A rigid wire consists of a semicircular portion of radius and two straight sections. The wire is partially immersed in a perpendicular magnetic field . The magnetic force on the wire if it has a current is:
- A
- B
- C
- D
A rigid wire consists of a semicircular portion of radius and two straight sections. The wire is partially immersed in a perpendicular magnetic field . The magnetic force on the wire if it has a current is:
Correct answer:D
Standard Method
Given: A rigid wire has a semicircular portion of radius and two straight sections. It carries current and is placed in a perpendicular magnetic field .
Find: The net magnetic force on the wire.
For a current-carrying wire in a uniform magnetic field,
where is the effective length vector from one end of the segment to the other.
For the semicircular part, the effective length equals the diameter, so its magnitude is
The two straight sections are parallel to the magnetic field, so the force on each straight segment is zero.
Hence the total force is due to the semicircular part alone. Substituting the effective length ,
Using the right-hand rule for the given current direction and magnetic field, the force is along . Therefore,
Therefore, the correct option is D.
Use effective length of the arc
Given: Only the portion of wire inside the field contributes to magnetic force.
Find: Net force on the wire.
A wire segment in uniform magnetic field can be treated using the end-to-end vector of that segment:
For a semicircular arc, the end-to-end distance is the diameter,
The straight sections are parallel to , so they contribute no force. Thus directly,
With direction from the right-hand rule, the force is . Hence,
So the correct option is D.
Treating the arc length as in . This is wrong because is the end-to-end vector, not the path length. Use the diameter for the semicircular part.
Adding force from the straight sections without checking orientation. This is wrong because a wire parallel to the magnetic field has zero magnetic force. First test whether the segment is parallel to .
Getting the magnitude correct but the direction wrong. This happens when the right-hand rule is applied carelessly. Determine the direction from before choosing the option.
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