Organic GOC & Hydrocarbons - NEET 2026

General Organic Chemistry & Hydrocarbons

Master inductive, mesomeric, and hyperconjugation effects. Reaction mechanisms follow predictable patterns.

Electronic Effects

Inductive effect (I): Permanent polarity along σ-bonds due to electronegativity difference. Electron-withdrawing groups (-I): -F, -Cl, -Br, -I, -NO₂, -CN, -COOH, -OH, -OR (halogens, electronegative atoms). Electron-donating groups (+I): alkyl groups (CH₃ > C₂H₅ > n-C₃H₇...).

Mesomeric/Resonance effect (M): Delocalization through π bonds or lone pairs. -M groups (withdraw electrons by resonance): -NO₂, -CHO, -COOH, -CN, -COR. +M groups (donate electrons by resonance): -OH, -OR, -NH₂, -NR₂, -halogens (lone pairs into ring).

Hyperconjugation: Delocalization involving C-H σ bonds adjacent to π bond or carbocation. No H, no hyperconjugation. Stability of alkenes: greater substitution = more hyperconjugation = more stable. Carbocation stability: 3° > 2° > 1° (due to hyperconjugation + inductive effect).

Reaction Mechanisms

Electrophilic Addition (EA): Unsaturated compounds (alkenes, alkynes). Electrophile attacks π-rich double bond. Markovnikov's rule: H adds to C with more H already (positive charge on more substituted C). HBr + alkene → anti-Markovnikov with peroxide (free radical mechanism — Kharash effect).

Electrophilic Aromatic Substitution (EAS): Benzene reactions. Mechanism: electrophile attacks → σ complex (arenium ion, Wheland intermediate) → loss of H⁺ → restored aromaticity.

Nucleophilic Substitution: SN2 (inversion of configuration — Walden inversion, one step, 2nd order, prefers primary), SN1 (carbocation intermediate, two steps, 1st order, racemisation, prefers tertiary).

Hydrocarbons

Alkanes: Free radical substitution. Cl₂ in UV light. Reactivity: F₂ > Cl₂ > Br₂ > I₂. Cl₂ is most useful for selective halogenation.

Alkenes: Electrophilic addition. Ozonolysis (O₃ → O₃ complex → cleave with Zn/H₂O → aldehydes/ketones). Hydroxylation with cold KMnO₄ (Baeyer's reagent, turns from purple → colourless = positive test for unsaturation).

Alkynes: More reactive than alkenes toward nucleophiles (linear molecule, exposed π). Acidic H on terminal alkyne (pKa ~25) — forms acetylides with NaNH₂ or Na. Used in Lindlar hydrogenation (cis-alkene) vs Na/liquid NH₃ (trans-alkene).

Benzene: Delocalized π electrons (6 electrons in ring). Resonance energy = 150 kJ/mol (Kekulé structures). Prefers EAS over EA to preserve aromaticity.

Named Reactions (NEET Tested)

Wurtz reaction: 2RX + 2Na → R-R + 2NaX. Couples two alkyl halides. Only alkanes with even carbon number from same halide.

Sandmeyer reaction: ArN₂⁺ + CuCl/CuBr/CuCN → ArCl/ArBr/ArCN + N₂. Converts diazonium salt to aryl halide.

Friedel-Crafts reactions: Alkylation (AlCl₃ + RX → R-Ar), Acylation (AlCl₃ + RCOCl → RCO-Ar). Cannot use on deactivated rings (NO₂, SO₃H groups).

Ozonolysis: Alkene + O₃ → ozonide → Zn/H₂O → carbonyl compounds. Products identify the structure of the original alkene.

Organic Chemistry Facts

Inductive Effect Groups

-I (withdraw): F > Cl > Br > I > OH > OR > NH₂
+I (donate): C(CH₃)₃ > CH(CH₃)₂ > C₂H₅ > CH₃
Acidity increases with -I groups
Basicity increases with +I groups

Acidity of carboxylic acids: HCOOH > CH₃COOH (formic more acidic — no alkyl group)

Carbocation Stability

3° > 2° > 1° > methyl
Allylic ≈ 3° carbocation (resonance)
Benzylic carbocation: very stable
Vinyl carbocation: very unstable
Phenyl carbocation: very unstable

Allylic and benzylic carbocations are stabilised by resonance — treat them as special cases

SN1 vs SN2

SN1: 3° substrate, polar protic solvent, racemisation, unimolecular
SN2: 1° substrate, polar aprotic, inversion (Walden), bimolecular
Strong Nu: favours SN2
Polar protic solvent: favours SN1

DMSO and acetone are polar aprotic — stabilise nucleophile, favour SN2

Baeyer's Reagent

Cold KMnO₄ (Baeyer's reagent)
Purple → colourless = alkene/alkyne present
Product: diol (cis-dihydroxylation)
Hot KMnO₄: cleaves double bond
Ozonolysis: O₃ then Zn/H₂O

Baeyer's reagent is a TEST for unsaturation — qualitative, not quantitative

Worked Examples

EasyArrange the following carboxylic acids in order of increasing acidity: CH₃COOH, HCOOH, CCl₃COOH, CF₃COOH▾

Acidity of carboxylic acids increases with more electron-withdrawing groups stabilising the carboxylate anion. CF₃ is strongest -I (F most electronegative). CCl₃ is strong but less than CF₃. CH₃ is +I (decreases acidity). HCOOH has no alkyl group at all.

Answer: CH₃COOH < HCOOH < CCl₃COOH < CF₃COOH (increasing acidity)

MediumWhich product forms when propene reacts with HBr in the presence of peroxide?▾

Without peroxide → Markovnikov → 2-bromopropane (major). With peroxide (free radical mechanism / Kharash effect / anti-Markovnikov addition): Br adds to the LESS substituted carbon (terminal C). Product: 1-bromopropane.

Answer: 1-bromopropane (anti-Markovnikov product)

Mistake DNA

❌ Applying Markovnikov's rule when peroxide is present

Peroxide (ROOR) initiates FREE RADICAL mechanism. In free radical addition of HBr, Br (not H) adds to the more substituted carbon. This gives ANTI-Markovnikov product. Markovnikov's rule applies ONLY to ionic mechanism.

Fix: HBr + alkene + peroxide → anti-Markovnikov. No peroxide → Markovnikov. HCl and HI don't show anti-Markovnikov even with peroxide.

❌ Saying halogens have +M effect in electron-withdrawing context

Halogens have DUAL effect: -I (electron-withdrawing by induction) AND +M (electron-donating by mesomeric/resonance via lone pairs). Net effect on benzene ring: halogens are deactivating (-I wins) but ortho-para directing (+M wins for directing).

Fix: Halogens on benzene: deactivating but ortho-para directors. Both effects coexist.

Chapter Intelligence

PYQ Frequency

Electronic effects/acidity order: 2 Q/year
Named reactions: 1 Q/year
Reaction mechanism: 1 Q/year

2026 Prediction

High: Acidity/basicity order question
Expected: SN1 vs SN2 condition
Watch: Ozonolysis product identification

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