Figure, shows an equilateral triangular loop CDE, carrying current I. Length of each side of triangle is l. If a uniform magnetic field exists parallel to side DE of loop, then find the foces acting on the three wires CD, DE and EC separately.

Figure, shows an equilateral triangular loop CDE, carrying current I.

1.	Figure, shows an equilateral triangular loop CDE, carrying current I. Length of each side of triangle is l. If a uniform magnetic field exists parallel to side DE of loop, then find the foces acting on the three wires CD, DE and EC separately.
Answer» Correct Answer - `IlBsqrt3//2`, normally outwards, zero `IlBsqrt3//2`, normally inwards For current in wire CD, the angle between `vecl` and `vecB` is `120^@`, i.e., `theta=120^@`. Therefore, force on wire CD is `vecF_(CD)=I[(vec(CD))xxvecB]=IlBsin 120^@hatn` or `F_(CD)=IlBsin120^@=IlBxxsqrt3//2` Its direction according to Right Hand Rule is normally out of the plane of paper. For arm DE, the anggle between `vecl` and `vecB` is zero i.e., `theta=0^@`. Therefore, force on wire DE is `IlBsin0^@=0` For arm EC, the angle between `vecl` and `vecB` is `120^@` i.e., `theta=120^@`. Therefore, force on wire EC is `F_(CE)I(CE)Bsin120^@=IlBxxsqrt3//2` Its direction is normally into the plane of paper.

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Figure, shows an equilateral triangular loop CDE, carrying current I. Length of each side of triangle is l. If a uniform magnetic field exists parallel to side DE of loop, then find the foces acting on the three wires CD, DE and EC separately.

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