Table of Contents
- 1 Which of them will move in a circular path with higher frequency?
- 2 Which has more frequency electron or proton?
- 3 What will be the path of a charged particle moving in a uniform electrostatic field?
- 4 Which has larger wavelength an electron or proton?
- 5 Why do electrons move in a helical path?
- 6 What happens when a proton and electron travel along parallel paths?
- 7 Why is magnetic force perpendicular to the direction of motion?
Which of them will move in a circular path with higher frequency?
electron
Thus electron move in circular path with higher frequency. A proton and an electron travelling along parallel patha enters a region of uniform magnetic field, acting perpendicular to their paths.
What is the path of a charged particle moving perpendicular to a uniform magnetic field?
Circle is the trajectory of charged particle moving perpendicular to the direction of uniform magnetic field.
Which has more frequency electron or proton?
The particles with the mass less can move faster than the larger mass particles. This is because the frequency is inversely proportional to the mass. Thus both the electron and the proton moves in the circular path but the electron moves at a greater frequency than the proton.
Why does a proton move in a circle in a magnetic field?
Protons in giant accelerators are kept in a circular path by magnetic force. Magnetic force is always perpendicular to velocity, so that it does no work on the charged particle. The particle’s kinetic energy and speed thus remain constant. The direction of motion is affected, but not the speed.
What will be the path of a charged particle moving in a uniform electrostatic field?
The charged particle will experience electrostatic force along the direction of field and will continue to move perpendicular to the field.So the path is superposition of two straight line paths,which is parabola.
What is the path of a charge particle moving in a magnetic field with velocity parallel to the magnetic field?
Constant Velocity Produces a Straight-Line If a charged particle’s velocity is parallel to the magnetic field, there is no net force and the particle moves in a straight line.
Which has larger wavelength an electron or proton?
A. The electron. The de Broglie hypothesis says the wavelength of a particle’s matter wave is inversely proportional to its momentum. Therefore the smaller mass and smaller momentum of the electron means that it has a longer wavelength.
Why do moving charge electron move in circular path in magnetic field?
1). If the field is in a vacuum, the magnetic field is the dominant factor determining the motion. Since the magnetic force is perpendicular to the direction of travel, a charged particle follows a curved path in a magnetic field. The result is uniform circular motion.
Why do electrons move in a helical path?
The electrons move on helix trajectories. Reason therefor is, that the inital speed v0 is not perpendicular to the magnetic field B. v⊥ causes the orbital motion, v∥ causes a motion in the direction of the magnetic field. So the electrons drift on a helix trajectory.
Which particles will move in a circular path perpendicular to their paths?
A proton and an electron travelling along parallel paths enter a region of uniform magnetic field, perpendicular to their paths. Which of them will move in a circular path with higher frequency? When a charge particle enters a region of uniform magnetic field, perpendicular to their paths, they move in a circular path.
What happens when a proton and electron travel along parallel paths?
A proton and an electron travelling along parallel paths enter a region of uniform magnetic field, perpendicular to their paths. Which of them will move in a circular path with higher frequency?
How does a magnetic field affect the motion of a particle?
Circular motion in a magnetic field. Charged particles in a magnetic field feel a force perpendicular to their velocity. Since their movement is always perpendicular to the force, magnetic forces due no work and the particle’s velocity stays constant.
Why is magnetic force perpendicular to the direction of motion?
Another way to look at this is that the magnetic force is always perpendicular to velocity, so that it does no work on the charged particle. The particle’s kinetic energy and speed thus remain constant. The direction of motion is affected but not the speed.