An electron moves at with a velocity of 0.130 c (c being the speed of light, 3.0×108 m/s) in the direction shown in the figure (Figure 1). There are points: A, B, C, and D, all the same distance d = 2.50 μm from the electron.
A: Find the magnitude of the magnetic field this electron produces at the point A.
B: Find the magnitude of the magnetic field this electron produces at the point B.
C: Find the magnitude of the magnetic field this electron produces at the point C.
D: Find the magnitude of the magnetic field this electron produces at the point D.
An electron moves at with a velocity of 0.130 c (c being the speed of light, 3.0×108 m/s) in the direction...
An electron moves at speed 5.6 x 106 m/s toward the velocity selector shown in (Figure 1). A 0.12-T magnetic field points into the paper. Part A Determine the magnitude of the magnetic force that the magnetic field exerts on the electron. Part B Determine the direction of the magnetic force that the magnetic field exerts on the electron. upward downward Part C What E field magnitude is required so that the electric force exerted on the electron is equal in magnitude and opposite in direction to the...
An electron moves with speed 4x107 m/s in the direction
indicated in the figure, in the presence of a 0.60 T magnetic field
that points in the x direction. What is the magnitude of the force
on the electron?
A. 1.2x10-20 N
B. 2.4x107 N
C. 2.7x10-12 N
D. 0.5 N
E. 3.8x10-12 N
450
An electron moves at 0.5 c (that is, 50% of the speed of light) in the negative y- direction (see 3D diagram z are all mutually perpendicular). There is a magnetic field of 2.5 mT in the z-direction. What is the force on the electron? (Give magnitude and direction!)
An electron that has velocity v=(3x10^5 m/s) and moves along positive x direction through the uniform magnetic field B=(0.8T) which is along the positive z direction. (a) Find the force on the electron (magnitude and direction). (e=1.6x10^-31 kg) (b) Calculate the radius of the electron's path in the magnetic field.
An electron that has velocity (3.4 x 10 m/s)i+ (2.5 x 106 m/s)j moves through a magnetic field B (0.03 Ti (0.15 T)]. (a) Find the force on the electron magnitude X* N direction Etera mumber (b) Repeat your calculation for a proton having the same velocity magnitude direction
As shown in the figure, an electron is fired with a speed of 3.73 x 10 m/s through a hole in one of the two parallel plates and into the region between the plates separated by a distance of 0.24 m. There is a magnetic field in the region between the plates and, as shown, it is directed into the plane of the page (perpendicular to the velocity of the electron). Determine the magnitude of the magnetic field so that...
answer both
QUESTION 1 An electron with velocity - (12 m/s) i moves through a magnetic field B - (4.0T) k. (i), and k denote unit vectors pointing along the x, y, and axes, respectively.) Find the magnitude of the force on the electron 08.77* 10-18N b.3.3 * 10-19 C. 48 N d. 6.0 N QUESTION 2 An electron with velocity - (12 m/s) i moves through a magnetic field B - (4.0T) k. (.), and k denote unit vectors...
An electron with a speed of 5.12 × 108 cm/s in the positive direction of an x axis enters an electric field of magnitude 2.84 × 103 N/C, traveling along a field line in the direction that retards its motion. (a) How far will the electron travel in the field before stopping momentarily, and (b) how much time will have elapsed? (c) If the region containing the electric field is 7.16 mm long (too short for the electron to stop...
An electron with a speed of 5.76 × 108 cm/s in the positive direction of an x axis enters an electric field of magnitude 2.08 × 103 N/C, traveling along a field line in the direction that retards its motion. (a) How far will the electron travel in the field before stopping momentarily, and (b) how much time will have elapsed? (c) If the region containing the electric field is 6.25 mm long (too short for the electron to stop...
An electron with a speed of 6.79 × 108 cm/s in the positive direction of an x axis enters an electric field of magnitude 2.13 × 103 N/C, traveling along a field line in the direction that retards its motion. (a) How far will the electron travel in the field before stopping momentarily, and (b) how much time will have elapsed? (c) If the region containing the electric field is 5.57 mm long (too short for the electron to stop...