What is the dielectric constant of the material between the plates?

AI Thread Summary
The discussion revolves around calculating the dielectric constant of a material used in a parallel-plate capacitor. When a 100 V potential difference is applied, removing the dielectric results in a measured potential of 500 V. The dielectric constant can be determined using the relationship between voltage, charge, and capacitance, specifically the equation V = Q/(kε₀A/d). Additionally, the conversation touches on the conservation of charge and energy equations relevant to electric potential differences. Ultimately, the key takeaway is that the dielectric constant can be calculated by rearranging the voltage equations with known values.
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electrical potential help..urgent!

1) A parallel-plate capacitor is made of two flat metal plates pressed against a thin slab of dielectric material. The capacitor is connected to a power supply, and a potential difference of 100 V is applied to the plates. With the power supply disconnected, the dielectric material is removed and the potential difference between the plates is measured to be 500 V. What is the dielectric constant of the material that was initially used to fill the gap between the plates?

2) Points A and B have electric potentials of 275 V and 129 V, respectively. When an electron released from rest at point A arrives at point C its kinetic energy is KA. When the electron is released from rest at point B, however, its kinetic energy when it reaches point C is KB = 4KA. What is the electric potential at point C?
 
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1) Here are some hints:

First, the voltage of a capacitor is equal the the charge divided by the capacitance, or V=Q/C
Second, charge is always conserved, in everything physics(so far at least), so that's a constant you'd want to use.
Last, the dielectric changes the capacitance according to the equation: C=k \epsilon _0 A/d where k is the dielectric constant you're looking for. (A and d stay the same in with or without the dielectric in this case)

2) qV=energy, where q is charge and V is the potential difference. Using this equation you can find the difference in energy from the path from A to C and from B to C, and then work from there.

If you need more help than these admittedly vague hints, I'll give a solution, but it's always best to solve things for yourself.
 
i get the second problem and thanks for explanations. but for some reason i still can't figure out the first one.
 
For the first question, put the second equation fluxC gave you into the first one ie.
V=\frac{Qd}{k\epsilon_0A}
Now everything there stays the same except V and k so you could rewrite the equation as
V=\frac{C}{k}
Where C is a constant. You also know that if k=1 (ie. no dielectric present) V=500, so you can solve for C. Then let V=100 and find k.
 

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