[SOLVED] particle in a box

[jk4]

1. The problem statement, all variables and given/known data
An electron moves with a speed of v = 10^{-4}c inside a one-dimensional box of length 48.5nm. The potential is infinite elsewhere. What is the approximate quantum number of the electron?

2. Relevant equations
E_{n} = \frac{n^{2}\pi^{2}\hbar^{2}}{2mL^{2}}
n = 1, 2, 3, . . .

E = \gamma mc^{2}

3. The attempt at a solution
I was trying to solve it by finding the total energy of the electron, then using the first equation I stated using the total energy as "En". Then I would try and solve for n but I get a very different number. The answer is supposed to be 4.

[Dick]

n=4 is right. What did you get for the E corresponding v=10^(-4)c? What do you get if you put n=4 into En? BTW v<<c. You could just use (1/2)mv^2 for the energy.

[tnho]

n=4 is right. What did you get for the E corresponding v=10^(-4)c? What do you get if you put n=4 into En? BTW v<<c. You could just use (1/2)mv^2 for the energy.

yes. I got 3.969 for using E_n=\frac{1}{2}mv^2.
Besides, E_{n} = \frac{n^{2}\pi^{2}\hbar^{2}}{2mL^{2}} is a result from Schrodinger Equation which is non-relativistic. I am not sure if this form preserve in Dirac Equation or not.

[jk4]

EDIT:
ok I got it, thanks for the help.

[Dick]

Put units on dimensionful numbers ok. I calculate E = (0.5)(9.1095 E -31*kg)(10E-4 x c)^2 and I get 4.09E-22J. We are using the same numbers, unless you are using a different value of c??

[tnho]

EDIT:
ok I got it, thanks for the help.


\frac{1}{2}mv^2 = \frac{n^{2}\pi^{2}\hbar^{2}}{2mL^{2}}

then

n=\frac{mvL}{\pi \hbar}

put m=9\times 10^{-31}, v=3\times 10^{4}, L=48.5\times 10^{-9} \mbox{ and } \hbar = 1.055\times 10^{-34}

then you can get n\approx 4

get it?

[wombat4000]

wow - this really helped - thanks!