, and oxidation. Phenols are also important industrially in making antiseptics, dyes, plastics, and pharmaceuticals.

Ethers have the general structure R–O–R and show low reactivity, making them useful as solvents. The class 12 chemistry alcohols phenols and ethers notes explain their preparation through Williamson Ether Synthesis and dehydration of alcohols. Students also learn how ethers undergo cleavage with concentrated HI and HBr. These alcohol phenol and ether class 12 explanations help build strong conceptual clarity.

Overall, these alcohols phenols and ethers notes simplify the entire chapter with easy language, clear diagrams, and exam-focused points. Whether you are revising before tests or preparing for boards, these class 12 chemistry chapter alcohol phenol and ether notes serve as a complete and reliable study resource.

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CBSE Class 12 Chemistry Notes Chapter 11 Alcohols, Phenols and Ethers

Here we have provided CBSE Class 12 Chemistry Notes Chapter 11 Alcohols, Phenols and Ethers-

Introduction

Alcohols are organic compounds characterized by the presence of a hydroxyl group (-OH) attached to a saturated carbon atom. This category includes various types of carbon, such as alkyl, alkynyl, alkenyl, cycloalkyl, or benzyl. Enols, a related class, feature a hydroxyl group linked to an unsaturated carbon within a double bond. When the hydroxyl group is attached directly to a benzene ring, the compound is known as a phenol. Alcohols are versatile in both industrial and daily applications. For instance, ethanol is commonly used for polishing wooden furniture. Additionally, essential compounds like sugar, cotton, and paper contain hydroxyl groups. Phenols are significant in the production of polymers such as Bakelite and pharmaceuticals like aspirin. Ethers, another class of compounds, are primarily utilized as anesthetics and solvents. In alcohols, the hydroxyl group's oxygen is bonded to the carbon via a sigma bond, which results from the overlap of sp hybridized orbitals of carbon and oxygen. The structural aspects of alcohols, phenols, and ethers are illustrated in the following figure, highlighting their different bonding and structural features.

Classification of Alcohol Phenol and Ether

1. Alcohols

Alcohols are classified based on the number of hydroxyl groups (-OH) they contain, and the type of carbon atom to which the -OH group is attached:

Based on the Number of Hydroxyl Groups:

• Monohydric Alcohols : Contain one -OH group. Example: Ethanol (CH₃CH₂OH).
• Dihydric Alcohols : Contain two -OH groups. Example: Ethylene glycol (1,2-ethanediol).
• Trihydric Alcohols : Contain three -OH groups. Example: Glycerol (1,2,3-propanetriol).
• Polyhydric Alcohols : Contain more than three -OH groups. Example: Sorbitol.

Based on the Carbon Atom Bonded with the -OH Group:

• Primary Alcohols : The -OH group is attached to a carbon that is bonded to only one other carbon. Example: Ethanol.
• Secondary Alcohols : The -OH group is attached to a carbon bonded to two other carbons. Example: Isopropanol (2-propanol).
• Tertiary Alcohols : The -OH group is attached to a carbon bonded to three other carbons. Example: tert-Butanol.

Based on the Position Relative to Double Bonds or Rings:

• Allylic Alcohols : The -OH group is attached to a carbon adjacent to a C=C double bond. Example: 3-Buten-1-ol.
• Benzylic Alcohols : The -OH group is attached to a carbon directly bonded to a benzene ring. Example: Benzyl alcohol.

2. Phenols

Phenols are aromatic compounds where one or more hydroxyl groups are directly bonded to a benzene ring:

Based on the Number of Hydroxyl Groups:

• Monohydroxy Phenols : Contain one -OH group attached to the benzene ring. Example: Phenol (C₆H₅OH).
• Dihydroxy Phenols : Contain two -OH groups. They can be further classified based on the positions of -OH groups:
• Ortho- (o-) : Hydroxyl groups are adjacent. Example: Catechol.
• Meta- (m-) : Hydroxyl groups are separated by one carbon. Example: Resorcinol.
• Para- (p-) : Hydroxyl groups are opposite each other. Example: Hydroquinone.
• Trihydroxy Phenols : Contain three -OH groups. Example: Phloroglucinol.

3. Ethers

Ethers are characterized by an oxygen atom connected to two alkyl or aryl groups:

Based on the Nature of Substituents:

• Simple Ethers : Both substituents are the same or similar alkyl/aryl groups. Example: Dimethyl ether (CH₃OCH₃).
• Mixed Ethers : Contain different alkyl or aryl groups. Example: Ethyl methyl ether (CH₃OCH₂CH₃).
• Cyclic Ethers : The oxygen atom is part of a ring structure. Example: Tetrahydrofuran (THF).

Nomenclature and Preparation of Alcohols, Phenols, and Ethers

Nomenclature:

Alcohols:

• Common Name: Derived from the alkyl group followed by "alcohol." For example, CH₃OH is named methyl alcohol.
• IUPAC Name: Derived from the name of the parent alkane with the suffix ‘-ol.’ For example, CH₃OH is named methanol (from methane).
• Cyclic Alcohols: Named by prefixing "cyclo-" and considering the hydroxyl group attached to the first carbon. Example: Cyclohexanol.

Phenol:

• Common Name: Phenol is the common and IUPAC name for the simplest hydroxy derivative of benzene.
• Dihydroxy Benzene Derivatives: Named based on the positions of the hydroxyl groups on the benzene ring as 1,2- (ortho), 1,3- (meta), and 1,4- (para) benzenediol. Example: 1,2-Benzenediol is catechol.

Ethers:

• General Names: Derived from the names of the alkyl or aryl groups connected to the oxygen atom, listed in alphabetical order, followed by "ether." Example: CH₃OC₂H₅ is ethyl methyl ether.

Preparation:

Alcohols:

• Hydrolysis of Halides: Alkyl halides react with an aqueous alkali hydroxide to yield alcohols through nucleophilic substitution. Example: R-X + KOH → R-OH + KX.
• Hydration of Alkenes: Alcohols can be prepared directly by adding water in the presence of a catalyst or indirectly by adding sulfuric acid followed by hydrolysis. Example: CH₂=CH₂ + H₂O → CH₃CH₂OH.
• Reduction of Aldehydes and Ketones: Aldehydes and ketones are reduced using reducing agents like LiAlH₄ to form alcohols. Example: CH₃CHO + H₂ → CH₃CH₂OH.
• Reduction of Carboxylic Acids: Carboxylic acids are reduced with hydrogen to yield alcohols. Example: CH₃COOH + H₂ → CH₃CH₂OH.
• Hydroboration of Alkenes: Alkenes react with diborane to form alkyl boranes, which on oxidation yield alcohols, typically leading to anti-Markovnikov addition. Example: R-CH=CH₂ + BH₃ → R-CH(OH)-CH₃.
• Grignard Synthesis: Grignard reagents react with carbonyl compounds to form alcohols. For instance, formaldehyde gives primary alcohols, while ketones yield tertiary alcohols.

Phenols:

• From Sulfonic Acids: Sodium benzene sulfonate is fused with sodium hydroxide to produce sodium phenoxide, which is acidified to yield phenol. Example: C₆H₅SO₃Na + NaOH → C₆H₅ONa + Na₂SO₄; C₆H₅ONa + HCl → C₆H₅OH + NaCl.
• From Diazonium Salts: Diazonium salts hydrolyzed under steam or boiling sulfuric acid produce phenol. Example: C₆H₅-N₂⁺Cl⁻ + H₂O → C₆H₅OH + N₂ + HCl.
• From Cumene: Cumene (isopropylbenzene) is oxidized to cumene hydroperoxide, which is then reacted with acid to yield phenol and acetone. Example: C₆H₅-CH(CH₃)₂ + O₂ → C₆H₅-C(CH₃)₂-OOH → C₆H₅OH + (CH₃)₂CO.

Physical Properties and Chemical Reactions of Alcohols, Phenols, and Ethers

Physical Properties:

• Solubility: Alcohols and phenols are soluble in water due to the formation of hydrogen bonds between their -OH groups and water molecules. However, this solubility decreases as the size of the hydrophobic (non-polar) group increases. Consequently, alcohols and phenols generally have higher boiling points compared to similar molecular mass hydrocarbons, except for carboxylic acids. This is attributed to their polar and protic nature.

Chemical Reactions:

Reaction with Metals:

• Alcohols and phenols react with active metals such as sodium (Na), potassium (K), and aluminum (Al) to form corresponding alkoxides, phenoxides, and hydrogen gas. This reaction demonstrates their acidic properties, though they are less acidic than water.

Acidity of Alcohols:

• The acidity of alcohols is influenced by the polarity of the -OH bond. Electron-releasing groups increase the electron density on oxygen, decreasing the bond’s polarity and thereby reducing acidity. The general acidity order of alcohols is Primary > Secondary > Tertiary. Alcohols are weaker acids compared to water.

Acidity of Phenols:

• Phenols are more acidic than alcohols due to the stabilization of the phenoxide ion through resonance. Electron-withdrawing groups enhance phenol’s acidity by stabilizing the phenoxide ion, while electron-releasing groups decrease acidity by destabilizing it.

Esterification:

• Alcohols and phenols react with carboxylic acids, acid chlorides, and anhydrides to form esters. Esterification with carboxylic acids is typically conducted using concentrated sulfuric acid to facilitate the reaction.

Reaction with Hydrogen Halides:

• Alcohols react with hydrogen halides (HX) to produce alkyl halides and water. For example: CH₃OH + HCl → CH₃Cl + H₂O.

Reaction with PCl₃ and PCl₅:

• Alcohols react with phosphorus trichloride (PCl₃) and phosphorus pentachloride (PCl₅) to yield alkyl chlorides.
• For example: 3 ROH + PCl₃ → 3 RCl + H₃PO₃ and ROH + PCl₅ → RCl + HCl + POCl₃

Reaction with SOCl₂:

• Alcohols react with thionyl chloride (SOCl₂) to form alkyl chlorides, sulfur dioxide, and hydrochloric acid. For example: ROH + SOCl₂ → RCl + SO₂ + HCl.

Dehydration:

• Alcohols undergo dehydration (removal of water) to form alkenes when treated with protic acids such as concentrated sulfuric acid (H₂SO₄), phosphoric acid (H₃PO₄), or aluminum oxide (Al₂O₃).

Oxidation:

• Alcohols can be oxidized to aldehydes (oxidation state 0) and carboxylic acids (oxidation state +2) depending on the reagents used.

Reactions of Phenol:

Halogenation: Phenol reacts with bromine in non-polar solvents like chloroform or carbon disulfide at low temperatures to form monobromo phenols. In the presence of bromine water, phenol yields 2,4,6-tribromophenol as a white precipitate.

Nitration: Phenol reacts with dilute nitric acid at low temperatures to produce a mixture of ortho and para nitrophenols.

Reimer-Tiemann Reaction: Phenol reacts with chloroform and sodium hydroxide (NaOH) to form salicylaldehyde, with the -CHO group attached at the ortho position of the benzene ring.

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Benefits of Alcohols, Phenols, and Ethers Class 12 Notes

1. Quick and Easy Revision
   These Class 12 notes summarize all important concepts like structure, nomenclature, preparation, and reactions, making last-minute revision fast and effective.

2. Clear Understanding of Concepts
   Complex topics such as acidity of phenols, oxidation of alcohols, and ether cleavage are explained in simple steps, helping students build strong conceptual clarity.

3. Exam-Focused Content
   The notes highlight important reactions, mechanisms, and exceptions frequently asked in board exams, helping students score better in Class 12 Chemistry.

4. Time-Saving and Well-Organized
   Instead of reading the full chapter again, students can quickly go through these structured class 12 chemistry alcohols phenols and ethers notes to revise key points, tables, and reaction summaries.

5. Supports Numerical and Reaction-Based Questions
   Understanding trends in boiling points, acidity, reactivity, and mechanisms helps students solve related numerical and reaction-based questions easily.

6. Boosts Confidence Before Exams
   With all formulas, mechanisms, and key reactions in one place, students feel more confident while attempting the Organic Chemistry section.

7. Better Memory Retention
   Well-structured points, charts, and reaction flow make it easier to remember important concepts for a long time.

Read More: NCERT Solutions for Class 12 Chemistry Chapter 11 Alcohols, Phenols and Ethers

FAQs on Alcohols, Phenols, and Ethers Class 12

1. What are alcohols in Class 12 Chemistry?
Alcohols are organic compounds that contain one or more hydroxyl (–OH) groups attached to a saturated carbon atom. Their physical and chemical properties depend on hydrogen bonding and the structure of the carbon chain.

2. Why are phenols more acidic than alcohols?
Phenols are more acidic because the phenoxide ion formed after losing a proton is stabilized by resonance. Alcohols do not have such resonance stabilization, making them less acidic.

3. What is Williamson Ether Synthesis?
Williamson Ether Synthesis is a key method of preparing ethers. It involves the reaction of an alkoxide ion (RO–) with a primary alkyl halide (R–X), leading to the formation of an ether (R–O–R).

4. How do ethers react with strong acids like HI or HBr?
Ethers undergo cleavage when treated with concentrated HI or HBr. The oxygen atom is protonated, and the C–O bond breaks to form an alcohol and an alkyl halide or two alkyl halides depending on the structure.

5. What are the main differences between alcohols, phenols, and ethers?
Alcohols have –OH attached to a carbon atom, phenols have –OH attached to an aromatic ring, and ethers contain an oxygen atom bonded to two alkyl or aryl groups. Their properties, acidity, and reactivity differ due to these structural variations.