Why Are The Units of Coulombs Law What They Are?

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The discussion centers on understanding the units in Coulomb's Law, specifically why force is expressed in Newtons (N) and how the units of the permittivity constant are derived. The units of the permittivity constant are (C^2)/(N-M^2), which ensures that the equation maintains dimensional consistency. The charges Q1 and Q2, measured in coulombs, do not appear in the final units because their product is counterbalanced by Coulomb's constant, which includes a coulomb-squared term. Ultimately, the relationship defined by Coulomb's Law allows the force to be expressed in Newtons, as the units of the constant K adjust accordingly. Understanding these unit relationships clarifies the application of Coulomb's Law in physics.
PurelyPhysical
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Why are the units of force used when applying coulombs law (N-M^2)/(C^2)? This is actually a three part question.

1. Why are the units of the permitivity constant (C^2)/(N-M^2)?
2. Why do Q1 and Q2 not contribute to the final units? Each charge is measured in coulombs, but those units don't reflect in the final units.
3. Units of force are Newtons. Why then can we say that coulombs law equals force? What's going on with the other units that makes it so that we can still refer to it as a force?
 
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Q1 times Q2 is canceled out by Coulomb's constant (which contains a coulomb-2 term).
 
David Lewis said:
Q1 times Q2 is canceled out by Coulomb's constant (which contains a coulomb-2 term).
Thank you. That makes a lot of sense.
 
PurelyPhysical said:
Why are the units of force used when applying coulombs law (N-M^2)/(C^2)? This is actually a three part question.
3. Units of force are Newtons. Why then can we say that coulombs law equals force? What's going on with the other units that makes it so that we can still refer to it as a force?

There is nothing mysterious with the units that makes the final result to be expressed in units of force.
In physics the first thing are the physical laws. The relationship between the units (and the units of possible constants that are used, like the coulomb constant K) are worked out after we discover the physical laws.

In our case the physical law that Coulomb discover is that the force between two charges is proportional to the product of the charges and inversely proportional to the square of the distance. In order to complete the equality we need a constant K so we can write down
##F=K\frac{Q_1Q_2}{r^2}## (1)
Now that we know this law holds, we can figure out the units of the constant K and the relationship between the units. So it will be because (1) holds

Newton=(units of constant K)*Coulomb*Coulomb/Meter^2. (2)

so the units of constant K have to be Newton*Meter^2/Coulomb^2 cause only if it is so then (2) holds.
 
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Do you mean F = [m1m2]/r^2?

Oh! What a popular equation! Newton, coulomb, La Place is there more?
 
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