Shown in the figure below is an experiment with an electron (q = -1.602e-19 Coulombs, m...
Please solve and explain Shown below is an experiment with an electron (q = -1.602e-19 coulombs, m= 9.109e-31 kg) fired into a magnetic field. The magnetic field is of the strenght B=1.19e-04 Tesla and is directed into the screen. The electron is fired with a velocity V=3.66e+06m/s as shown. trajectory a magnetic field Cinto the screen) electron v Trajectory B a) which path is followed by the electron? trajectory A or trajectory B? meters b) What is the radius of...
Shown in the figure below is an experiment with an alpha particle (g = 3.204e-19 Coulombs, m = 6.645e-27 kg) fired into a magnetic field. The magnetic field is of strength B = 0.197 Tesla and is directed into the screen. The alpha is fired with a velocity v = 3.12e+06 m/s as shown. Trajectory A Magnetic Field (into the screen) Alpha Particle Trajectory B Which path is followed by the alpha particle? O Trajectory B Trajectory A What is...
2 An electron (magnitude of its change is (q) = 1.6x109 Coulombs, and mass of an election m = 9.11x103 kg) enters a magnetic field of strength B= 2 x 10t Tesla, with a speed of 1.5*108 m/s perpendicularity and therefore moves in a circle. Calculate the radius of that circle.
5. An electron carrying charge -9 (where q=1.602e-19 C) is moving along the x axis in the +x direction with a velocity ū(x, y, z) = 5 x 107 cm/s. a. We want to make the electron to curve to the right and eventually go in a circle clockwise in the xy plane by applying a magnetic field. To achieve that, the magnetic field should exert a force on the electron that is perpendicular to its direction of motion. Which...
PLEASE SHOW ALL WORK 2 An electron (magnitude of its change is (q) = 1.6*109 Coulombs, and mass of an election me = 9.11x10² kg) enters a magnetic field of strength B= 2 x 10t Tesla, with a speed of 1.5*10%m/s perpendicularly and therefore moves in a circle. Calculate the radius of that circle.
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...
My Notes As shown in the figure, an electron is fired with a speed of 3.64 x 106 m/s through a hole in one of the two parallel plates and into the region between the plates separated by a distance of 0.19 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 velooty of the electron). Determine the magnitude of the magnetic field...
As shown in the figure, an electron is fired with a speed of 3.59 × 106 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...
Consider the situation shown in the figure below. An electric field of 300 V/m is confined to a circular area d = 10.4 cm in diameter and directed outward perpendicular to the plane of the figure. Consider that the field is increasing at a rate of 18.2 V/m . S. (a) What is the direction of the magnetic field at the point P, r = 14.6 cm from the center of the circle? O upwards O downwards (b) What is...
Consider the situation shown in the figure below. An electric field of 300 V/m is confined to a circular area d = 10.5 cm in diameter and directed outward perpendicular to the plane of the figure. Consider that the field is increasing at a rate of 20.8 V/m.s (a) What is the direction of the magnetic field at the point P, r-14.7 cm from the center of the circle? upwards downwards (b) what is the magnitude of the magnetic field...