A moveable (massless and frictionless) bar with a length of L = 18/50 m is being moved at a constant velocity of 60/10 m/s from left to right along two conducting rails by an external force, F, as shown in
the Figure. If the system is immersed in a uniform magnetic field (out of the paper) with magnitude
18/100 Tesla, What is the induced current and its direction of the loop if the resistance is 18/5 Ω ?

Transcribed Image Text:

The image depicts a diagram related to fluid dynamics or electromagnetism concepts. It features a closed loop and interactions between a surface and a vector field. Here's a detailed explanation: - **Closed Loop**: The diagram shows a rectangular loop with its top segment highlighted. This segment is labeled with a length \( \ell \). - **Vector Field**: Numerous circular symbols with dots inside (typically representing field lines coming out of the page) are evenly distributed across the diagram. - **Velocity Vector**: There is a green arrow pointing to the right, labeled \( v \), indicating the direction and magnitude of velocity or flow. - **Area Element**: A small section of the upper part of the loop is highlighted, with a perpendicular dashed line labeled \( dA \), representing a differential area element. - **Dimensions**: The vertical distance of the loop section is marked as \( \ell \), indicating this is a significant dimension in the context of the problem the diagram is illustrating. This diagram might be used to illustrate concepts such as the flow of a fluid through a loop, the magnetic field interaction with a moving conductor, or other similar physical phenomena.