Study the image below of levitating magnets. Assume the top side of the topmost disk magnet is North. Use evidence of repulsion and attraction to identify ALL of the poles of each magnet in the order they occur from top to bottom. (Hint: You may consider disk magnets as "squished" or flattened bar magnets.) +000

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**Levitating Magnets and Magnetic Poles** **Study the image of levitating magnets provided. Assume the top side of the topmost disk magnet is North. Use evidence of repulsion and attraction to identify all of the poles of each magnet in the order they occur from top to bottom.** *Hint: You may consider disk magnets as "squished" or flattened bar magnets.* **Image Description:** The image features a series of four disk magnets levitating on a rod. From top to bottom, the disks are colored blue, green, yellow, and red. The magnets are arranged so that they appear to be floating above one another without touching, demonstrating the principles of magnetic repulsion and attraction. The rod provides a central axis to align and stabilize the magnets, allowing the magnetic interactions to be clearly observed. **Understanding the Phenomenon:** - **Magnetic Poles:** Each magnet has a North and South pole. Like poles repel each other, while opposite poles attract. - **Application:** Based on the assumption that the North pole is on the topmost side of the blue magnet, you can infer the alignment of the other poles. For levitation to occur, the facing sides of adjacent magnets must be like poles (either North-North or South-South) causing repulsion. Analyze the positioning and stabilize the floating effect to determine the sequence of poles in this setup, further enhancing the understanding of magnetism and its fundamental properties.