For JEE Main and NEET aspirants, Class 12 Chemistry Chapter 7 Alcohols, Phenols and Ethers is one of the highest-yield Organic blocks of the year, reliably contributing 3 to 4 percent of the JEE Main Chemistry paper and 2 to 3 NEET questions on named reactions alone. The 2026-27 NCERT retains all of Sections 7.1 to 7.6 in full, and this Collegedunia formula sheet collates every preparation route, named reaction, and acidity trend on a single revision page.
- CBSE Weightage: 4 to 6 marks
- JEE Main Weightage: 3 to 4 percent (3 to 4 questions per paper)
- NEET Weightage: 2 to 3 questions per year
This formula sheet is curated by subject experts, mapped to the 2026-27 new NCERT edition, and refined against the last five years of CBSE Board, JEE Main, and NEET papers.
The compact sheet that follows lists every reaction, mechanism cue, and acidity / boiling-point trend, with its NCERT section reference.
Also Check:
- Alcohols, Phenols and Ethers Class 12 Chemistry Notes
- Alcohols, Phenols and Ethers Class 12 Chemistry NCERT Solutions
- CBSE Class 12 Chemistry Syllabus 2026-27
Why Alcohols, Phenols and Ethers Matters in 12th Chemistry and Entrance Exams
The chapter is the launchpad for the rest of the organic block. Acidity of phenols vs alcohols, the SN1/SN2 ladder revisited for dehydration, and the named reactions of phenol carry directly into Chapters 8 (Aldehydes, Ketones, Carboxylic Acids) and 9 (Amines). Phenol-based named reactions appeared in 4 of the last 5 NEET papers and in every JEE Main session since 2022. Students who lock in the Reimer-Tiemann, Kolbe, and Williamson syntheses score the easy 2-mark items every year.
Alcohols Phenols and Ethers Video Walkthrough
Source: Magnet Brains on YouTube
How will Collegedunia's Alcohols, Phenols and Ethers Formula Sheet Help You?
The sheet is built for a 25 to 30 minute final revision pass on the night before a Chemistry paper.
- 2026-27 NCERT Alignment: Every reaction, named reaction, and acidity trend matches the current syllabus print of Sections 7.1 to 7.6.
- One-Page Printability: The master table fits on a single A4 landscape sheet.
- Named-Reaction Tagging: Each preparation is tagged Williamson, Reimer-Tiemann, Kolbe, or oxidation-route, with the catalyst and product clearly listed.
- Expert Verification: Cross-checked against NCERT Sections 7.1 to 7.6 and the last five JEE Main and NEET papers.
Alcohols, Phenols and Ethers Symbol and Notation Glossary
Three of the most common 1-mark slips on this chapter come from mixing primary / secondary / tertiary alcohol notation. The glossary below locks in every symbol used in the master table.
| Symbol | Meaning | Typical Unit / Note |
|---|---|---|
| R-OH | Generic alcohol (OH on sp3 C) | - |
| Ar-OH | Phenol (OH on sp2 aromatic C) | - |
| R-O-R' | Generic ether (O bonded to two C atoms) | R = R' is symmetrical; R ≠ R' is unsymmetrical |
| 1° / 2° / 3° R-OH | Alcohol class by C bearing OH | -CH2OH / >CH-OH / >C(R)-OH |
| RO- | Alkoxide ion (conjugate base of R-OH) | Strong base |
| ArO- | Phenoxide ion (conjugate base of Ar-OH) | Resonance-stabilised |
| pKa | Acidic strength index (lower pKa = stronger acid) | R-OH ~ 16, Ar-OH ~ 10 |
| ΔvapH | Enthalpy of vaporisation | kJ mol-1; raised by H-bonding |
| RMgX | Grignard reagent (R-MgX, X = Cl, Br, I) | Source of R- carbanion |
| LiAlH4 | Strong hydride reducing agent | Reduces -COOH, -CHO, -COR to R-OH |
| conc. H2SO4, Δ | Acid-catalysed dehydration / etherification | 443 K → alkene; 413 K → ether |
Alcohols, Phenols and Ethers All Important Formulae and Reactions for Class 12 Chemistry
The canonical master table below lists every working formula, named reaction, and quantitative trend in NCERT Chapter 7, with reagents, conditions, section reference, and the typical exam-use cue. All entries below are retained in the 2026-27 syllabus.
| Concept / Reaction | Formula / Equation | Conditions | NCERT Ref | Common Use |
|---|---|---|---|---|
| Monohydric alcohol general formula | CnH2n+1OH | - | 7.1 | Saturated, one -OH |
| Phenol structure | C6H5-OH | - | 7.1 | -OH on aromatic ring |
| Ether general formula | R-O-R' | - | 7.1 | Two C-O single bonds at O |
| Alcohol from alkene (acid hydration) | CH2=CH2 + H2O H+ CH3CH2OH | dil. H2SO4 | 7.3 | Markovnikov addition |
| Alcohol from alkene (hydroboration-oxidation) | 3 R-CH=CH2 + (BH3)2 → (R-CH2-CH2)3B H2O2/OH- R-CH2-CH2OH | diborane then alkaline H2O2 | 7.3 | anti-Markovnikov, syn-addition |
| Alcohol from aldehyde (reduction) | R-CHO + 2[H] Ni/Pt/Pd or LiAlH4 R-CH2-OH | catalytic H2 or hydride | 7.3 | Gives 1° alcohol |
| Alcohol from ketone (reduction) | R-CO-R' + 2[H] Ni/Pt/Pd or LiAlH4 R-CHOH-R' | catalytic H2 or hydride | 7.3 | Gives 2° alcohol |
| Alcohol from carboxylic acid | R-COOH LiAlH4 or B2H6 R-CH2-OH | LiAlH4 (expensive); B2H6 preferred | 7.3 | Reduces ester > acid (B2H6) |
| Alcohol via Grignard reagent | R-MgX + R'-CHO dry ether R'-CHR-OMgX H2O R'-CHR-OH | dry ether; aqueous work-up | 7.3 | HCHO → 1°; RCHO → 2°; ketone → 3° |
| Phenol from chlorobenzene (Dow) | C6H5-Cl + NaOH 623K, 320 atm C6H5-OH + NaCl | high T, high P | 7.3 | Industrial scale |
| Phenol from benzene sulphonic acid | C6H5-SO3H NaOH fusion, then H+ C6H5-OH | molten NaOH then acidification | 7.3 | Goes via sodium phenoxide |
| Phenol from diazonium salt | C6H5-N2+Cl- + H2O warm C6H5-OH + N2 + HCl | aqueous, warm | 7.3 | From aniline route |
| Phenol from cumene | C6H5-CH(CH3)2 O2 then H+ C6H5-OH + (CH3)2C=O | O2 then dil. acid | 7.3 | Major industrial route (by-product acetone) |
| Boiling point trend (R-OH vs R-O-R' vs R-X) | R-OH ≫ R-O-R' > R-X (same M) | - | 7.2 | H-bonding only in R-OH |
| Solubility in water | Decreases as alkyl chain grows | - | 7.2 | CH3OH miscible; C6H13OH sparingly soluble |
| Acidity (R-OH) | R-OH R-O- + H+ | pKa ~ 16 | 7.4 | Weaker acid than water |
| Acidity (Ar-OH) | Ar-OH Ar-O- + H+ | pKa ~ 10 | 7.4 | ~106x more acidic than R-OH |
| Acidity order of alcohols | 1∘ > 2∘ > 3∘ (in water) | - | 7.4 | +I effect of alkyl reduces acidity |
| R-OH with Na | 2R-OH + 2Na → 2R-O-Na+ + H2 ↑ | cold, neat | 7.4 | Test for -OH (H2 evolution) |
| Ar-OH with NaOH | Ar-OH + NaOH → Ar-O-Na+ + H2O | aqueous | 7.4 | Phenol dissolves in alkali (alcohols don't) |
| Esterification of R-OH | R-OH + R'COOH R'COOR + H2O | conc. H2SO4, Δ | 7.4 | Reversible; remove H2O to drive |
| Esterification of Ar-OH | Ar-OH + R'COCl base R'COO-Ar + HCl | Schotten-Baumann (pyridine / NaOH) | 7.4 | Acid chloride used (Ar-OH less nucleophilic) |
| R-OH + HX | R-OH + HX → R-X + H2O | HCl needs ZnCl2 (Lucas test) | 7.4 | 3° > 2° > 1° reactivity |
| R-OH + PX3 | 3R-OH + PX3 → 3R-X + H3PO3 | X = Cl, Br | 7.4 | Standard lab prep |
| R-OH + SOCl2 | R-OH + SOCl2 → R-Cl + SO2 ↑ + HCl ↑ | - | 7.4 | By-products escape as gases |
| Dehydration to alkene (intramolecular) | R-CH2-CH2-OH conc. H2SO4, 443K R-CH=CH2 + H2O | conc. H2SO4, 443 K (170 °C) | 7.4 | Saytzeff product |
| Dehydration to ether (intermolecular) | 2R-OH conc. H2SO4, 413K R-O-R + H2O | conc. H2SO4, 413 K (140 °C) | 7.4 / 7.6 | Williamson alternative for symmetrical ethers |
| Oxidation 1° R-OH (mild) | R-CH2-OH PCC R-CHO | PCC in CH2Cl2 | 7.4 | Stops at aldehyde |
| Oxidation 1° R-OH (vigorous) | R-CH2-OH KMnO4/K2Cr2O7 R-COOH | acidic / alkaline KMnO4, Δ | 7.4 | Goes through R-CHO to R-COOH |
| Oxidation 2° R-OH | R-CHOH-R' KMnO4 / Na2Cr2O7 R-CO-R' | oxidising agent + Δ | 7.4 | Gives ketone (no further oxidation easily) |
| Dehydrogenation of R-OH | R-CH2-OH Cu, 573K R-CHO + H2 | Cu catalyst, 573 K | 7.4 | 3° R-OH gives alkene (no α-H) |
| Iodoform test | R-CHOH-CH3 + 4I2 + 6NaOH → CHI3 ↓ + R-COO-Na+ + 5NaI + 5H2O | aq. NaOH + I2 | 7.4 | Yellow ppt; identifies CH3-CHOH- group |
| Phenol electrophilic substitution | C6H5-OH E+ o- and p-substituted product | activated by -OH (+M) | 7.5 | o- and p- directing |
| Bromination (water) | C6H5-OH + 3Br2 H2O 2,4,6-tribromophenol ↓ + 3HBr | aq. Br2, white ppt | 7.5 | No catalyst; very fast (test for phenol) |
| Bromination (CS2, low T) | C6H5-OH + Br2 CS2, low T o- and p-bromophenol | polar solvent suppresses ionisation | 7.5 | Mono-substituted product |
| Nitration (dil HNO3) | C6H5-OH + HNO3 dil, low T o- and p-nitrophenol | low T, dilute acid | 7.5 | o-isomer steam-volatile (intramolecular H-bond) |
| Nitration (conc. HNO3) | C6H5-OH + 3HNO3 → 2,4,6-trinitrophenol (picric acid) + 3H2O | conc. HNO3 + H2SO4 | 7.5 | Picric acid is a strong acid |
| Kolbe's reaction | C6H5-O-Na+ + CO2 400K, 4-7 atm sodium salicylate H+ salicylic acid | moderate T, P | 7.5 | Electrophilic at o- position |
| Reimer-Tiemann reaction | C6H5-OH + CHCl3 + NaOH → salicylaldehyde (o-CHO) | aq. NaOH, Δ | 7.5 | -CHO at o- to -OH |
| Oxidation of phenol | C6H5-OH Na2Cr2O7/H+ benzoquinone (yellow) | chromic acid | 7.5 | Different product from alcohols |
| Williamson ether synthesis | R-O-Na+ + R'-X Δ R-O-R' + NaX | SN2; R'-X should be 1° | 7.6 | Best for unsymmetrical ethers |
| Williamson failure mode | R-O-Na+ + 3∘ R'-X → alkene (E2) | 3° substrate gives elimination | 7.6 | Use 1° halide + bulkier alkoxide |
| Ether by alcohol dehydration | 2R-OH H2SO4, 413K R-O-R + H2O | SN2, only for symmetrical 1° ethers | 7.6 | Fails for 2° / 3° R-OH |
| Ether cleavage with HI | R-O-R + HI → R-I + R-OH; then R-OH + HI → R-I + H2O | excess HI, Δ | 7.6 | Both alkyl groups become R-I |
| Ether cleavage (anisole) | C6H5-O-CH3 + HI → C6H5-OH + CH3I | excess HI | 7.6 | I- attacks at -CH3, NOT aryl C |
| Friedel-Crafts on anisole | C6H5-O-CH3 + RCOCl AlCl3 p-acyl-anisole (major) | AlCl3, anhydrous | 7.6 | -OCH3 is o-, p-directing (+M) |
Use the temperature lever as the single anchor for dehydration questions: conc. H2SO4 at 413 K gives ether; at 443 K it gives alkene. The same reagent yields different products purely on the temperature you set, and CBSE has tested this in 3 of the last 5 board papers. Mixing up 413 K and 443 K is the most common 1-mark slip on Chapter 7.
Acidity and Boiling Point Reference Table for Alcohols, Phenols and Ethers
The two trends below power most of the 1-mark MCQs on this chapter. JEE Main has asked at least one acidity-ranking question every year since 2021.
| Compound | Structure | pKa | Boiling Point | Key Note |
|---|---|---|---|---|
| Ethanol | CH3CH2-OH | ~ 16 | 351 K | Reference 1° alcohol |
| Isopropanol | (CH3)2CH-OH | ~ 17 | 355 K | 2° alcohol; +I effect lowers acidity |
| tert-Butanol | (CH3)3C-OH | ~ 19 | 356 K | 3° alcohol; weakest acid in the alcohol set |
| Phenol | C6H5-OH | ~ 10 | 455 K | 106x more acidic than ethanol |
| p-Nitrophenol | p-O2N-C6H4-OH | ~ 7.2 | - | -NO2 (-M) increases acidity |
| 2,4,6-Trinitrophenol (picric acid) | (O2N)3-C6H2-OH | ~ 0.4 | - | Stronger than acetic acid |
| p-Cresol | p-CH3-C6H4-OH | ~ 10.3 | - | -CH3 (+I) decreases acidity slightly |
| Diethyl ether | CH3CH2-O-CH2CH3 | - | 308 K | No H-bonding (no O-H), so b.p. low |
Alcohols, Phenols and Ethers Quick-Fact Cards for MCQ Recall
The four facts below are the ones JEE Main and NEET rotate as 1-mark MCQs. Memorise them in this exact form.
Alcohols, Phenols and Ethers Common-Numerical Pattern Templates for 12th Chemistry
The four problem setups below have dominated CBSE, JEE Main, and NEET papers since 2021.
| Pattern | What the question gives | Formula / Rule to apply | Common trap |
|---|---|---|---|
| Acidity ranking | List of substituted phenols and alcohols | EWG (NO2, X) raises acidity; EDG (R, OR) lowers it; Ar-OH always > R-OH | Forgetting that 3° R-OH is the weakest acid in the alcohol set |
| Dehydration product | R-OH + acid + temperature | 413 K → ether (SN2 between two ROH); 443 K → alkene (E1, Saytzeff) | Reading 413 as 443 or vice versa; reversing alkene / ether outcome |
| Williamson product | R-O- + R'-X | Pick the 1° R'-X side; the bulkier alkyl goes on R-O- | Using 3° R'-X, which gives alkene (E2), not ether |
| Grignard product | R-MgX + carbonyl (HCHO / RCHO / R2CO) | HCHO → 1° R-OH; RCHO → 2° R-OH; ketone → 3° R-OH | Forgetting the aqueous work-up step (H2O / dil. acid) |
Top 3 Most-Asked Alcohols, Phenols and Ethers PYQ Topics in CBSE, JEE and NEET
The three patterns below have repeated most often since 2021. The full year-by-year map sits on the Collegedunia NCERT Solutions page.
| Topic | Frequency (CBSE + JEE + NEET, 2026 to 2021) | Typical mark band |
|---|---|---|
| Acidity of phenol / substituent effect ordering | 13 times | 1 to 3 marks |
| Named reactions (Williamson, Reimer-Tiemann, Kolbe, cumene) | 11 times | 2 to 3 marks |
| Mechanism of acid-catalysed dehydration / Markovnikov vs anti-Markovnikov | 8 times | 2 to 3 marks |
Full year-wise PYQ map: Alcohols, Phenols and Ethers Class 12 Chemistry NCERT Solutions
One-Shot Revision Tips for Class 12th Chemistry Alcohols, Phenols and Ethers
- Lucas test order: 3° R-OH turbid in < 1 minute, 2° in 5 to 10 minutes, 1° only on heating. Conc. HCl + ZnCl2 is the reagent.
- Iodoform test (CH3-CHOH-R only): ethanol, propan-2-ol, butan-2-ol give yellow CHI3. Methanol and propan-1-ol do NOT.
- Phenol does not give ester with carboxylic acid easily; use acid chloride or anhydride (Schotten-Baumann). Reason: Ar-OH is a poorer nucleophile because the lone pair on O is partly delocalised into the ring.
- Ether cleavage with HI selectivity: if one R group is 3° or allylic, it leaves as the carbocation (SN1); else the smaller group is attacked (SN2). For anisole, only -CH3 is attacked because aryl C-O is too strong.
- Friedel-Crafts on phenol: works but gives poor yields; -OH may coordinate the AlCl3. Anisole (C6H5-OCH3) reacts cleanly because -OCH3 can't deactivate the catalyst.
Alcohols, Phenols and Ethers Weightage Compared Across Class 12 Chemistry Chapters
Typical CBSE marks distribution across the 10 chapters of the 2026-27 NCERT, averaged over the last five board papers. Alcohols, Phenols and Ethers sits in the mid tier, equal to the d- and f-Block Elements and slightly above Haloalkanes and Haloarenes in board-paper weight.
Related Links:
- Haloalkanes and Haloarenes Class 12 Chemistry Formula Sheet (Previous Chapter)
- Aldehydes, Ketones and Carboxylic Acids Class 12 Chemistry Formula Sheet (Next Chapter)
More Alcohols, Phenols and Ethers Chemistry Class 12 Resources
- Alcohols, Phenols and Ethers Class 12 Chemistry NCERT Solutions
- Alcohols, Phenols and Ethers Class 12 Chemistry Notes
- Alcohols, Phenols and Ethers Class 12 Chemistry NCERT Book PDF
- Alcohols, Phenols and Ethers Class 12 Chemistry NCERT Exemplar Book PDF
- Alcohols, Phenols and Ethers Class 12 Chemistry NCERT Exemplar Solutions
- Alcohols, Phenols and Ethers Class 12 Chemistry Handwritten Notes
NCERT Formula Sheet for Class 12 Chemistry: All Chapters
Jump to the formula sheet for any other chapter of Class 12 Chemistry below.
| Chapter | Resource |
|---|---|
| Chapter 1 | Solutions Formula Sheet |
| Chapter 2 | Electrochemistry Formula Sheet |
| Chapter 3 | Chemical Kinetics Formula Sheet |
| Chapter 4 | d- and f-Block Elements Formula Sheet |
| Chapter 5 | Coordination Compounds Formula Sheet |
| Chapter 6 | Haloalkanes and Haloarenes Formula Sheet |
| Chapter 8 | Aldehydes, Ketones and Carboxylic Acids Formula Sheet |
| Chapter 9 | Amines Formula Sheet |
| Chapter 10 | Biomolecules Formula Sheet |
Alcohols, Phenols and Ethers Class 12 Chemistry Formula Sheet FAQs
Ques. Where can I download the Alcohols, Phenols and Ethers Class 12 Chemistry Formula Sheet PDF?
Ans. You can download the Alcohols, Phenols and Ethers Class 12 Chemistry Formula Sheet PDF directly from this Collegedunia page. Both the Normal and HD versions are available and free of cost.
Ques. Is this Formula Sheet aligned with the 2026-27 NCERT?
Ans. Yes. This page reflects the current 2026-27 syllabus for Class 12 Chemistry. Alcohols, Phenols and Ethers is fully retained in the new edition with no formula cuts; every relation in Sections 7.1 to 7.6 of the NCERT remains examinable.
Ques. How many pages is the Class 12th Chemistry Alcohols, Phenols and Ethers Formula Sheet PDF?
Ans. The Formula Sheet PDF runs approximately 8 to 9 pages and covers the master reaction table, symbol glossary, acidity / boiling-point reference, quick-fact MCQ cards, and four common numerical pattern templates.
Ques. Why is phenol more acidic than ethanol?
Ans. The phenoxide ion (C6H5-O-) is stabilised by resonance: the negative charge is delocalised onto the ortho and para carbons of the benzene ring, spreading it over multiple atoms. The ethoxide ion has no such delocalisation, so the negative charge stays fully on one oxygen. The resonance-stabilised phenoxide is roughly 106 times more stable than ethoxide, which is why phenol has pKa 10 and ethanol pKa 16.
Ques. What products are formed when ethanol is heated with conc. H2SO4 at 413 K and 443 K?
Ans. At 413 K (140 °C), conc. H2SO4 catalyses intermolecular dehydration of ethanol to give diethyl ether: 2 C2H5-OH → C2H5-O-C2H5 + H2O. At 443 K (170 °C), the same acid catalyses intramolecular dehydration to give ethene: C2H5-OH → C2H4 + H2O. The temperature is the only variable that flips the outcome.
Ques. What is the Williamson ether synthesis and when does it fail?
Ans. Williamson synthesis is the SN2 reaction of a sodium alkoxide with an alkyl halide: R-O-Na+ + R'-X → R-O-R' + NaX. It is the standard route for unsymmetrical ethers. It fails when R'-X is a tertiary (3°) halide because steric crowding pushes the reaction to E2 elimination, giving an alkene instead. The fix is to choose the 1° halide as R'-X and put the bulkier group on the alkoxide.
Ques. Why does anisole + HI give phenol and methyl iodide, not iodobenzene and methanol?
Ans. When anisole (C6H5-O-CH3) reacts with HI, the I- nucleophile attacks the methyl carbon (SN2 at sp3 C), not the aryl carbon (sp2, locked in the aromatic ring). The aryl C-O bond has partial double-bond character from lone-pair donation into the ring, making it too strong to cleave. The products are therefore C6H5-OH (phenol) + CH3-I (methyl iodide).
Ques. What is the Reimer-Tiemann reaction and what product does it give?
Ans. The Reimer-Tiemann reaction treats phenol with chloroform (CHCl3) in the presence of aqueous NaOH to introduce a -CHO group at the ortho position of the ring, giving salicylaldehyde (2-hydroxybenzaldehyde). Mechanism: NaOH deprotonates CHCl3 to dichlorocarbene (:CCl2), which attacks the activated phenoxide at the ortho carbon; subsequent hydrolysis of -CCl2H gives -CHO. The reaction is examinable in both CBSE and JEE Main.
Ques. What is the Kolbe reaction for preparing salicylic acid from phenol?
Ans. Sodium phenoxide is heated with CO2 at 400 K and 4 to 7 atm; the carboxylate intermediate is acidified to give salicylic acid (2-hydroxybenzoic acid). The mechanism involves electrophilic attack of CO2 on the activated ortho carbon of the phenoxide. The Kolbe reaction is the industrial route to salicylic acid, the precursor of aspirin.
Ques. What are the cumene process and Dow process for preparing phenol?
Ans. The cumene process oxidises cumene (isopropylbenzene) with atmospheric O2 to cumene hydroperoxide, then acidifies to give phenol and acetone (valuable co-product). The Dow process hydrolyses chlorobenzene with NaOH at 623 K and 320 atm to give phenol. Cumene is the dominant industrial route today because acetone offsets the cost.
Ques. How is picric acid (2,4,6-trinitrophenol) prepared from phenol?
Ans. Picric acid is prepared by stepwise nitration of phenol: dilute HNO3 gives ortho/para-nitrophenol; more concentrated HNO3 gives 2,4-dinitrophenol; final nitration with conc. HNO3 + H2SO4 gives picric acid (pKa 0.4), stronger than acetic acid. Three -NO2 groups stabilise the conjugate base by resonance and -I effects.
Ques. What is hydroboration-oxidation, and how does it give the anti-Markovnikov alcohol?
Ans. Hydroboration-oxidation uses B2H6 in THF followed by alkaline H2O2 on an alkene. The boron attaches to the less-substituted carbon (anti-Markovnikov), and oxidation replaces it with -OH without rearrangement. The reaction is concerted and syn-additive, so no carbocation forms and no Wagner-Meerwein rearrangement is possible. This makes it CBSE's preferred 3-mark answer when the question demands a rearrangement-free preparation.
Ques. How does PCC differ from KMnO4 when oxidising a primary alcohol?
Ans. PCC (pyridinium chlorochromate) in dichloromethane is a mild oxidant that stops at R-CHO; KMnO4 is a strong aqueous oxidant that overshoots to R-COOH because the aldehyde hydrates in water and is oxidised further. For secondary alcohols, both reagents give the ketone (no further oxidation easily). Tertiary alcohols resist both because there is no alpha-H.
Ques. What is the Saytzeff rule for the acid-catalysed dehydration of alcohols?
Ans. Saytzeff's rule says that in an E1 dehydration, the more-substituted (more stable) alkene is the major product. 2-Methylbutan-2-ol with conc. H2SO4 at 443 K gives 2-methylbut-2-ene (trisubstituted) as the major product over 2-methylbut-1-ene (disubstituted). Alkene stability follows hyperconjugation: more alpha-H atoms mean more hyperconjugative stabilisation.
Ques. Why does bromination of phenol with Br2 water give 2,4,6-tribromophenol while Br2/CS2 at low temperature gives mono-substituted product?
Ans. In water, the phenol partially ionises to phenoxide, which is much more activated than phenol itself; the highly activated ring undergoes triple electrophilic substitution at the 2, 4 and 6 positions to give 2,4,6-tribromophenol (white precipitate) very fast. In CS2 (a non-polar solvent) at low temperature, ionisation is suppressed and the reaction stops at the mono-bromo stage, giving a mixture of o- and p-bromophenol.
Ques. What is the Lucas test, and how does it distinguish 1°, 2°, and 3° alcohols?
Ans. The Lucas test mixes the alcohol with Lucas reagent (concentrated HCl + anhydrous ZnCl2) at room temperature. Tertiary alcohols give immediate turbidity because the 3° carbocation forms fast; secondary alcohols give turbidity in 5 to 10 minutes; primary alcohols give no turbidity at room temperature and need heating. The Lucas test is the standard CBSE / JEE Main / NEET distinction question for the chapter.
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