Determine the Magnetic field intensity at a point P due to a current carrying    ...

13. A current carrying wire sits inside a magnetic field. The 5 meter wire carries a...

13. A current carrying wire sits inside a magnetic field. The 5 meter wire carries a conventional current of 3 amps along the +z-direction (toward the sky) and experiences a force of 10 newtons along the y-direction (toward the South). What are the x-,y-, and z-components of the magnetic field? Use a diagram to show your answer.

The current in a wire is directed along the y-axis in a uniform magnetic field. The...

The current in a wire is directed along the y-axis in a uniform magnetic field. The resulting force on the wire is directed along the negative z-axis. The magnetic field is directed along the +x axis +y axis -x axis -y axis None of the above.

All current-carrying wires along the surface of the Earth lie in the magnetic field of the...

All current-carrying wires along the surface of the Earth lie in the magnetic field of the Earth. When the current is turned on why don't these wires jump?

Two long, straight, current carrying wires are situated in a traditional x-y-z coordinate system, where distances...

Two long, straight, current carrying wires are situated in a traditional x-y-z coordinate system, where distances are in meters. Wire 1 lies along the z-axis and carries a current in the positive z-direction of ?1 = 4.00 ?. Wire 2 is parallel to wire 1, passing through the point (3, 3, 0), and carrying a current in the negative z-direction of ?2 = 3.00 ?. Determine the magnetic field at the point (2, 1, 0) in unit-vector notation.

At a point on the Earth’s surface the magnetic field has a horizontal component due north...

At a point on the Earth’s surface the magnetic field has a horizontal component due north of 1.8 ́ 10-5 T and a vertical component downwards of 5.5 ́ 10-5 T. (i) Draw a diagram. (ii) Calculate the force on a 1.5 m length of wire carrying a current of 13 A when the wire is held vertically with the current flowing downwards. (iii) Calculate the force when the wire is horizontal with the current flowing west to east.

1. The magnetic field B of a long current carrying wire at a point is obtained...

1. The magnetic field B of a long current carrying wire at a point is obtained using the following formula:            B=μ0 I /(2π r),         where I is the current going through the wire and r is the distance of the point from the wire in cm. (a) Given the data in the table below, plot B versus 1/r and a best fitted line through them on the grid provided below. (b) Calculate the slope of...

Find the magnetic field of an infinitely long-current carrying wire with current I = A cos(wt)...

Find the magnetic field of an infinitely long-current carrying wire with current I = A cos(wt) in the +x direction with w > 0 but small and constant and A > 0 constant.

A short section of coaxial cable consists of a line current along the z-axis from z...

A short section of coaxial cable consists of a line current along the z-axis from z = -L to z = L carrying current ?0?̂ surrounded by a hollow cylindrical shell (centered on the z-axis, top at z = L , bottom at z = -L) carrying a surface current ?⃗⃗ = ?0 (−?̂). Radius 2R a. Find an expression for the magnetic field at an arbitrary point (x, y, z) b. Draw a qualitative graph of the magnetic field...

In free space, the electric field intensity ? = 20 cos (ωt-50x) ?̂ V/m. ?̂ is...

In free space, the electric field intensity ? = 20 cos (ωt-50x) ?̂ V/m. ?̂ is the unit vector along y-axis. Calculate (i) Displacement current density (?? ?? ). (ii) Magnetic Field intensity (?) (iii) Angular frequency (ω). Assume ? 0 = 4? × 10( −7) and ? 0 = 8.854 × 10 (−12) ?/?

A flat,106 turn current‑carrying loop is immersed in a uniform magnetic field. The area of the...

A flat,106 turn current‑carrying loop is immersed in a uniform magnetic field. The area of the loop is 5.95×10−4 m2, and the angle between its magnetic dipole moment and the field is 43.1∘. Find the strength of the magnetic field that causes a torque of 1.53×10−5 N⋅m to act on the loop when a current of 0.00395 A flows in it.