The coill in the figure carries current i-156 A in the direction indicated, is parallel to an xz plane, has 2 turns and an area of 5.81 x 10³ m², and lies in a uniform magnetic field (2.291-384-4.74 ) mT. (a) What is the magnetic potential energy of the coil-magnetic field system? (b) What is the magnetic torque (in unit-vector notation) on the coil? (a) Number i (b) Number ( Unit 7+ i A) Unit

Transcribed Image Text:

The image features a physics problem related to electromagnetic fields involving a coil. Here's a detailed transcription suitable for an educational website: --- **Problem Statement:** The coil in the figure carries a current \( I = 1.56 \, \text{A} \) in the direction indicated. It is parallel to an \( xy \) plane, has 2 turns, and an area of \( 5.8 \times 10^{-3} \, \text{m}^2 \), and lies in a uniform magnetic field \(\mathbf{B} = (2.29\hat{\imath} - 3.84\hat{\jmath} + 4.74\hat{k})\, \text{T}\). (a) What is the magnetic potential energy of the coil-magnetic field system? (b) What is the magnetic torque (in unit-vector notation) on the coil? **Diagram Explanation:** The diagram shows a simple circular coil with an arrow indicating the direction of current flow. The coil is situated in an \( xyz \)-coordinate system with the magnetic field vectors represented by labeled components along each axis. **Calculation Fields:** For parts (a) and (b), there are input fields provided: (a) Magnetic potential energy: - **Number:** [Input Box] - **Unit:** [Dropdown Menu] (b) Magnetic torque: - **i-component:** [Input Box] - **j-component:** [Input Box] - **k-component:** [Input Box] - **Unit:** [Dropdown Menu] --- This presentation helps students understand the problem setup and guides them through calculating the magnetic potential energy and torque on the coil.