Marvin uses a long copper wire with resistivity 1.681.68 x 10-8 Ω⋅m and diameter 1.00 x 10-3 m to create a solenoid that has a 3.00 cm radius. Part A) Calculate the total resistance if Marvin uses 11.9 meters of wire to create the solenoid. Part B) Assume that Marvin has used the full length of the wire to produce the solenoid (that, is you may neglect any length of wire necessary to connect the solenoid to an battery). Calculate how many turns are in the solenoid. Part C) A 3.00 Volt potential difference is applied across the wires of the solenoid. Calculate the current that passes through the solenoid. Part D) If the coils in the solenoid are separated so that they are evenly spaced across a total length of 0.1 m, what is the magnitude of the magnetic field along the central axis inside of the solenoid?

Marvin uses a long copper wire with resistivity 1.681.68 x 10-8 Ω⋅m and diameter 1.00 x 10-3 m to create a solenoid that has a 3.00 cm radius. Part A) Calculate the total resistance if Marvin uses 11.9 meters of wire to create the solenoid. Part B) Assume that Marvin has used the full length of the wire to produce the solenoid (that, is you may neglect any length of wire necessary to connect the solenoid to an battery). Calculate how many turns are in the solenoid. Part C) A 3.00 Volt potential difference is applied across the wires of the solenoid. Calculate the current that passes through the solenoid. Part D) If the coils in the solenoid are separated so that they are evenly spaced across a total length of 0.1 m, what is the magnitude of the magnetic field along the central axis inside of the solenoid?