manswered Question 13 0/8 pts Two parallel metal plates have a uniform electric field between them...
Two parallel metal plates have a uniform electric field between them of 3 N/C. There is a uniform magnetic field of 0.18 T applied perpendicularly to the electric field. An electron in an electron beam is aimed between the plates as shown b. What is the magnitude of the electric force on the electron as it travels through the electric field? Answer in terms of "x"x10-19N ++++ +++++
Two parallel plates have a uniform electric field between them. What is the connection between the field strength and the voltage between the plates?
19. [6 pts] An electron moving with a velocity v enters a region between two parallel plates that are 6 mm apart. The electron is deflected toward the bottom plate. On the diagram, draw and label the following vectors: (a) The electric field vector due to the parallel plates at the location of the electron. Label it E (b) The electric force vector acting on the electron. Label it FE. Your answer must be consistent with part (a). (c) The...
Two large, parallel, metal plates are charged so as to create a
uniform electric field between them. The plates are squares and
each edge is 1.0 meter long. One plate is given a net electrical
charge of +0.17708 nano-Coulomb and it is located to the left of
the center of the space between the plates. The other plate is
charged oppositely to -0.17708 nano-Coulomb and it is located to
the right of center. The plates are separated by some distance...
EL These two parallel metal plates of length L-1.0 m have a uniform electric field of strength 1000 N/C between them, pointing up in the positive y-direction. A positive charge q-1x 1016 C of mass m-1.0x 10-17kg is shot horizontally at speed Vo-1000 m/s in the x-direction between them. It will be deflected as shown. Neglect gravity, how far apart are the plates in m if the charge just barely grazes the top plate before exiting the apparatus?
A uniform electric field exists in a region between two oppositely charged parallel plates. An electron is released from rest at the surface of the negatively charged plate and strikes the surface of the opposite plate, 2 cm distant from the first, in a time interval of 1.5x10 s. (a) Find the electric field , (b) find the velocity of the electron when it strikes the second plate.
Two large parallel copper plates are 4.86 cm apart and have a uniform electric field of magnitude E = 5.60 N/C between them (see Figure). An electron is released from the negative plate at the same time that a proton is released from the positive plate. Neglect the force of the particles on each other and find their distance from the positive plate when they pass each other.
Two large parallel copper plates are 6.32 cm apart and have a uniform electric field of magnitude E = 4.41 N/C between them (see the figure). An electron is released from the negative plate at the same time that a proton is released from the positive plate. Neglect the force of the particles on each other and find their distance from the positive plate when they pass each other Positive plate P Negative plate
Two very large parallel plates with a uniform surface charge
density
are seperated by a distance d.
a) Show that the electric field between the plates
b) Using solid lines, draw the electric field.
c) If an electron were to enter between the plates with a
velocity along the +x direction, draw the path of its motion.
L04. An electron with charge-e is injected as shown into a uniform electric field between two parallel metal (conducting) plates as shown below. (Ignore the effects of gravity in this calculation) v, 3.00x 10'm/s and E- 1.00 x 10 N/C. Note that coordinate axes are given in the diagram; the initial velocity of the electron is parallel to the x-axis, and the electric field is parallel to the y-axis. (Look up values -e the charge and m the electron). Electron...