Change the bond between the two carbon atoms in each molecule to a double or triple bond as needed to complete the structure. If the bond should remain a single bond, then you do not need to do anything to the bond. Do not change any other bonds in the molecules. Molecule A Molecule B Select Draw Rings More Erase Select Draw Rings More Erase C H. H H H. H H- U- I

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Title: Understanding Carbon Bond Transformations --- **Activity Instructions:** Change the bond between the two carbon atoms in each molecule to a double or triple bond as needed to complete the structure. If the bond should remain a single bond, then you do not need to do anything to the bond. Do not change any other bonds in the molecules. --- **Molecule A:** - **Diagram Description:** The molecular structure consists of two carbon atoms (C) connected by a single bond. Each carbon atom has three hydrogen atoms (H) bonded to it, giving it a total of four bonds, maintaining carbon's tetravalency. - **Toolbox Options:** - Single bond - Double bond - Triple bond - C (Carbon) - H (Hydrogen) - Erase - **Action Required:** Determine if the single bond between the two carbon atoms needs to be changed to a double or triple bond to complete the molecular structure according to its requirements. --- **Molecule B:** - **Diagram Description:** The molecular structure displays two carbon atoms (C) connected by a single bond. Each carbon has two hydrogen atoms (H) bonded to it. The linear arrangement implies that further bond modification may be required to satisfy the correct molecular geometry. - **Toolbox Options:** - Single bond - Double bond - Triple bond - C (Carbon) - H (Hydrogen) - Erase - **Action Required:** Assess whether the single bond between the two carbon atoms should be adjusted to a double or triple bond in order to achieve the correct structural stability of the molecule. --- Make sure to use the tools provided to adjust the bonds as needed without altering any other part of the molecular structures.