Conservation of Energy with Metal Spheres

AI Thread Summary
Two small metal spheres, with masses of 2.0g and 4.0g and both charged to +2.1 μC, are initially at rest on a frictionless surface connected by a string. When the string is cut, the potential energy converts entirely into kinetic energy, allowing for the calculation of their speeds using conservation of energy and momentum principles. The initial energy of the system is determined to be 0.74 J, leading to the equations for kinetic energy and momentum conservation. The correct approach involves ensuring mass is converted from grams to kilograms, which affects the final speed calculations. Ultimately, the correct speeds for the spheres are found to be v1 = 0.70 m/s and v2 = 0.35 m/s after proper unit conversions and calculations.
ZEli
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Homework Statement


Two small metal spheres with masses 2.0g and 4.0g are tied together by a 5.4-cm-long massless string and are at rest on a frictionless surface. Each is charged to +2.1 μC .

The string is cut. What is the speed of each sphere when they are far apart?

Homework Equations


U = Kq1q2/r
F = K q1/q2/r^2
m1v1 = m2v2

The Attempt at a Solution


I'm not entirely sure how to approach this. I calculated that the energy in the system is .74 J and also the tension in the string is 14 N. How can I use that to my advantage?
 
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When they are far apart the potential energy -> 0, so they energy of the system that begins entirely as potential must now be all kinetic. This should give you one equation. To get a 2nd you know that momentum is conserved as well.
 
So, .74 = 1/2mv^2. I picked the 2g sphere, so v = .86 m/s. This doesn't give me the right answer :(
 
The initial energy is equal to the sum of the kinetic energies of the two spheres at the end. So it should be .73 = .5*m1*v1^2 + .5m2*v2^2. This leaves you with two unknowns (v1 and v2). To get a 2nd equation you can use conservation of momentum.
 
Hmm, it's still not quite right. I have the two equations, .74 = .5*m1*v1^2 + .5m2*v2^2 and 2*v1 = 4*v2. I solved for v1, giving me v1 = 2*v2. Plugging into the first equation I end up with v2 = .35 and v1 = .70.

I understand that all potential energy turns into kinetic energy and that energy is conserved. Am I just using the wrong equation for conservation of energy?
 
I get a different answer, maybe check your work? Remember when you plug v1=2v2 into the equation v1^2=4v2^2. Also don't forget mass is in grams.
 
Ohh, I forgot to convert grams into kg. Thank you for all the help!
 

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