Answer:
B_{total} = (170.71 i ^ - 170.71 j ^ ) 10⁻⁷ T
Step-by-step explanation:
For this exercise, the easiest way to solve it is using Ampere's law, for each wire and then adding vectorly the fields at the point of the free corner
∫B. ds = μ₀ I
Let's use as the surface of calculates a circle of radius at the desired point, the length of this circle is
s = 2π r
substituting
B 2π r = μ₀ I
B =
The direction of the field can be found by making the thumb point in the direction of the current and the curved fingers are in the direction of the magnetic field.
Let's find the distance to the unoccupied corner (without wire), using the Pythagorean theorem
for the opposite corner
r₁ =
r₁ = √2 L
for adjacent corners
r₂ = L
now let's find the magnetic field created for the wire in the opposite corner
B₁ = \frac{\mu_o \ I}{2\pi \ r_1}
let's reduce the distance to the SI system
L = 4.0cm = 0.040m
let's calculate
B₁ = 4π 10⁻⁷ 2.0 /( 2π √2 0.04)
B₁ = 70.71 10⁻⁷ T
the direction of this field is if we suppose that the current is upwards, it is counterclockwise, if the current is downwards, it is clockwise, since all currents go the same direction, all magnetic fields are circular.
Therefore the creed field in the opposite scheme is a perpendicular to the diagonal
The fields produced by the adjacent cables are
B₂ = 4π 10⁻⁷ 2.0 / 2π 0.04
B₂ = 100 10⁻⁷ T
the field is perpendicular to the seam line
the direction of this field is perpendicular to the line that joins the wire with the vacant corner, so we have for each wire
B_{total} = B₂ i ^ - B₂ j ^ + B₁ cos 45 i ^ - B₁ sin 45 j ^
B_{total} = (170.71 i ^ - 170.71 j ^ ) 10⁻⁷ T