An ideal solenoid 7.20 cm in diameter and38.0 cm long has N = 4.69e4 turns andcarries 12.0 A of current.Calculate the magnetic flux through thesurface of a disk of radius 5.00 cm that ispositioned perpendicular to and centered onthe axis of the solenoid.Your Response History:1. Incorrect. Your answer: "7.31e-5 TmCorrect answer: "0.00732 Tm²".2"The data used on this submission:45300 turns;Submitted 1 days after latedeadline.Score: 0/4You may change your answer andresubmit:Tm² (+ 5E-5 Tm²)Source: Serway and Beichner, Physics for Scientists and Engineers, 5th edition,Problem 30.34a

Given: Diameter of solenoid, 7.2 cm Radius, r=3.6×10-2 m Length, L=38 cm Number of turns, N=4.69…

Answered: An ideal solenoid 7.20 cm in diameter…

Similar questions

In a solenoid in vacuum of length l = 10 cm with 2052 turns per meter the current creates the field B = 70 µT. What will be the value of the current if the solenoid is placed in an external uniform magnetic field Bext = 35 µT with field lines exactly opposite to the field produced by the solenoid? Assume µo = 4Tt × 10¬7 H/m and give your answer in milli-amperes (mA).
A solenoid of length 2.50 cm and radius 0.750 cm has 33 turns. If the wire of the solenoid has 1.25 amps of current, what is the magnitude of the magnetic field inside the solenoid? magnitude of the magnetic field: 2.07 x10-3 Ignoring the weak magnetic field outside the solenoid, find the magnetic energy density inside the solenoid. magnetic energy density: 1.70 J/m³ What is the total magnetic energy inside the solenoid? 3.19 x10¬6 total magnetic energy: J Incorrect
For a solenoid in vacuum of length l = 10 cm with 10* turns per meter calculate the value of the current if the solenoid is placed in an external uniform magnetic field Bext = 35 µT with field lines exactly opposite to the field produced by the solenoid. Take vacuum permeability Ho = 4x x 10-7 H/m. Provide your answer in SI units. Answer:
A given toroidal coil has 1000 turns. Calculate the magnetic field at a point on a circle of radius 1.30 m inside the coil when the current I = 2.9 × 105 A.
In a given region of space, the vector magnetic potential is given by A = x5 coszy + z(0.2+ sin zx) mWb/m. The magnetic flux passing through a square loop with 0.25 cm long edges if the loop is in the x-y plane, its center is at the origin, and its edges are parallel to the x- and y- axis?
. A cylindrical solenoid has a length of 10 cm and a radius of 1 cm. It is tightly wound with 100 turns of wire. The axis of the solenoid is aligned with the z-axis, and the center of the solenoid is at the origin. The current flowing through the solenoid is 1.5 A. What is the magnetic field at the following points of interest? B, Tesla Point of interest x=0, y=0, z=2 cm x=0, y=0, z=200 cm x=0, y=2 cm, z=0 cm سا
As a new electrical technician, you are designing a large solenoid to produce a uniform 0.120-T magnetic field near the center of the solenoid. You have enough wire for 4000 circular turns. This solenoid must be 55.0 cm long and 2.80 cm in diameter. What current will you need to produce the necessary field? Express your answer to three significant figures and include the appropriate units.
A current loop of 2-m radius creates 5 T magnetic field at the center of the loop. A student makes a solenoid out of the same loop wire. He measures the length of the solenoid that is 37 cm and counts the number of turns (that is 76). Calculate the magnetic field at the center of the solenoid.

An ideal solenoid 7.20 cm in diameter and 38.0 cm long has N = 4.69e4 turns and carries 12.0 A of current. Calculate the magnetic flux through the surface of a disk of radius 5.00 cm that is positioned perpendicular to and centered on the axis of the solenoid.