Physics Problem 22: Mass of Charged Object in Electric Field

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In summary, the problem involves finding the mass of an object with a net charge of 40 uC placed in a uniform electric field of 572 N/C. The formula used is F=qE, where F is the force experienced by the charge q in the field E. The force must be equal to the weight of the object in order for it to float, so the equation to solve is qE=mg, where g=9.81m/s^2. The mass can be found by solving for m. This equation can be derived from Coulomb's law, which describes the force between two point charges. The charge of the object and the source of the electric field are not important, only the strength of the field matters.
  • #1
mustang
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Problem 22.
given: g=9.814m/s^2.
An object with a net charge of 40 uC is placed in a uniform electric field of 572 N/C, directed vertically.
What is the mass of this object if it floats in this electric field? In units of kg.
Note: What formula would you use?
 
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  • #2
Use Equilibrium Condition, Relation b/w Field and Force
 
  • #3
I need more help. What does "b" and "w" mean?
 
  • #4
"b" and "w" don't mean anything. humanshu121 was using b/w to mean "between".
 
  • #5
I having a hard time solving problem since I don't know what formula I should use and the values to "sub" in.
 
  • #6
What is the formula for the force experienced by a charge q in an electric field of magnitude E?
 
  • #7
Would that formula be Electric field strength=Coulomb constant* charge producing the field(q)/(distance)^2.
 
  • #8
No -- that formula describes the strength of the field PRODUCED by a charge q.

You want the force EXPERIENCED by a charge q under the influence of a field from some other source.
 
  • #9
Is the formula electric force=Coulomb constant*(charge1)(charge2)/(distance)^2
 
  • #10
Not exactly, but you could find the right one "hidden" in there (because in there you have included the expression that you wrote up above for the field produced by a charge).
 
  • #11
I'm comfused?
 
  • #12
You have two forces,

1.weight from the mass acting towardds the earth
2.an electric force from the electric field, the key equation here is that: the force on a charged particle is its charge times the field -> F = qE

Note: Coulomb law is that just mentioned without the charge of the particle in question. Coulmbs law is with q1 and q2 is between two paticles, in this case the electric field is probably produced by large metal plates with millions of particles in them - point is how the field is made is not important.
 
  • #13
If the field E1 produced by a point charge q1 is
E1 = keq1/r2

and the force exerted on point charge q2 by point charge q1 is
F12 = keq1q2/r2

just substitute the formula up above for E to get
F12 = q2E1

Here, you aren't dealing with 2 point charges. Instead you have 1 point charge in a uniform field from some unspecified source. But as dodger said, the formula above can be generalized, so the force on a charge q from any uniform field is
F = qE

Now you just have to find the conditions so that force exactly offsets the weight of the particle -- basically a geometry question.
 
  • #14
This subject should not be a confusing thing, a field is produced by charged stuff and this exerts a force on other charged stuff, the size of this force (as given by the equation i said) tells you how big a force acts on the charged thing. Stop and think about it - if you have a charged particle in an electric field and you double its charge the effect on it goes the same - the force on it doubles. The same effect would happen if the field was doubled - the force on it would double.
 
  • #15
Right.

And forget about my unnecessary "geometry" comment.

There's really no geometry to deal with here. One force (the weight) acts straight down and the other (the electrical force) acts straight up (do you see why?).

If the object floats, these two forces must be equal, right? Simple algebra. Just solve for m.
 
  • #16
So F=qE is bascially F=ma, Right.
 
  • #17
Right; well, F=qE=F=mg.

I assume you meant g, right?
 
  • #18
So the equation to solve this problem is qE=mg, where g=9.81m/s^2, E=572N/C, and q= 40*10^-6.
 
  • #19
Correct.
 
  • #20
Thanks!

Thank you!
 

What is the formula for calculating the mass of a charged object in an electric field?

The formula for calculating the mass of a charged object in an electric field is: m = qE/F, where m is the mass in kilograms, q is the charge in coulombs, E is the electric field strength in newtons per coulomb, and F is the force in newtons.

How do I determine the direction of the electric force on a charged object?

The direction of the electric force on a charged object can be determined using the right-hand rule. Simply point your thumb in the direction of the electric field and your fingers in the direction of the charge's motion. The direction in which your palm is facing is the direction of the electric force.

What factors affect the mass of a charged object in an electric field?

The mass of a charged object in an electric field is affected by the strength of the electric field, the magnitude of the charge, and the direction of the force on the object. Additionally, the mass of the object itself will also play a role in the calculation.

Can the mass of a charged object in an electric field be negative?

Yes, the mass of a charged object in an electric field can be negative. This would occur if the direction of the electric force and the direction of the object's motion are in opposite directions, resulting in a negative mass value.

What units are used to measure the mass of a charged object in an electric field?

The mass of a charged object in an electric field is typically measured in kilograms (kg). However, it is also common to use grams (g) or even milligrams (mg) for smaller objects.

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