How do you determine if a reaction is SN1 or SN2?

The key factors are substrate class, nucleophile strength, and solvent. Primary substrates with strong nucleophiles in polar aprotic solvents favor SN2. Tertiary substrates with weak nucleophiles in polar protic solvents favor SN1.

What is the stereochemical outcome of SN1 vs SN2?

SN2 proceeds with inversion of configuration (Walden inversion). SN1 produces a racemic mixture from the flat carbocation intermediate.

What are good SN2 solvents vs SN1 solvents?

SN2: polar aprotic (DMSO, acetone, DMF). SN1: polar protic (water, methanol, ethanol).

Can a tertiary substrate undergo SN2?

No. Tertiary substrates are too sterically hindered for backside attack.

What happens to secondary substrates?

Secondary substrates are context-dependent. Strong nucleophiles in polar aprotic solvents push toward SN2. Weak nucleophiles in polar protic solvents allow SN1.

What is a carbocation rearrangement?

Carbocation rearrangements (hydride and methyl shifts) occur during SN1 when the initial carbocation can rearrange to a more stable one.

⚡ Nucleophilic Substitution · SN1 · SN2

SN1 and SN2 Reaction Solver — Free Step-by-Step Mechanism

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SN2: CH3CH2Br + NaOH SN1: (CH3)3CBr + H2O 2-bromobutane + NaCN SN2 vs tertiary substrate Carbocation rearrangement

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Identifying reaction type…

🔬 Analyzing substrate class…

⚡ Evaluating nucleophile strength…

🧪 Checking solvent & leaving group…

🔀 Determining SN1 vs SN2 pathway…

📐 Building mechanism & stereochemistry…

⚡ Reaction Identified

SN2 Pathway

Bimolecular

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SN1 Pathway

Unimolecular

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Major Product

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Stereochemical Outcome

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Step 1

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3 more mechanism steps available

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The core question

How to Determine SN1 vs SN2: The Complete Decision Framework

The SN1 vs SN2 question is one of the most tested concepts in Orgo 1. Substrate class, nucleophile strength, leaving group ability, and solvent polarity all interact to determine which mechanism dominates.

Factor	Favors SN2	Favors SN1	Why
Substrate	Primary (1°)	Tertiary (3°) · allylic · benzylic	Steric hindrance blocks backside attack
Nucleophile	Strong (CN⁻, I⁻, RS⁻, RO⁻)	Weak (H₂O, ROH)	SN2 rate depends on [Nu]; SN1 does not
Solvent	Polar aprotic (DMSO, DMF)	Polar protic (H₂O, MeOH, EtOH)	Aprotic leaves Nu reactive; protic stabilizes cations
Leaving group	Good LG needed	Good LG needed	Both mechanisms require good LG
Secondary (2°)	Strong Nu + polar aprotic	Weak Nu + polar protic	Conditions determine pathway
Rearrangement	Never	Possible (hydride/methyl shift)	Diagnostic for SN1
Stereochemistry	Inversion (Walden)	Racemization	Most tested stereo topic
Rate law	k[sub][Nu] — bimolecular	k[sub] — unimolecular	Reflects rate-determining step

Substrate class

How Substrate Class Determines the Mechanism

The single most important factor is the class of the carbon bearing the leaving group.

1°

Primary

CH₃Br, CH₃CH₂Br

Low steric hindrance. Primary carbocations too unstable.

Strongly favors SN2

2°

Secondary

2-bromobutane, cyclohexyl bromide

Moderate hindrance. Conditions determine pathway.

Conditions determine

3°

Tertiary

(CH₃)₃CBr, tert-amyl chloride

SN2 impossible. Stable carbocations.

Strongly favors SN1

⚠️

Special Cases: Allylic and Benzylic

Allylic and benzylic substrates can undergo SN1 even at secondary level because resonance stabilizes the carbocation. Always check for these features before applying the standard rules.

Mechanism breakdown

SN1 and SN2 Mechanisms: Step-by-Step Comparison

SN2 is concerted (one step). SN1 is stepwise (leaving group departs first, nucleophile attacks second). This timing difference explains stereochemistry, rate law, and rearrangements.

⚡ SN2 Mechanism

Steps

One concerted step

Transition state

Pentacoordinate carbon, trigonal bipyramidal

Stereochemistry

100% inversion (Walden inversion)

Rate law

Rate = k[substrate][nucleophile]

Rearrangements

Never

🔁 SN1 Mechanism

Steps

Two steps (+ possible rearrangement)

Intermediate

Planar sp2 carbocation

Stereochemistry

Racemization

Rate law

Rate = k[substrate]

Rearrangements

Possible via 1,2-shifts

Stereochemical outcomes

Stereochemistry of SN1 and SN2 Reactions

↩️

SN2: Walden Inversion

Nucleophile attacks from the back face (180°). All substituents flip. R → S or S → R. 100% stereospecific.

SN2 · 100% inversion

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SN1: Racemization

Flat carbocation attacked from both faces equally. 50:50 R and S mixture. Optically inactive product.

SN1 · racemic mixture

Solvent effects

Polar Aprotic vs Polar Protic Solvents

Polar aprotic solvents leave nucleophiles reactive (SN2). Polar protic solvents stabilize carbocations (SN1).

Polar Aprotic → SN2

DMSOSN2

DMFSN2

AcetoneSN2

AcetonitrileSN2

THFSN2

Polar Protic → SN1

WaterSN1

MethanolSN1

EthanolSN1

Acetic acidSN1

Formic acidSN1

Advanced topic

Carbocation Rearrangements in SN1 Reactions

When SN1 forms a secondary carbocation adjacent to a tertiary carbon, the carbocation rearranges via 1,2-hydride or methyl shift to the more stable form.

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1,2-Hydride Shift

A hydrogen migrates from an adjacent carbon to the carbocation center, converting a secondary carbocation into a more stable tertiary one. This shift is extremely fast.

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1,2-Methyl Shift

A methyl group migrates when no hydride shift is possible. Produces a rearranged carbon skeleton.

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Exam Strategy

If the product carbon skeleton differs from the substrate, a rearrangement occurred, confirming SN1. SN2 can never give rearranged products.

Competition reactions

SN2 vs E2 and SN1 vs E1: When Does Elimination Compete?

Strong, non-bulky nucleophiles at lower temperatures favor SN2. Bulky bases promote E2. For tertiary substrates, SN1 and E1 compete, with E1 favored at higher temperatures.

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Related solvers

↕ E1 & E2 Solver 📘 Orgo 1 Solver ⚗️ Full Solver 📄 SN1 vs SN2 Guide

Frequently asked questions

SN1 and SN2 Reaction Solver — FAQ

How do you determine SN1 or SN2? +

Primary + strong Nu + polar aprotic = SN2. Tertiary + weak Nu + polar protic = SN1. Secondary depends on conditions.

What is the stereochemical outcome? +

SN2: complete inversion (Walden inversion). SN1: racemization from flat carbocation.

What solvents favor SN2 vs SN1? +

SN2: polar aprotic (DMSO, DMF, acetone). SN1: polar protic (water, methanol, ethanol).

Can tertiary undergo SN2? +

No. Three alkyl groups completely block backside attack.

What is carbocation rearrangement? +

1,2-hydride or methyl shift in SN1 converts a less stable carbocation to a more stable one, changing the product skeleton. SN2 cannot rearrange.

SN2 vs E2 competition? +

Non-bulky nucleophiles favor SN2. Bulky bases favor E2. Higher temperature favors elimination. See the elimination solver.

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