Draw the product of an SN2 reaction shown below. Use wedge and dash bonds to indicate stereochemistry where appropriate. Ignore inorganic byproducts. NaCCCH2CH3. THF Ō||III.

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**Title: Understanding SN2 Reactions: Stereochemistry and Product Formation**

**Introduction to SN2 Reactions**

SN2 reactions are a type of nucleophilic substitution where a nucleophile attacks an electrophile, resulting in the displacement of a leaving group. These reactions are bimolecular, meaning that the rate of reaction depends on the concentration of both the nucleophile and the substrate.

**Objective**

In this activity, you will learn how to draw the product of an SN2 reaction while indicating stereochemistry using wedge and dash bonds. The reaction involves an organic substrate and an acetylide ion (NaCCC\(_2\)H\(_3\)) in the presence of THF (tetrahydrofuran) as a solvent. Inorganic byproducts can be ignored for the purpose of this exercise.

**Reaction Details**

The substrate is a carbon chain with a leaving group (Cl) attached. The leaving group is situated on a stereocenter, indicated by wedge and dash lines, representing the three-dimensional arrangement of atoms.

- **Substrate:** A hydrocarbon chain with a Cl group on a stereocenter.
- **Nucleophile:** NaC≡CCH\(_2\)CH\(_3\) (sodium propynide)
- **Solvent:** THF (tetrahydrofuran)

**Mechanism Steps**

1. **Nucleophilic Attack:** The nucleophile (acetylide ion) attacks the electrophilic carbon atom bearing the leaving group (Cl). This occurs from the side opposite to the leaving group (backside attack).
2. **Inversion of Configuration:** Due to backside attack, the stereochemistry at the carbon center is inverted (Walden inversion).
3. **Formation of Product:** The chlorine (Cl) group leaves, resulting in the formation of the new product, now with the nucleophile attached.

**Expected Outcome**

- The product will display an inversion of stereochemistry at the carbon center where the Cl was originally attached.
- The use of wedge and dash bonds is critical in representing this three-dimensional change.

**Example**

The following depiction illustrates the mechanism of the SN2 reaction using wedge and dash bonds to define the stereochemistry.

(Here, you could use a drawing feature to illustrate the substrate, transition, and product with appropriate stereochemistry.)

Understanding these concepts of SN2 reactions will help in visualizing how nucleophilic substitution reactions proceed and how stereochemistry plays a crucial role in
Transcribed Image Text:**Title: Understanding SN2 Reactions: Stereochemistry and Product Formation** **Introduction to SN2 Reactions** SN2 reactions are a type of nucleophilic substitution where a nucleophile attacks an electrophile, resulting in the displacement of a leaving group. These reactions are bimolecular, meaning that the rate of reaction depends on the concentration of both the nucleophile and the substrate. **Objective** In this activity, you will learn how to draw the product of an SN2 reaction while indicating stereochemistry using wedge and dash bonds. The reaction involves an organic substrate and an acetylide ion (NaCCC\(_2\)H\(_3\)) in the presence of THF (tetrahydrofuran) as a solvent. Inorganic byproducts can be ignored for the purpose of this exercise. **Reaction Details** The substrate is a carbon chain with a leaving group (Cl) attached. The leaving group is situated on a stereocenter, indicated by wedge and dash lines, representing the three-dimensional arrangement of atoms. - **Substrate:** A hydrocarbon chain with a Cl group on a stereocenter. - **Nucleophile:** NaC≡CCH\(_2\)CH\(_3\) (sodium propynide) - **Solvent:** THF (tetrahydrofuran) **Mechanism Steps** 1. **Nucleophilic Attack:** The nucleophile (acetylide ion) attacks the electrophilic carbon atom bearing the leaving group (Cl). This occurs from the side opposite to the leaving group (backside attack). 2. **Inversion of Configuration:** Due to backside attack, the stereochemistry at the carbon center is inverted (Walden inversion). 3. **Formation of Product:** The chlorine (Cl) group leaves, resulting in the formation of the new product, now with the nucleophile attached. **Expected Outcome** - The product will display an inversion of stereochemistry at the carbon center where the Cl was originally attached. - The use of wedge and dash bonds is critical in representing this three-dimensional change. **Example** The following depiction illustrates the mechanism of the SN2 reaction using wedge and dash bonds to define the stereochemistry. (Here, you could use a drawing feature to illustrate the substrate, transition, and product with appropriate stereochemistry.) Understanding these concepts of SN2 reactions will help in visualizing how nucleophilic substitution reactions proceed and how stereochemistry plays a crucial role in
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