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Answer:
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10.90V
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Explanation:
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Faraday's law of induction states that the electromotive force (E) produced in a magnetic field is directly proportional to the change in flux, ΔΦ, inversely proportional to change in time, Δt. i.e
E = - N ΔΦ / Δt ----------------(i)
Where;
N = proportionality constant called the number of coils in the wire.
With a small change in time, equation (i) could be re-written as follows;
E = - N δΦ / δt --------------(ii)
Also, the magnetic flux, Φ, is given as follows;
Φ = BA cos θ --------------------(iii)
Where;
B = magnetic field
A = cross sectional area of the wire
θ = angle between the field and the cross-section of the wire
Substitute equation (iii) into equation (ii) as follows;
E = - N δ(BAcosθ) / δt
E = - NAcosθ δ(B) / δt -----------------------(iv)
From the question;
B(t) = (3.75 T) + (3.05 T/s)t + (− 6.95 T/s²) t² -------------------(v)
Substitute equation (v) into equation (iv) as follows;
E = - NAcosθ δ[(3.75 T) + (3.05 T/s)t + (− 6.95 T/s²) t²] / δt -----(vi)
Solve equation (vi) by taking derivative as follows;
E = - NAcosθ [3.05 − (2)6.95 t]
E = - NAcosθ [3.05 − 13.9t] ----------------(vii)
Solve for A using the following relation;
A = πr² -----------------(viii)
Where;
r = radius of the wire loop = 0.220m
π = 3.142
Substitute these values into equation (viii) as follows;
A = 3.142 x 0.220²
A = 0.152m²
Now substitute A = 0.152m², N = 1 (a single coil), θ = 19.5° and t = 5.71s into equation (vii)
E = - (1) (0.152)cos(19.5)° [3.05 − 13.9(5.71)]
E = - (1) (0.152)(0.94) [3.05 − 13.9(5.71)]
E = 10.90V
Therefore, the induced EMF in the loop is 10.90V
