Ranking velocities of particles in uniform magnetic field

In summary, the particles A, B, C, D, and E have equal mass and enter a region of uniform magnetic field. The largest to smallest velocity ranking cannot be determined due to lack of information about the charges of the particles. The radius of a particle's trajectory is not solely determined by its speed, but also by its charge. The formula v = qBr/m shows that the velocity is dependent on the charge, and without knowledge of the charges, the problem cannot be solved.
  • #1
Linus Pauling
190
0
1. Five equal-mass particles (A–E) enter a region of uniform magnetic field directed into the page. They follow the trajectories illustrated in the figure.

1011734.jpg


Rank from largest to smallest velocity



2. qvBsin(theta) = ma
qvB = ma = m(v^2/r)
v = qBr/m




3. Based on their radii, it should be A > B > C=E

But what about D? It is neutral, so has no radius because it doesn't go in a circle, but clearly has a velocity despite r = 0. Is the answer indeterminate, then?
 
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  • #2
I think you're meant to assume that all particles have the same charge; otherwise, the problem would be unsolvable. So assuming they have the same charge, D appears to go straight because it's barely affected by the magnetic field. What does that tell you about its velocity?
 
  • #3
The answer actually was that it couldn't be determined.

Now I am asked to rank the speeds largest to smallest of A, B, C, and E. I thought it was clearly A > B > C=E, but it is not and it tells me this:

The radius of the trajectory of a particle depends on more than just its speed. Be sure not to make assumptions about the relative magnitudes of the charges.

WTF?
 
  • #4
Linus Pauling said:
v = qBr/m
The velocity depends on the charge, and you are not given any information about the charges. Therefore the problem is not solvable.
 
  • #5
nvmm
 
Last edited:

1. What is a uniform magnetic field?

A uniform magnetic field is a magnetic field that has a consistent strength and direction at all points within a given area. This type of magnetic field is often created by placing a magnet in a specific orientation or by running an electric current through a wire in a specific direction.

2. How are particles affected by a uniform magnetic field?

Particles with an electric charge will experience a force when placed in a uniform magnetic field. The direction of this force is perpendicular to both the direction of the magnetic field and the direction of the particle's velocity. The magnitude of the force depends on the strength of the magnetic field, the charge of the particle, and its velocity.

3. How do we rank the velocities of particles in a uniform magnetic field?

The ranking of velocities of particles in a uniform magnetic field is based on the direction and magnitude of the force they experience. The particle with the greatest velocity and perpendicular component of velocity will experience the greatest force and therefore have the highest ranking. The particle with no perpendicular component of velocity will not experience any force and will have the lowest ranking.

4. What factors can affect the ranking of velocities in a uniform magnetic field?

Aside from the strength and direction of the magnetic field, the ranking of velocities can also be affected by the mass and charge of the particles, as well as the angle between the direction of the particle's velocity and the direction of the magnetic field. Additionally, the presence of other particles or external forces can also affect the ranking.

5. How is the ranking of velocities used in scientific research?

The ranking of velocities in a uniform magnetic field is important in various fields of science, such as particle physics and plasma physics. It helps scientists understand the behavior of charged particles in magnetic fields and can be used to make predictions about the movement of particles in complex systems. This information is crucial in areas such as nuclear fusion and the development of new technologies, such as particle accelerators.

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