Can you please solve a, b, c? Problem 3: A rod AB with length L = 0.115 m is lying on a rectangularconducting loop of zero resistance in a magnetic field as shown in thefigure. The magnetic field has a constant magnitude B = 0.75 T. The rod ismoving to the right with speed v = 0.77 m/s. The resistance on AB is R =140 Q.AXXXLVRandomized VariablesL = 0.115 mB = 0.75 Tv = 0.77 m/sR = 140 Q1ВPart (a) Express the change of the magnetic flux going through the loop 1, A@1, in terms of B, v, L and At.Expression :A®1 =Select from the variables below to write your expression. Note that all variables may not be required.a, At, ɛ1, y, 0, B, d, g, h, L, m, n, P, R, vPart (b) Express the magnitude of the average emf induced in loop 1, 81, in terms of B, L and v.Expression :E1 =Select from the variables below to write your expression. Note that all variables may not be required.a, B, At, ɛ1, 0, B, d, g, h, L, m, P, R, t, vPart (c) Calculate the numerical value of ɛ, in volts.Numeric : Anumeric value is expected and not an expression.E1 =Part (d) Whatť's the direction of the current induced by ɛ,?MultipleChoice :1) Clockwise.2) Counterclockwise.Part (e) Express the change of the magnetic flux going through the loop 2, 4¢2, in terms of B, v, L and At.Expression :A92 =Select from the variables below to write your expression. Note that all variables may not be required.a, At, ɛ1, y, 0, B, d, g, h, L, m, n, P, R, vPart (f) Express the magnitude of the emf induced in loop 2, ɛ2, in terms of B, L and v.Expression :E2 =Select from the variables below to write your expression. Note that all variables may not be required.a, At, ɛ1, y, 0, B, d, g, h, L, m, P, R, t, vPart (g) Calculate the numerical value of ɛ2, in volts.Numeric : A numeric value is expected and not an expression.E2 =Part (h) What's the direction of the current induced by ɛ2?MultipleChoice :1) Counterclockwise.2) Clockwise.

Answered: Image /qna-images/answer/2c0f5eea-a402-4a14-bb87-96e82883a7ec.jpg

Problem 3: A rod AB with length L= 0.115 m is lying on a rectangular conducting loop of zero resistance in a magnetic field as shown in the figure. The magnetic field has a constant magnitude B = 0.75 T. The rod is moving to the right with speed v = 0.77 m/s. The resistance on AB is R = 140 Q. A X х х X L х х х Randomized Variables X" L = 0.115 m B = 0.75 T v = 0.77 m/s R = 140 Q X, В Parı (a) Express the change of the magnetic flux going through the loop 1, A01, in terms of B, v, L and At. Expression : A01 = Select from the variables below to write your expression. Note that all variables may not be required. a, At, ɛ1, y, 0, B, d, g, h, L, m, n, P, R, v Part (b) Express the magnitude of the average emf induced in loop 1, e1, in terms of B, L and v. Expression : E1 = Select from the variables below to write your expression. Note that all variables may not be required. a, B, At, ɛ1, 0, B, d, g, h, L, m, P, R, t, v Part (c) Calculate the numerical value of ɛ1, in volts.

Problem 3: A rod AB with length L= 0.115 m is lying on a rectangular conducting loop of zero resistance in a magnetic field as shown in the figure. The magnetic field has a constant magnitude B = 0.75 T. The rod is moving to the right with speed v = 0.77 m/s. The resistance on AB is R = 140 Q. A X х х X L х х х Randomized Variables X" L = 0.115 m B = 0.75 T v = 0.77 m/s R = 140 Q X, В Parı (a) Express the change of the magnetic flux going through the loop 1, A01, in terms of B, v, L and At. Expression : A01 = Select from the variables below to write your expression. Note that all variables may not be required. a, At, ɛ1, y, 0, B, d, g, h, L, m, n, P, R, v Part (b) Express the magnitude of the average emf induced in loop 1, e1, in terms of B, L and v. Expression : E1 = Select from the variables below to write your expression. Note that all variables may not be required. a, B, At, ɛ1, 0, B, d, g, h, L, m, P, R, t, v Part (c) Calculate the numerical value of ɛ1, in volts.

University Physics Volume 2

18th Edition

ISBN:9781938168161

Author:OpenStax

Publisher:OpenStax

Chapter13: Electromagnetic Induction

Section: Chapter Questions

Problem 69AP: The conducting rod shown in the accompanying figure moves along parallel metal rails that are 25-cm...

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