Which chair represents the most stable conformation of Molecule A? A a B b C C D d E e Molecule A OH OH но OH Newman projections a) b) c) H H OH OH OH OH но OH но. H. H но но OH H H HO HO. H H. H H. H H d) e) H он H он но. но. HO H. но H. H он H OH

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**Question:** Which chair represents the most stable conformation of Molecule A? **Options:** - **A)** a - **B)** b - **C)** c - **D)** d - **E)** e **Molecule Diagram:** The image contains a molecular diagram labeled "Molecule A" at the top. It is a chemical structure composed of a six-membered ring with various hydroxyl (OH) groups and hydrogen (H) atoms attached. Below the chemical structure, there are five Newman projections labeled (a), (b), (c), (d), and (e). Each projection shows a different chair conformation of the molecule, depicting the spatial arrangement of the substituent groups around the six-membered ring. - **Projection a** shows hydroxyl and hydrogen atoms in various axial and equatorial positions. - **Projection b** follows a different pattern of axial and equatorial positions for hydroxyl and hydrogen atoms. - **Projection c** has another distinct pattern of substituent positions. - **Projection d** again presents a unique arrangement of substituents. - **Projection e** follows its own distinct pattern. The diagrams illustrate the different spatial orientations in which Molecule A can be arranged, which influence the molecule's stability based on steric hindrance and interactions between the substituents. **Note for Educators:** When teaching about chair conformations and molecular stability, it’s crucial to explain how substituents in axial positions can cause steric strain and how placing bulky groups in equatorial positions generally leads to a more stable conformation. Utilize these projections to show how different arrangements impact the molecule's overall energy and stability.