Forces on a Positively Charged Particle in an Electric & Magnetic Field

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Homework Help Overview

The discussion revolves around determining the directions of forces acting on a positively charged particle in the presence of electric and magnetic fields, as described in a specific figure. Participants are exploring the implications of the right-hand rule and the relationship between electric and magnetic fields.

Discussion Character

  • Exploratory, Conceptual clarification, Assumption checking

Approaches and Questions Raised

  • Participants are attempting to apply the right-hand rule to ascertain the direction of the magnetic force and are questioning how to determine the electric force. There is discussion about the definitions of electric fields and their relationship to the forces on charged particles.

Discussion Status

Some participants have provided insights into the right-hand rule and its variations, while others are seeking clarification on the relationship between electric and magnetic fields. There is an ongoing exploration of how these forces interact and the assumptions underlying their directions.

Contextual Notes

Participants are grappling with the definitions and properties of electric and magnetic fields, particularly regarding their perpendicular nature and the implications for the forces acting on charged particles. There is mention of potential confusion regarding the application of the right-hand rule.

jlmessick88
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Homework Statement


Assuming the particle in Figure P24.62 is positively charged, what are the directions of the forces due to the electric field and to the magnetic field?
a. The force due to the electric field is directed up (toward the top of the page); the force due to the magnetic field is directed down (toward the bottom of the page).
b. The force due to the electric field is directed down (toward the bottom of the page); the force due to the magnetic field is directed up (toward the top of the page).
c. The force due to the electric field is directed out of the plane of the paper; the force due to the magnetic field is directed into the plane of the paper.
d. The force due to the electric field is directed into the plane of the paper; the force due to the magnetic field is directed out of the plane of the paper.




The Attempt at a Solution


Now if i use the right hand rule where my thumb is the velocity, my index finger is the mag. field, and my middle finger is the force, then the mag. field is pointed up and the force on the proton is pointed out of the plane of the paper...but I'm not sure how I'm supposed to solve for the electric field??
any suggestions??
 

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The force that an electric field exerts on a positively charged particle is parallel to the field. (For a negatively charged particle, it's in the opposite direction, antiparallel to the field.)
 


so with that in mind, the electric field would be directed out the plane of the paper?
 


jlmessick88 said:

Homework Statement


Assuming the particle in Figure P24.62 is positively charged, what are the directions of the forces due to the electric field and to the magnetic field?
a. The force due to the electric field is directed up (toward the top of the page); the force due to the magnetic field is directed down (toward the bottom of the page).
b. The force due to the electric field is directed down (toward the bottom of the page); the force due to the magnetic field is directed up (toward the top of the page).
c. The force due to the electric field is directed out of the plane of the paper; the force due to the magnetic field is directed into the plane of the paper.
d. The force due to the electric field is directed into the plane of the paper; the force due to the magnetic field is directed out of the plane of the paper.




The Attempt at a Solution


Now if i use the right hand rule where my thumb is the velocity, my index finger is the mag. field, and my middle finger is the force, then the mag. field is pointed up and the force on the proton is pointed out of the plane of the paper...but I'm not sure how I'm supposed to solve for the electric field??
any suggestions??

That's a right hand rule I haven't seen before, but it seems to work. I usually point my four fingers in direction of the Velocity vector of the particle, curl my fingers in the direction of the Magnetic Field Vector, and my thumb points in the direction of the Mag. Force.

For your question, you should first think about how Electric Fields are defined starting from Coulomb's Law. That ought to take you into the correct direction on figuring out the Electric Force on the positive particle due to the Electric Field.
 


Maxwellkid said:
That's a right hand rule I haven't seen before, but it seems to work. I usually point my four fingers in direction of the Velocity vector of the particle, curl my fingers in the direction of the Magnetic Field Vector, and my thumb points in the direction of the Mag. Force.
It's the way I first learned it (I mean the RHR that jlmessick88 described), and still my favorite variation of the right-hand rule. Partially because it doubles as a frisbee grip :wink: but I digress.
 


jlmessick88 said:
Now if i use the right hand rule where my thumb is the velocity, my index finger is the mag. field, and my middle finger is the force, then the mag. field is pointed up and the force on the proton is pointed out of the plane of the paper...but I'm not sure how I'm supposed to solve for the electric field??
any suggestions??

how can you get your middle finger to point down if you place your palm facing upwards? There are 2 ways you can position your index finger to point out of the xy plane.

I don't think that's a sound version of the right hand rule. try it the other way. Also, if you are using electrons as your particle, then you can switch hands to form the LEFT hand rule!
 


i guess I'm still not getting it...everything that i read shows that the electric field and the mag. field are always perpendicular...all of my answers indicate that they are opposite from each other...how??
 

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