Electric Field of Uniformly Charged Ring

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The discussion focuses on calculating the electric field along the axis of a uniformly charged ring with a radius of 10.0 cm and a total charge of 58.0μC. The relevant formula for the electric field is E = (kQx)/(x^2 + r^2)^(3/2), where x is the distance from the center of the ring and r is the radius. The origin of this formula is explained as a result of integrating the contributions from infinitesimal charge elements of the ring, each treated as a point charge. This integration process is necessary because the electric field of a ring differs from that of a point charge, represented by E = kq/r^2. Understanding this derivation is essential for applying the formula correctly in physics problems.
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A uniformly charged ring of radius 10.0 cm has a total charge of 58.0μC. Find the electric field on the axis of the ring at the following distances from the center of the ring. (Choose the x-axis to point along the axis of the ring.).

I know the equation I want to use is E= (kQx)/(x^2+r^2)^(3/2)
where x is distance from the center of the ring and r is the radius.

But, I don't know where this equation comes from. I know E=kq/r^2, so I'm just not sure where the x/(x^2+r^2)^(3/2) comes from.
 
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The formula that you wrote: E = kq/r^2, is the field of a point charge. If you have a ring of charge, you have to calculate the field due to tiny pieces of the ring, each considered a point charge, and vectorially add the fields. This process, in the limit as each tiny piece tends to zero size, is called integration. If you do the integration, you will get the more complicated formula that you wrote. This is given in detail in any calculus based textbook of introductory physics
 
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