A proton (m= 1.67e-27 kg) is accelerated from rest through a potential difference of 11.5 kV before entering a velocity selector. If the B- field of the velocity selector is perpendicular to the velocity and the electric field (E) has a magnitude of 3.5e6 N/C, what is the required magnitude of the magnetic field (B) if the proton is undeflected?
A proton (m= 1.67e-27 kg) is accelerated from rest through a potential difference of 11.5 kV...
A beam of electrons is accelerated through a potential difference of 11.0 kV before entering a velocity selector. If the B-field of the velocity selector is perpendicular to the velocity and has a value of 0.02 T, what value of the E-field is required (in the magnetic field region) if the particles are to be undeflected? answer in V/m
4. A beam of electrons is accelerated through a potential difference of 10.0 kV before entering a velocity selector. If the B-field of the velocity selector is perpendicular to the velocity and has a value of 0.02 T, what value of the E-field is required (in the magnetic field region) if the particles are to be undeflected? V/m
4. A beam of electrons is accelerated through a potential difference of 12.0 kV before entering a velocity selector. If the B-field of the velocity selector is perpendicular to the velocity and has a value of 0.03 T, what value of the E-field is required (in the magnetic field region) if the particles are to be undeflected? V/m
A beam of electrons is accelerated through a potential difference of 12.0 kV before entering a velocity selector. If the B-field of the velocity selector is perpendicular to the velocity and has a value of 0.02 T, what value of the E-field is required (in the magnetic field region) if the particles are to be undeflected? It's not 1.949*10^6.
A beam of electrons is accelerated through a potential difference of 10 kV before entering a region having uniform electric and magnetic fields that are perpendicular to each other and perpendicular to the direction in which the electron is moving. If the magnetic field in this region has a value of 0.010 T, what magnitude of the electric field is required if the particles are to be undeflected as they pass through the region?
A proton is accelerated from rest through a potential differences of 1.0 kV. It enters a uniform magnetic field of 4.5 mT that is initially perpendicular to its velocity. (a) Find the radius of the proton's circular path (b). Calculate the period of revolution of the proton.
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?
(c) A proton is accelerated from rest through a potential difference of 10 kV. A proton has chargeqproton = +1.6 10-19 C and mass mproton = +1.67 10-27 C i. Calculate the change in potential energy of the proton, in your answer you must explicitly state whether it is a gain or loss in potential energy. ii. Calculate the final velocity of the proton.
A proton, that is accelerated from rest through a potential of 13.0 kV enters the velocity filter, consisting of a parallel-plate capacitor and a magnetic field, shown below. The E-field between the parallel capacitor plates is 3.9·105 N/C. What B-field is required so that the protons are not deflected? (Ignore relativistic effects for high velocities.)
A proton accelerated through a potential of 12.0 kV enters a device which has both an electric and a magnetic field, that are perpendicular to each other as shown in the figure. This device is known as a "velocity filter", because only protons with a given velocity are not deflected and continue their trajectory along the y-axis through the aperture shown in the figure. Indicate the directions of both the electric force and the magnetic force. +x -x +y -y...