Aldol Condensation Base Heat

Aldol Reactions: Addition vs. Condensation (Base-Catalyzed)

Aldol reactions are base-catalyzed carbonyl reactions that form a new C–C bond via an enolate. For most college organic chemistry problems, the key is conditions: cold/dilute base stops at the β-hydroxy carbonyl (aldol addition), while heat (Δ) drives dehydration to the α,β-unsaturated carbonyl (aldol condensation, E1cb).

Quick Summary

NaOH, cold/dilute → aldol addition → β-hydroxy carbonyl
NaOH, heat (Δ) → aldol condensation → α,β-unsaturated carbonyl (dehydration via E1cb)

Conditions at a Glance

Conditions	Product
NaOH (dilute), cold	β-Hydroxy carbonyl (aldol addition)
NaOH, Δ (heat)	α,β-Unsaturated carbonyl (aldol condensation)

Mechanism

Mechanism overview

Aldol Addition (Steps 1–3)

Step 1: Form the enolate

Base removes an α‑H to give an enolate (the nucleophile).

Aldol reaction step 1: enolate formation

Step 2: Make the C–C bond

The enolate attacks a carbonyl to give an alkoxide (new C–C bond).

Aldol reaction step 2: carbon-carbon bond formation

Step 3: Protonate

Protonation gives the β-hydroxy carbonyl (aldol addition product).

Aldol reaction step 3: protonation to form the beta-hydroxy carbonyl

If the problem says cold/dilute base, stop after Step 3 (aldol addition).

Aldol Condensation (Steps 4–5)

If the problem shows heat (Δ), dehydration continues to the condensation product:

Step 4: Deprotonate (E1cb)

Base removes an α‑H again to set up elimination.

Aldol condensation step 4: deprotonation (E1cb)

Step 5: Eliminate (dehydration)

Elimination gives the α,β-unsaturated carbonyl (conjugated product).

Aldol condensation step 5: E1cb dehydration to alpha,beta-unsaturated carbonyl

Worked Examples

Example A: Self-Aldol Condensation

2 eq

→

Acetaldehyde self-condensation → crotonaldehyde

Example B: Crossed Aldol (Claisen–Schmidt)

Benzaldehyde has no α‑hydrogens, so it can’t form an enolate (electrophile only).

Enolate

Electrophile

→

Acetaldehyde + Benzaldehyde → cinnamaldehyde

Example C: Intramolecular Aldol (Ring Formation)

Intramolecular aldol cyclizations usually favor 5‑ and 6‑membered rings.

→

2,5-hexanedione → 3-methylcyclopent-2-enone (5-membered ring)

Exam Quick Reference

Clue in Problem	Product
"NaOH, cold" or "dilute"	β-Hydroxy carbonyl (addition)
"NaOH, Δ" or "heat"	α,β-Unsaturated carbonyl (condensation)
Benzaldehyde + ketone	Crossed aldol (benzaldehyde = electrophile only)
Dicarbonyl + base	Intramolecular → ring

Key points:

Heat drives dehydration (E1cb elimination)
Conjugated product is usually (E) (trans)
Self-condensation doubles carbons minus H₂O

Interactive Toolbox

Use NaOH (cold/dilute) to stop at the β-hydroxy carbonyl (aldol addition).

Add heat (Δ) to drive dehydration to the α,β-unsaturated carbonyl (aldol condensation).

Mechanism Solver — step through aldol addition/condensation with electron-pushing arrows.
Reaction Solver — draw a carbonyl and predict the aldol product under cold vs heat conditions.
IUPAC Namer — name the β-hydroxy carbonyl or α,β-unsaturated carbonyl product.

Study Tools