Noting the curved arrows, draw all the product(s), organic and inorganic, of the following reaction. H3C CH3 • You do not have to consider stereochemistry. Draw one structure per sketcher. Add additional sketchers using the drop-down menu in the bottom right corner. Separate structures with + signs from the drop-down menu.

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### Reaction Products Identification **Instruction:** Noting the curved arrows, draw all the product(s), organic and inorganic, of the following reaction.  **Task Requirements:** - You do not have to consider stereochemistry. - Draw one structure per sketcher. Add additional sketchers using the drop-down menu in the bottom right corner. - Separate structures with "+" signs from the drop-down menu. **Reaction Mechanism Detail:** 1. The curved arrow indicates the electron movement. 2. The reaction involves a nucleophilic attack where the electrons from the pi bond of propene (CH₃CH=CH₂) attack a proton (H⁺), leading to the formation of a new bond. **Diagram Explanation:** The top section shows a chemical reaction mechanism: - **Reactants:** A propene molecule and a hydrogen cation (H⁺). - **Curved Arrow:** Indicates the movement of electrons from the double bond in propene towards the H⁺ ion. The tool shown is a ChemDoodle interface for drawing chemical structures. Please use the tools provided in the interface to accurately depict the chemical structures that result from the reaction described above.

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### Electrophilic Addition of HBr to Alkenes **Mechanism Overview:** The electrophilic addition of HBr to alkenes results in the formation of a bromoalkane. This reaction initiates with an electrophilic attack by the π electrons of the alkene's double bond on the hydrogen of HBr, generating a carbocation intermediate. **Markovnikov's Rule Application:** The hydrogen atom from HBr adds to the sp² carbon with the greater number of hydrogens, following Markovnikov’s rule. This preference leads to the most stable carbocation: - **Stability Order:** \(1^{\circ} < 2^{\circ} < 3^{\circ}\) **Carbocation Rearrangement:** To achieve a more stable carbocation, a \(1,2\)-shift of an adjacent hydride or methyl group may occur before the final step of the reaction. **Final Step:** Nucleophilic bromide ion then adds to the carbocation, yielding a neutral bromoalkane. **Mechanism Instructions:** The task involves drawing curved arrows to illustrate electron movement during the mechanism. **Diagram Explanation:** 1. **Initial Alkene and HBr Reaction:** - The alkene reacts with HBr, attacking the H to form a carbocation. 2. **Carbocation Intermediate:** - Illustrated with the positive charge on the carbon adjacent to the addition site of the H. 3. **Bromide Ion Addition:** - The negatively charged bromide ion is shown adding to the carbocation, completing the bromoalkane formation. This activity requires indicating the electron flow precisely, using the curved arrows provided in the interface. Once completed, learners can submit their answers or retry as needed. **Interactive Components:** - Use the "Arrow-pushing Instructions" for guidance. - Options available: "Submit Answer," "Retry Entire Group." **Learning Objective:** Understand and apply Markovnikov’s rule in the context of electrophilic addition reactions to correctly predict the formation of addition products from alkenes and HBr.