An electron falls through a distance d in a uniform electric
field of magnitude E. Thereafter, the direction of the field is
reversed (keeping its magnitude the same) and now a proton falls
through the same distance. Compare, using quantitative reasoning,
the time of fall in each case.
Contrast this situation with that of objects falling freely under
gravity.
An electron falls through a distance d in a uniform electric field of magnitude E. Thereafter,...
An electron falls through a distance d in a uniform electric field of magnitude E. Thereafter, the direction of the field is reversed (keeping its magnitude the same) and now a proton falls through the same distance. Compare, using quantitative reasoning, the time of fall in each case. Contrast this situation with that of objects falling freely under gravity. Also, make sure that your response(s) are substantial and consist of at least 30 words.
For this discussion, respond to the following... An electron falls through a distance d in a uniform electric field of magnitude E. Thereafter, the direction of the field is reversed (keeping its magnitude the same) and now a proton falls through the same distance. Compare, using quantitative reasoning, the time of fall in each case Contrast this situation with that of objects falling freely under gravity
Subscribe For this discussion, respond to the following.. An electron falls through a distance d in a uniform electric field of magnitude E. Thereafter, the direction of the field is reversed (keeping its magnitude the same) and now a proton falls through the same distance. Compare, using quantitative reasoning, the time of fall in each case. Contrast this situation with that of objects falling freely under gravity
Q5. A uniform electric field of magnitude E 360 V/m is directed in the positive X direction. A proton moves from the origin to the point (x, y)-(30.0 cm, 40.0 cm). (a) Through what potential difference does the charge move? Show your work to score. (b) What is the change in the potential energy of the charge field system? Show your work to score. (c) In this uniform electric field E mentioned above, if an electron was released at rest...
A proton is released from rest in a uniform electric field of magnitude 376 N/C. (a) Find the electric force on the proton. magnitude N direction ---Select--- in the direction of the electric field in the opposite direction of the electric field The magnitude is zero. (b) Find the acceleration of the proton. magnitude m/s2 direction ---Select--- in the direction of the electric field in the opposite direction of the electric field The magnitude is zero. (c) Find the distance...
A proton is released from rest in a uniform electric field of magnitude 403 N/C. (a) Find the electric force on the proton. magnitude N direction ---Select--- in the direction of the electric field in the opposite direction of the electric field The magnitude is zero. (b) Find the acceleration of the proton. magnitude m/s2 direction ---Select--- in the direction of the electric field in the opposite direction of the electric field The magnitude is zero. (c) Find the distance...
An electron is released from rest in a uniform electric field. The electron accelerates vertically upward, traveling 4.65 m in the first 1.90 µs after it is released. (a) What are the magnitude and direction of the electric field? magnitude N/C direction (b) Are we justified in ignoring the effects of gravity? Yes No
an electron and a proton are fixed at a separation distance of 839 nm. find the magnitude and direction of the electric field at their midpoint i know the direction is either: toward the proton, perpendicular to the line of the particles, or toward the electron, or it cannot be determined
2. An electron and a proton are each placed at rest in a uniform electric field of magnitude 4000 N/C. Determine the magnitude and direction of each particle's velocity 100.0 ns after being released.
A proton is acted on by an uniform electric field of magnitude 273 N/C pointing in the negative y direction. The particle is initially at rest. (a) In what direction will the charge move? (b) Determine the work done by the electric field when the particle has moved through a distance of 3.25 cm from its initial position. (c) Determine the change in electric potential energy of the charged particle. d) Determine the speed of the charged particle.