Non uniform charge density and electric potential

Click For Summary

Homework Help Overview

The discussion revolves around calculating the electric potential at a point due to a rod with a non-uniform charge density. The rod has a length of 9.8 m and a linear charge density defined as λ = αx, where α is a constant. The point of interest is located 3.59 m away from the rod along the x-axis.

Discussion Character

  • Exploratory, Mathematical reasoning, Assumption checking

Approaches and Questions Raised

  • Participants discuss integrating the charge density over the length of the rod to find the total charge and its contribution to the potential at point A. There are questions about the correct distance to use in the calculations and how to set up the integrals properly.

Discussion Status

Participants are actively exploring the integration process needed to calculate the potential. Some guidance has been provided regarding the setup of the integrals and the interpretation of the variables involved. However, there is still uncertainty about the limits of integration and the correct expressions to use.

Contextual Notes

There are discussions about the assumptions regarding the distance from the charge to the point of interest and the need to clarify the integration limits. Participants are also addressing the implications of the non-uniform charge density in their calculations.

usfelectrical
Messages
5
Reaction score
0
As shown in the figure, a rod of length 9.8 m lies along the x-axis, with its left end at the origin. The rod has a non-uniform linear charge density λ = αx, where α = 0.009 C/m2 and x is the position. Point A lies on the x-axis a distance 3.59 m to the left of the rod, as shown in the figure.
Q is the total charge on the rod. The Coulomb constant is 8.988 × 109 N m2/C2.

Find the potentia at A, and answer in units of volts




the two relevant equations i can find are:
v=kq/r
dv=kdq/r and lambda=qx?


i am completely stuck on this problem and just need to find a way to start it. I though that you might be able to integrate the charge density formula over the total area of the rod and treat that value as Q and then plug that value into v=kq/r where r is the 3.59, but apparently that is worng and i am back to square one with no idea as to what to do
 
Physics news on Phys.org
usfelectrical said:
the two relevant equations i can find are:
v=kq/r
dv=kdq/r and lambda=qx?


i am completely stuck on this problem and just need to find a way to start it. I though that you might be able to integrate the charge density formula over the total area of the rod and treat that value as Q and then plug that value into v=kq/r where r is the 3.59, but apparently that is worng and i am back to square one with no idea as to what to do

The potential is additive, you need to integrate the contribution dV of a small segment of the rod dx with charge dq=λdx for the whole rod:
V(A)=∫(kdq/r)=∫(kλdx/r).

ehild
 

Attachments

  • chargedrod.JPG
    chargedrod.JPG
    3.4 KB · Views: 2,013
Last edited:
wait so then what would be the values for the r? cause i have been using just 3.95 since that's the distance of your point away from the rod but it doesn't work
 
usfelectrical said:
wait so then what would be the values for the r? cause i have been using just 3.95 since that's the distance of your point away from the rod but it doesn't work
Maybe this will help: r = 3.59 + x
 
ok, so then in the last integral you will have a ln, but would that be the same that you integrate over?
 
usfelectrical said:
As shown in the figure, a rod of length 9.8 m lies along the x-axis, with its left end at the origin. The rod has a non-uniform linear charge density λ = αx, where α = 0.009 C/m2 and x is the position. Point A lies on the x-axis a distance 3.59 m to the left of the rod, as shown in the figure.
Q is the total charge on the rod. The Coulomb constant is 8.988 × 109 N m2/C2.

Find the potentia at A, and answer in units of volts




the two relevant equations i can find are:
v=kq/r
dv=kdq/r and lambda=qx?

This equation is wrong. It should be dq = [itex]\lambda[/itex]x dx.

Integrate this over the total length of the rod to get [itex]\lambda[/itex] expressed in terms of q. Then integrate dv=kdq/r to get total v at A.
 
i know that you have to integrate dq over the rod, what I'm saying is what do you integrate dv over?
 
dV is the contribution from dq to the potential at A (with respect to infinity). The integral of dV is simply V(A) the potential at A. Without charge, V is zero.

ehild
 
ok, so the integral for dv would be from 0 to 3.59 because you're integrating to the potential at A?
 
  • #10
dV is in volts, not in meters. dV is integrated over the potential belonging to zero charge to the actual potential V(A) of the total charge of the rod. The integral on the right-hand side goes along the length of the rod, from x= to x=9.8 m.
You need to use the 3.59 m in the term "r", distance from the charge dq to A.

ehild
 
Last edited:

Similar threads

Electric potential due to shell containing a charge at an offset outside
  • · Replies 5 ·
Replies
5
Views
1K
Uniform charge density and electric potential
  • · Replies 4 ·
Replies
4
Views
3K
Calculate Electric Potential from Non-uniform Linear Charge
  • · Replies 20 ·
Replies
20
Views
7K
Potential and Electric Field near a Charged CD Disk
  • · Replies 2 ·
Replies
2
Views
2K
Earthing of two parallel conducting plates
  • · Replies 11 ·
Replies
11
Views
2K
Calculate the electric field due to a line of charge of finite length
  • · Replies 6 ·
Replies
6
Views
4K
Determine the Electrical potential at a given point
  • · Replies 7 ·
Replies
7
Views
2K
MIT OCW, 8.02 Electromagnetism: Potential for an Electric Dipole
  • · Replies 1 ·
Replies
1
Views
3K
Calculating Electric Potential for a Non-Negligible Thickness Toroid
  • · Replies 4 ·
Replies
4
Views
2K
Volume charge density and potential difference in sphere
  • · Replies 6 ·
Replies
6
Views
3K