Falling bar A conducting rod with a mass m and a length L can slide with no friction down a pair of vertical conducting rails, as shown in the figure below. The rails are joined at the bottom by a lightbulb of resistance R. The rails have stops near the bottom to prevent the rod from smashing the bulb. Thereis a uniform magnetic field of magnitude B directed out of the page. When the rod is released from rest, the force of gravity causes the rod to accelerate down the rails, but the rod eventually reaches a terminal velocity (that is, it falls at constant speed). @ Part (b) o Homework Answered Due Mar 19th, 12:15 PM Which graph best represents the shape of the graph of the magnitude of the induced current passing through the light bulb as a function of time while the rod is falling? U e RN Select an answer and submit. For keyboard navigation, use the up/down arrow keys to select an answer. Select an answer and submit. For keyboard navigation, use the up/down arrow keys to select an answer. W Graph 1 b Graph2 Graph3 d Graph4 e Graph5 f Graph g Graph7 h Graphs8 @ Part (c) o Homework Answered Due Mar 19th, 12:15 PM Use these numbers: the rod has a weight of mg=2.00 N and a length of L = 3.00 m. The resistance of the light bulb is R= 5.00 ohms, and the strength of the magnetic field is B= 0.550 T. Calculate the magnitude of the maximum current in this situation. A Type your numeric answer and submit e Cannot be empty Answered - Incorrect 3 attempts left @ Part (d) o Homework Unanswered Due Mar 19th, 12:15 PM Calculate the rod's terminal speed. m/s Type your numeric answer and submit 0000 Unanswered e 5 attempts left @ Part (e) o Homework Unanswered Due Mar 19th, 12:15 PM Calculate the maximum power dissipated in the light bulb as the bar falls. W Type your numeric answer and submit 0] Unanswered e 5 attempts left