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The figure below shows an end view of a single-turn square loop of metal wire in the center of and coaxial with a very long solenoid with a circular cross section. The solenoid is 21.0 cm long, has a radius r = 3.00 cm, and consists of 126 turns of wire. The length of each side of the square loop is ℓ = 1.50 cm. (a) The current in the solenoid is 4.00 A. What is the magnetic flux through the square loop (in T⋅m2)? T⋅m2 (b) The current decreases from 4.00 A to zero in 4.00 s. What is the magnitude of the average induced emf in the square loop (in V ) over this time? V

The figure below shows an end view of a single-turn square loop of metal wire in the center of and coaxial with a very long solenoid with a circular cross section. The solenoid is 21.0 cm long, has a radius r = 3.00 cm, and consists of 126 turns of wire. The length of each side of the square loop is ℓ = 1.50 cm. (a) The current in the solenoid is 4.00 A. What is the magnetic flux through the square loop (in T⋅m2)? T⋅m2 (b) The current decreases from 4.00 A to zero in 4.00 s. What is the magnitude of the average induced emf in the square loop (in V ) over this time? V

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The figure below shows an end view of a single-turn square loop of metal wire in the center of and coaxial with a very long solenoid with a circular cross section. The solenoid is 21.0 cm long, has a radius r = 3.00 c m , and consists of 126 turns of wire. The length of each side of the square loop is = 1.50 c m . (a) The current in the solenoid is 4.00 A . What is the magnetic flux through the square loop (in T m 2 )? T m 2 (b) The current decreases from 4.00 A to zero in 4.00 s . What is the magnitude of the average induced emf in the square loop (in V ) over this time? V

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