A very long, rectangular loop of wire can slide without fnction on a horizontal surface. Initially the loop has part of its area in a region of uniform magnetic field that has magnitude B=3.10 T and is perpendicular to the plane of the loop.The loop has dimensions 4.00 cm by 60.0 cm, mass 260 g, and resistance R=6.00×10−3Ω The loop is initially at rest, then a constant force Fext​ = 0.180 N is applied to the loop to pull it out of the field (Figure 1).. i ) What is the acceleration of the loop when v = 3.00 cm/s? a = ---------m/s^2

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A very long, rectangular loop of wire can slide without fnction on a horizontal surface. Initially the loop has part of its area in a region of uniform magnetic field that has magnitude B=3.10 T and is perpendicular to the plane of the loop.The loop has dimensions 4.00 cm by 60.0 cm, mass 260 g, and resistance R=6.00×10−3Ω The loop is initially at rest, then a constant force Fext​ = 0.180 N is applied to the loop to pull it out of the field (Figure 1)..

i ) What is the acceleration of the loop when v = 3.00 cm/s?

a = ---------m/s^2

A very long, rectangular loop of wire can slide without
friction on a horizontal surface Initially the loop has part of
its area in a region of uniform magnetic field that has
magnitude B=3.10 T and is perpendicular to the plane
of the loop. The loop has dimensions 4.00 cm by
60.0 cm, mass 26.0 g, and resistance
R=6.00×10-3 2 The loop is initially at rest, then a
constant force Fet = 0.180 N is applied to the loop to pull
it out of the field (Figure 1).
Figure
4.00 cm
600 cm
< 1 of 1 >
Transcribed Image Text:A very long, rectangular loop of wire can slide without friction on a horizontal surface Initially the loop has part of its area in a region of uniform magnetic field that has magnitude B=3.10 T and is perpendicular to the plane of the loop. The loop has dimensions 4.00 cm by 60.0 cm, mass 26.0 g, and resistance R=6.00×10-3 2 The loop is initially at rest, then a constant force Fet = 0.180 N is applied to the loop to pull it out of the field (Figure 1). Figure 4.00 cm 600 cm < 1 of 1 >
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