Equation for speed of charges (electrostatics)?

AI Thread Summary
The discussion revolves around finding an equation that links the speed of charged particles to their electrostatic interactions. A user presents a problem involving two charged particles and seeks guidance on calculating their speeds as they approach each other. While Coulomb's law is mentioned for determining the force between the particles, the challenge lies in the changing force and acceleration as they move closer, complicating the calculation of speed. The suggestion to use conservation laws indicates a potential approach to solve the problem despite the non-constant acceleration. Overall, the thread highlights the complexities of relating charge, distance, and speed in electrostatics.
devil0150
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I am trying to do an exercise but there's no equation in the book that links speed and charges. Can anyone help? This is the exercise:

Homework Statement


There is a particle with mass = 20 grams and charge = 6 x 10^(-6) C, and another particle with mass = 50 grams and charge = -4 x 10^(-6) C. The distance between the particles is 1 m. Find the speed of each particle when their distance becomes 0.5 m.
 
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devil0150 said:
there's no equation in the book that links speed and charges.
Not directly, but I'm sure you have equations that relate charge and distance to force, force and mass to acceleration, acceleration and distance to speed.
 
Yes I tried using coulomb's law to find the force, and then each of the accelerations (a = F/m) but to find the speed from this (v^2 = 2*a*d) I need the individual distance traveled by each particle, and I only have the sum of both distances (0.5 m).

Edit: And since the force has different value for different positions of the particles, doesn't that mean that the acceleration isn't constant? How can I find the speed using a non-constant acceleration?
 
Last edited:
devil0150 said:
Edit: And since the force has different value for different positions of the particles, doesn't that mean that the acceleration isn't constant? How can I find the speed using a non-constant acceleration?

In such cases it's often profitable to consider the problem in terms of conservation laws :wink:
 

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