Trajectory of an electron in cathode ray tubes

AI Thread Summary
An electron in a magnetic field travels in a circular path due to the force being always perpendicular to its velocity, maintaining constant speed while changing direction. In contrast, when subjected to an electric field, the force acts in a constant direction, resulting in a parabolic trajectory as the electron accelerates. The magnetic force changes direction as the electron moves, while the electric force remains constant, leading to different motion patterns. The equations governing these forces, F=qVXB for magnetic fields and F=qE for electric fields, illustrate their distinct effects on charged particles. Understanding these principles is crucial for comprehending electron behavior in cathode ray tubes.
mattg443
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Why is it that an electron traveling under the influence of a magnetic field (i.e electron going from left to right and B field going into the page) will travel in the arc of a circle

yet when an electric field alone is applied (say up page and the direction of motion of the electron is the same) the electron will travel in a parabolic path? when in both cases, a force is exerted on the electron is downwards?
 
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The force the magnetic field exerts on a moving charged particle is perpendicular to both the magnetic field and the velocity of the particle. The acceleration is normal to the velocity: only the direction of the velocity changes, its magnitude does not. This is circular motion.
 
mattg443 said:
yet when an electric field alone is applied (say up page and the direction of motion of the electron is the same) the electron will travel in a parabolic path? when in both cases, a force is exerted on the electron is downwards?

The force due to the magnetic field is not constantly downwards. It may initially be downwards, but as it changes the direction of the velocity, the force will also change direction; even though the magnetic field remains the same.

the force from a magnetic field is given by
F=qVXB (resulting in circular motion)

and for the electric field alone,
F=qE.

Bold letters are vectors. hope this helps!
 

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