For the SN2 reaction, draw the major organic product and select the correct (R) or (S) designation around the stereocenter carbon in the organic substrate and organic product. Include wedge‑and‑dash bonds and draw hydrogen on a stereocenter.

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### Transcription and Explanation for Educational Use **Chemical Reaction Scheme:** This diagram depicts a nucleophilic substitution reaction involving an optically active bromocyclopentane molecule and a cyanide ion. **Reactant:** - **Bromocyclopentane:** A cyclopentane ring (a five-membered carbon ring) with a bromine atom (Br) attached as well as a hydrogen atom (H) on the same carbon. The bromine is shown with a wedge bond, indicating that it is coming out of the plane towards the viewer. The hydrogen is shown with a dashed bond, indicating that it is going behind the plane. **Reagent:** - **Cyanide Ion (\( \text{C} \equiv \text{N}^- \)):** A linear ion composed of carbon triple-bonded to nitrogen, negatively charged and depicted to the right of the reaction arrow. The arrow indicates that the cyanide ion will be acting as the nucleophile in this reaction. **Reaction Arrow:** - The arrow represents the progress of the reaction from the reactants on the left to the products (not shown) on the right. In a typical nucleophilic substitution, the negatively charged cyanide ion will attack the electrophilic center where bromine is attached, potentially leading to the displacement of the bromine atom. This reaction is an example of a nucleophilic substitution (SN2) mechanism, where the cyanide ion serves as a nucleophile, attacking the electrophilic carbon and displacing the bromine atom. The reaction results in the formation of a new carbon-carbon bond, converting the bromocyclopentane into a nitrile compound.