The discussion revolves around calculating the voltage required to accelerate a proton to penetrate a silicon nucleus, considering the charges and radii of both particles. The context involves concepts from electrostatics and potential energy related to point charges.
The discussion includes various interpretations of the problem, with some participants expressing confusion about the model answer and the calculations involved. Guidance has been offered regarding the interpretation of distances and the application of relevant equations.
There is mention of potential confusion regarding the exponent in the model answer and the assumption that the distance starts from infinity. Participants also note the need to consider the sum of the radii of the proton and silicon nucleus in their calculations.
What is the potential energy of a charge q1 a distance r from another charge q2? What is the potential energy of a proton whose surface is situated 3.6E-15 m. from the centre of a silicon nucleus?crazy student said:How much voltage must be used to accerlerate a proton (radius 1.2E-15 m) so that it has sufficient energy to just penetrate a silicon nucleus? A silicon nucleus has a charge of +14e, and its radius is about 3.6E-15 m. Assume the potential is that for point charges.
crazy student said:that's all from the question given...
I think it suppose r starts from infinity
but i can't get to the model ans 4.2E-6 J
The force between charges depends on the distance from the centre of the charge. The electric field of a charge is given by Gauss' law, which states that the field depends only on the enclosed charge:crazy student said:sorry, it should be 4.2E6 J
I found the question quite confusing also...
from the model ans and equation V = KQ/r
r = 4.8E-15 m, which is the sum of proton and silicon nucleus radii
but i don't know the reason behind...