Final answer:
Using the Lorentz force formula, the force experienced by a 1-meter long conductor carrying a current of 5 A in a parallel orientation to a 0.1 Tesla magnetic field is calculated to be 0 N because the angle between the conductor and the field is 0 degrees, resulting in no perpendicular component to cause a force.
Step-by-step explanation:
The subject in this question is Physics, and it pertains to the high school level. The scenario being considered involves a conductor carrying a current and experiencing a force while being placed in a magnetic field. To calculate the force experienced by a conductor in a magnetic field, the following formula derived from the Lorentz force is used: F = I x L x B x sin(θ), where F is the force in newtons, I is the current in amperes, L is the length of the wire in meters, B is the magnetic field strength in teslas, and θ is the angle between the wire and the direction of the magnetic field.
In the given problem, the conductor is 1 meter long (L = 1m), carries a current of 5 A (I = 5A), and is placed in a parallel orientation to a magnetic field with a strength of 0.1 Tesla (B = 0.1T). Because the wire is parallel to the field, the angle θ is 0 degrees, and since sin(0°) = 0, the magnitude of the force is F = 5A x 1m x 0.1T x sin(0°) = 0 N.