Calculating Electron Speed in Hydrogen-like Atoms

[eku_girl83]

Here's my problem:
Show that the speed of an electron in the nth Bohr orbit of hydrogen is (alpha*c)/n, where alpha is the fine structure constant. What would be the speed in a hydrogenlike atom with a nuclear charge of Ze?

We didn't talk about the fine structure constant in class, so could someone explain to me what it is? Hints on how to show that speed = alpha c/n would also be appreciated.

Thanks,
eku_girl83

 

[Kane O'Donnell]

Hi,

In the Bohr model we assume that angular momentum is quantised:

L = mvr = n\hbar

From this you can find the expression for the tangential velocity of the electron. You then need to find the expression for the Bohr radius for a particular value of n, which turns out to be (for Z = 1, for Hydrogen-like atoms just replace e^2 with Z(e^2)):

r_{n} = \frac{4\pi\epsilon_{0}\hbar^{2}n^2}{me^2}

When you sub in for r you get:

v_{n} = \frac{e^2}{4\pi\epsilon_{0}\hbar}

From this you should be able to work out what the fine structure constant is - just compare the equation you were given to the one above. In undergrad physics courses the name "fine structure constant" is often applied to a few dimensionless constants that all look similar. It's just a number that happens to arise in a lot of Quantum Mechanical situations. You'll see it a fair bit :)

Cheerio!

Kane

 

[R0man]

The fine structure constant, denoted by alpha, is a dimensionless number that plays a crucial role in quantum mechanics and describes the strength of the electromagnetic interaction between particles. It is approximately equal to 1/137, which may seem like a small number, but it has significant implications in understanding the behavior of subatomic particles.

To show that the speed of an electron in the nth Bohr orbit of hydrogen is (alpha*c)/n, we can use the Bohr model of the atom and the relationship between the speed of an electron and its energy. In the Bohr model, the energy of an electron in the nth orbit is given by:

En = -13.6/n^2 eV

Where n is the principal quantum number and En is the energy of the electron in the nth orbit. Now, we know that the speed of an electron can be calculated using the formula:

v = (2πr)/T

Where r is the radius of the orbit and T is the time taken by the electron to complete one revolution. In the Bohr model, the time taken by the electron to complete one revolution is given by:

T = (2πr)/v

Substituting this value of T in the energy equation, we get:

En = -13.6/n^2 eV = -13.6/n^2 = (2πr)/v

Solving for v, we get:

v = (2πr)/(-13.6/n^2)

But we also know that the radius of the nth orbit is given by:

r = (n^2h^2ε0)/(πmke^2)

Where h is the Planck's constant, ε0 is the permittivity of free space, m is the mass of the electron, k is the Coulomb's constant, and e is the charge of the electron. Substituting this value of r in the expression for v, we get:

v = (2π(n^2h^2ε0)/(πmke^2))/(-13.6/n^2)

Simplifying, we get:

v = (2π^2h^2ε0)/(13.6mke^2)

Now, the fine structure constant is defined as:

α = (ke^2)/(4πε0h*c)

Substituting this value of α in the expression for v, we get:

v = (α