A particle with charge 2.50 µC and mass 3.00x10-11 kg is initially traveling in the +y-direction with a speed vo = 1.60x10° m/s. It then enters a region containing a uniform magnetic field that is directed into, and perpendicular to, the page in the figure (Figure 1). The magnitude of the field is 0.450 T. The region extends a distance of 25.0 cm along the initial direction of travel; 75.0 cm from the point of entry into the magnetic field region is a wall. The length of the field- free region is thus 50.0 cm. When the charged particle enters the magnetic field, it follows a curved path whose radius of curvature is R. it then leaves the magnetic field after a time ti, having been deflected a distance Azz. The particle then travels in the field-free region and strikes the wall after undergoing a total deflection Az. Part A Determine the radius R of the curved part of the path. Express your answer in meters. VO AE R = m Submit Request Answer Figure < 1 of 1> Part B Wall Determine t1, the time the particle spends in the magnetic field. Express your answer in seconds. Πνα ΑΣφ 5.0cm t1 =

A particle with charge 2.50 µC and mass 3.00x10-11 kg is initially traveling in the +y-direction with a speed vo = 1.60x10° m/s. It then enters a region containing a uniform magnetic field that is directed into, and perpendicular to, the page in the figure (Figure 1). The magnitude of the field is 0.450 T. The region extends a distance of 25.0 cm along the initial direction of travel; 75.0 cm from the point of entry into the magnetic field region is a wall. The length of the field- free region is thus 50.0 cm. When the charged particle enters the magnetic field, it follows a curved path whose radius of curvature is R. it then leaves the magnetic field after a time ti, having been deflected a distance Azz. The particle then travels in the field-free region and strikes the wall after undergoing a total deflection Az. Part A Determine the radius R of the curved part of the path. Express your answer in meters. VO AE R = m Submit Request Answer Figure < 1 of 1> Part B Wall Determine t1, the time the particle spends in the magnetic field. Express your answer in seconds. Πνα ΑΣφ 5.0cm t1 =

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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Question

Constants
A particle with charge 2.50 µC and mass 3.00x10-11 kg is initially
traveling in the +y-direction with a speed vo = 1.60x105 m/s. It then
Part A
enters a region containing a uniform magnetic field that is directed
into, and perpendicular to, the page in the figure (Figure 1). The
magnitude of the field is 0.450 T. The region extends a distance of
25.0 cm along the initial direction of travel; 75.0 cm from the point of
entry into the magnetic field region is a wall. The length of the field-
free region is thus 50.0 cm. When the charged particle enters the
magnetic field, it follows a curved path whose radius of curvature is
R. It then leaves the magnetic field after a time tı, having been
deflected a distance Azj. The particle then travels in the field-free
region and strikes the wall after undergoing a total deflection Ar.
Determine the radius R of the curved part of the path
Express your answer in meters.
ινα ΑΣφ
R =
m
Submit
Request Answer
Figure
< 1 of 1 >
Part B
Wall
KAr
Determine t1, the time the particle spends in the magnetic field.
Express your answer in seconds.
D-
Hνα ΑΣφ
?
Ar, 750 cm
25.0 cm
ti =
Submit
Request Answer

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