A proton traveling to the right moves in between the two large plates. A vertical electric field, pointing downwards with magnitude 3.0N/C, is produced by the plates.
A proton traveling to the right moves in between the two large plates. A vertical electric...
A proton moving at 3.0 106 m/s passes into the region between two parallel conductors. The region between the plates has a constant electric field pointing to the right of magnitude 2.0 x 104 N/C. a) what acceleration does the proton experience between the plates? b) if the plates were 3 cm apart what is the speed of the proton as it exits the plates?
A proton is to be levitated by placing it between two large, parallel, horizontal plates 0.1 m apart. What is the potential difference between the plates? Which plate is at a higher potential? Begin by sketching the setup, a free-body diagram of the proton, and the direction of the electric field.
The electric field between the plates of the capacitor shown in the figure below is 1.12 !105 N / m and the applied magnetic field is everywhere 0.54T. Once leaving the electric field region, a stream of singly ionized selenium ions moves in a circular path with a radius of 31cm in the magnetic field. (a) Copy the figure below onto your paper, and draw in the electric field corresponding to the given situation, as well as the electric force...
A proton enters a parallel-plate capacitor traveling to the right at a speed of 1.276 x 10-5 m/s, as shown in the figure. The distance between the two plates is 1.62 cm. The proton enters the capacitor halfway between the top plate and the bottom plate; that is, a distance r = 0.810 cm from each plate, as shown in the figure. The capacitor has a 2.95 x 10* N/C uniform electric field between the plates that points downward from...
A Proton between Oppositely Charged Plates A uniform electric field exists in the region between two oppositely charged parallel plates 1.55 cm apart. A proton is released from rest at the surface of the positively charged plate and strikes the surface of the opposite plate in a time interval 1.56x10-6 s. Part A Find the magnitude of the electric field. Use 1.60x10-19 C for the magnitude of the charge on an electron and 1.67x10-27 kg for the mass of a...
3. A proton enters a uniform electric field created by two charged parallel plates, as in the diagram below. The electric field is uniform and has a magnitude is 2000 N/C. (a) Transfer the diagram to your answer sheet and show clearly which plate is positively charged and which is negatively charged. (b) Draw the electric force acting on the proton. (c) Calculate the acceleration of the proton. (d) Calculate the time the electron spends in the electric field if...
A proton traveling at v= 4.65 x 10° m/s to the right enters the region between two parallel charged plates separated by a distance d = 5.09 cm that also contains a uniform magnetic field out of the page of field strength B = 8.47 ut. a What does the potential difference across the plates have to be for the proton to continue traveling at constant velocity? Express your answer using two decimal places. Your answer should be in V.
Consider an experimental setup where charged particles (electrons or protons) are first accelerated by an electric field and then injected into a region of constant magnetic field with a field strength of 0.25 T.Part (a) What is the potential difference, in volts, required in the first part of the experiment to accelerate electrons to a speed of 5.95 x 107 m/s?Part (b) Find the radius of curvature, in meters, of the path of a proton accelerated through this same potential...
A proton enters a parallel-plate capacitor traveling to the right at a speed of 1.276 x 10-5 m/s, as shown in the figure. The distance between the two plates is 1.59 cm. The proton enters the capacitor halfway between the top plate and the bottom plate; that is, a distance r = 0.795 cm from each plate, as shown in the figure. The capacitor has a 2.75 x 10-4 N/C uniform electric field between the plates that points downward from...
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 ++++ +++++