Answer:
[tex]\dfrac{q_1}{q_2}=2\left(\dfrac{2}{5}\right )^{3/2}[/tex]
Explanation:
Given that
Charge on ring 1 is q1 and radius is R.
Charge on ring 2 is q2 and radius is R.
Distance ,d= 3 R
So the total electric field at point P is given as follows
Given that distance from ring 1 is R
[tex]\dfrac{1}{4\pi\epsilon _o}\dfrac{q_1R}{(R^2+R^2)^{3/2}}-\dfrac{1}{4\pi\epsilon _o}\dfrac{q_2(d-R)}{(R^2+(d-R)^2)^{3/2}}=0[/tex]
[tex]\dfrac{1}{4\pi\epsilon _o}\dfrac{q_1R}{(R^2+R^2)^{3/2}}-\dfrac{1}{4\pi\epsilon _o}\dfrac{q_2(3R-R)}{(R^2+4R^2)^{3/2}}=0[/tex]
[tex]\dfrac{q_1R}{(2R^2)^{3/2}}-\dfrac{q_2(2R)}{(5R^2)^{3/2}}=0[/tex]
[tex]\dfrac{q_1}{q_2}=2\left(\dfrac{2}{5}\right )^{3/2}[/tex]
The figure is missing, so i have attached it.
Answer:
q1/q2 = 2[(2/5)^(3/2)] ≈ 0.506
Explanation:
The Electric Field for a ring of charge is given by the equation;
E = qz/[4πε_o(z² + R²)]
where;
z is the distance along the z-axis
q is the charge on the ring
R is the radius of the ring.
Now, at the point P, we want the two contributions to be equal to each other.
So, plugging in the same R
for each and the appropriate z, we get;
q1•R/[4πε_o(R² + R²)^(3/2)]
= q2•2R/[4πε_o((2R)² + R²)^(3/2)]
The terms 4πε_o cancels out to give ;
q1•R/[(R² + R²)^(3/2)]
= q2•2R/[((4R² + R²)^(3/2)]
Let's rearrange to get q1/q2.
Thus;
q1/q2 = 2R/[((4R² + R²)^(3/2)]/[R/[(R² + R²)^(3/2)]]
This gives;
q1/q2 = 2R/[((4R² + R²)^(3/2)]•[[(R² + R²)^(3/2)]/R]
Gives;
q1/q2 = [2/[(2R²)^(3/2)]]/[(5R²)^(3/2)]
Gives;
q1/q2 = 2(2R²/5R²)^(3/2)
R² cancels out to give ;
q1/q2 = 2[(2/5)^(3/2)] ≈ 0.506
