I NaCN CN acetonitrile

I NaCN CN acetonitrile

A) What is the solvent: (polar/nonpolar) and (protic/aprotic)

B) What is the nucleophile in this reaction?

C) What is the mechanism for this reaction? (Sn1, Sn2, E1, E2 or none)

The correct answer and explanation is:

Answer:

A) Solvent:

• Acetonitrile (CH₃CN) is a polar aprotic solvent.
  • Polar: Acetonitrile has a significant dipole moment due to the electronegativity difference between carbon and nitrogen in the CN group.
  • Aprotic: Acetonitrile lacks an -OH or -NH group, meaning it cannot donate hydrogen bonds.

B) Nucleophile:

• The nucleophile in this reaction is cyanide ion (CN⁻).
  • CN⁻ is a strong nucleophile due to its negative charge and ability to form a strong bond with electrophiles.
  • The lone pair on the carbon in CN⁻ makes it highly reactive in nucleophilic substitution reactions.

C) Mechanism:

• The reaction follows the SN2 (bimolecular nucleophilic substitution) mechanism.

Explanation:

1. Why SN2?
   • SN2 reactions occur when a strong nucleophile (like CN⁻) attacks an electrophilic carbon (often in an alkyl halide).
   • Since the solvent is polar aprotic, it does not stabilize the nucleophile, making it more reactive and favoring the SN2 mechanism.
   • Acetonitrile, as a polar aprotic solvent, enhances nucleophilicity by preventing solvation of CN⁻, allowing a direct backside attack.
2. Mechanism Steps:
   • CN⁻ approaches the substrate (likely an alkyl halide or similar compound).
   • A concerted mechanism occurs: the nucleophile attacks the carbon while the leaving group departs in a single step.
   • The transition state forms as the bond to the leaving group weakens and the bond to CN⁻ strengthens.
   • The product forms with inversion of configuration at the reaction center due to backside attack.
3. Why Not SN1, E1, or E2?
   • SN1/E1 require a polar protic solvent to stabilize the carbocation intermediate.
   • E2 typically needs a strong base, whereas CN⁻ acts primarily as a nucleophile rather than a base.

Thus, the reaction proceeds via an SN2 mechanism with a strong nucleophile (CN⁻) and a polar aprotic solvent (acetonitrile).

I’ll generate an image to illustrate the mechanism.

Here is the image illustrating the SN2 mechanism, showing the cyanide ion (CN⁻) attacking the substrate from the opposite side of the leaving group, the transition state, and the final product with inversion of configuration. Let me know if you need further details!