A proton travels with speed 1.0 x 107 m/s between two parallel charged plates as shown...
An electron travels with speed 9.0×106 m/s between the two parallel charged plates shown in the figure. The plates are separated by 1.0 cm and are charged by a 200 V battery. (Figure 1) What magnetic field strength will allow the electron to pass between the plates without being deflected?
An electron travels with speed 0.70×107m/s between the two parallel charged plates shown in the figure(Figure 1) . The plates are separated by 1.0 cm and are charged by a 200 V battery. What magnetic field strength will allow the electron to pass between the plates without being deflected?
As the electrons are accelerated through the second anode, the gain in kinetic energy is 2.0 x 10-15 J, and the speed of the electrons as they enter the region between the plates is 6.6 x 107 m/s. The electrons are moving to the right as they pass between the plates. The plates are 2.0 cm long, 1.0 mm apart, and as the electrons pass between the plates, the potential difference is 450 V. Determine the time it takes to...
3. (8 pts) For the circuit below, write two loop equations (2V-0) and one junction equation DO NOT SOLVE THE ALGEBRA, but enter the resistor and emf values in the three equat esistors. Include a detailed diagram showing the direction of the currents and sign conventions across 12V 5Ω 10Ω 3V 52 9 V pts) An electron travels with speed 0.60x 10'm/s between the two parallel charged plates shown in the . The plates are separated by 1.0 cm and...
A proton is accelerated through a 3.11 kV potential difference and directed between parallel plates separated 12.3 mm as shown below. The EMF of the battery is 10.0 V. What is the magnitude and direction of the uniform magnetic field between the plates that allows the proton to travel undeflected?
A negatively charged particle enters a region between two parallel plates. Each plate (top and bottom) are oppositely charged, hence the exists a uniform electric field between the plates along with a gravitational field). Assume the particle travels the region straight through completely un-deflected and exits. a) Determine and identify below) te polarities of the plates and the resulting Electric Field direction inside the plated region needed so the particle travels through un-deflected: b) If the particle has a mass...
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.
A positively charged particle is moving from right to left between two parallel charged plates. A uniform magnetic field between the plates is chosen such that the particle is not deflected. The direction of the magnetic field is + into the page out of the page toward the top of the page toward the bottom of the page
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 charged particle with a positive net electric charge travels with a velocity of 2×107 m.s-1 in the positive x-direction between two plates of a parallel plate capacitor. A uniform magnetic field of 2 mT that is directed into the page also exists in the same location as the capacitor. a. If the parallel plates of the capacitor are separated by 3 cm, determine the voltage required over the plates in order to stop any deflection of the particle. V = __________ V b. ...