How Do You Calculate Charge and Distance from Electric Potential and Field?

AI Thread Summary
The discussion focuses on calculating the charge (q) and distance (r) from a point charge based on given electric potential and electric field values. The correct equations for electric potential (V = kq/r) and electric field (E = kq/r^2) are highlighted as essential for solving the problem. A participant expresses confusion over the calculations and suggests that their method for finding r may be flawed. It is emphasized that the equations must be verified against class materials, as they are fundamental to the topic. Understanding these principles is crucial for accurately determining the values of charge and distance in electrostatics.
nfcfox
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Homework Statement


The electric potential a distance r from a point charge q is 195 V, and the magnitude of the electric field is 2870 N/C. Find the values of q and r.

Homework Equations


2780q=F
Fr=W
W/q=195

The Attempt at a Solution


Using substitution I got r=.00679 meters, which is correct. I can't substitute to find q... I have no idea what to do.
 
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What are the equations for the electric field and electric potential at a distance r from a point charge q? Your text or class notes must have these two equations as they are quite fundamental. Hint: They both involve the constant from Coulomb's law.
 
gneill said:
What are the equations for the electric field and electric potential at a distance r from a point charge q? Your text or class notes must have these two equations as they are quite fundamental. Hint: They both involve the constant from Coulomb's law.
Ik the equation F=(kQ1Q2)/(r^2) that's Coulomb's law. We never really did anything with fields or potentials... I found that electric field=F/q which I already have up there.
gneill said:
What are the equations for the electric field and electric potential at a distance r from a point charge q? Your text or class notes must have these two equations as they are quite fundamental. Hint: They both involve the constant from Coulomb's law.
I already have the electric field equation up there and the electric potential is U=(kQq)/r
 
nfcfox said:
Ik the equation F=(kQ1Q2)/(r^2) that's Coulomb's law. We never really did anything with fields or potentials... I found that electric field=F/q which I already have up there.

I already have the electric field equation up there and the electric potential is U=(kQq)/r
I suspect that your method for finding the distance r was actually flawed, and your correct result was a coincidence. I say this because one of your relevant equations, Fr = W, is not correct for this situation. If F is meant to be force and W the work done, then it doesn't hold if the force varies with the distance (F is not constant so W = F⋅d doesn't hold).

Your new equation, U=(kQq)/r, gives the electric potential energy (in Joules) for a system of two charges. That's the energy required to bring them from infinity to a separation distance of r. What you need is the electric potential (in Volts) for a point charge at distance r.

The equations that you're seeking are:

##E = k \frac{q}{r^2}~~~~~~~~~~## Electric field strength (N/C)

##V = k \frac{q}{r}~~~~~~~~~~~## Electric potential (Volts)

You should verify that these equations are given in your textbook.
 

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