mLVA positively charged particle is tied by a massless string and allowed to move on a smooth plane, as shown in the picture. A uniform magneticfield B = 2 T is applied perpendicular to the plane pointing down. The length of the string is L = 50 cm. The mass of the particle is m = 55 kg.The charge on this particle is q = 0.6 C. The velocity of the motion is a constant v = 0.9265 m/s, in the clockwise direction when observingfrom above the plane. You can ignore friction.%3DAt a speed of v = 0.9265 m/s, how much is the Lorentz force (i.e. magnetic force) on the particle? (in units of Newton)%3DSubmit AnswerTries 0/2To maitain the circular motion at this speed with a radius L, the net force Fnet on the particle is pointing to the center O. How much is Fnet? (inunits of Newton)Submit AnswerTries 0/2It is strongly recommended that you draw a free body diagram to answer the next two parts of the problem.How much is the tension in the string? (in units of Newton)NSubmit AnswerTries 0/2If the particle moves in the opposite direction, but with the same speed v, how much is the tension in the string? (in units of Newton)

Given: The mass of the object is 55 kg. The length of the string is 50 cm. The speed of the object…

m 10 B A positively charged particle is tied by a massless string and allowed to move on a smooth plane, as shown in the picture. A uniform magnet field B = 2 T is applied perpendicular to the plane pointing down. The length of the string is L = 50 cm. The mass of the particle is m = 55 k The charge on this particle is q = 0.6 C. The velocity of the motion is a constant v = 0.9265 m/s, in the clockwise direction when observing from above the plane. You can ignore friction. At a speed of v = 0.9265 m/s, how much is the Lorentz force (i.e. magnetic force) on the particle? (in units of Newton) Submit Answer Tries 0/2 To maitain the circular motion at this speed with a radius L, the net force Fnet on the particle is pointing to the center O. How much is Fnet? units of Newton) Submit Answer Tries 0/2 It is strongly recommended that you draw a free body diagram to answer the next two parts of the problem. How much is the tension in the string? (in units of Newton) Submit Answer Tries 0/2 If the particle moves in the opposite direction, but with the same speed v, how much is the tension in the string? (in units of Newton)

m 10 B A positively charged particle is tied by a massless string and allowed to move on a smooth plane, as shown in the picture. A uniform magnet field B = 2 T is applied perpendicular to the plane pointing down. The length of the string is L = 50 cm. The mass of the particle is m = 55 k The charge on this particle is q = 0.6 C. The velocity of the motion is a constant v = 0.9265 m/s, in the clockwise direction when observing from above the plane. You can ignore friction. At a speed of v = 0.9265 m/s, how much is the Lorentz force (i.e. magnetic force) on the particle? (in units of Newton) Submit Answer Tries 0/2 To maitain the circular motion at this speed with a radius L, the net force Fnet on the particle is pointing to the center O. How much is Fnet? units of Newton) Submit Answer Tries 0/2 It is strongly recommended that you draw a free body diagram to answer the next two parts of the problem. How much is the tension in the string? (in units of Newton) Submit Answer Tries 0/2 If the particle moves in the opposite direction, but with the same speed v, how much is the tension in the string? (in units of Newton)

College Physics

11th Edition

ISBN:9781305952300

Author:Raymond A. Serway, Chris Vuille

Publisher:Raymond A. Serway, Chris Vuille

Chapter1: Units, Trigonometry. And Vectors

Section: Chapter Questions

Problem 1CQ: Estimate the order of magnitude of the length, in meters, of each of the following; (a) a mouse, (b)...

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