Quantum Mechanics pendulum problem

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Homework Statement



The pendulum of a grandfather clock has a period of 1s and makes excursions of 3cm either side of dead centre. Given that the bob weighs 0.2kg, around what value of n would you expect its non negligible quantum amplitudes to cluster?


Homework Equations





The Attempt at a Solution



I think the n here refers to the nth energy eigenvalue so En = (n + 1/2) h/2pi w

How do i work this out? My guess is that I need to work out the energy of a classical harmonic oscillator and equate this to (n+1/2) h/2pi w to get n?

So i know w = 2pi ... but how do i work out the energy of the oscillator? At max displacement it will have no KE, only PE..but how do i work out what this is?

Thanks!
 
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dude, draw a picture with both the equilibrium and final positions, then find out how high the final position is w.r.t to the equilibrium position.
 
graphene said:
dude, draw a picture with both the equilibrium and final positions, then find out how high the final position is w.r.t to the equilibrium position.

thanks..but this is my problem. i don't know how high the final position is wrt initial position... all they say is that it makes excursions of 3cm either side of dead centre...but i don't know what what angle it is at at the extrema, so how can i work out how high it goes?

Thanks
 
If you have the period, don't you have the length? T = 2pi sqrt(l/g) approximately.
From this you can get the height? I have no knowledge of quantum mechanics so this is just a shot in the dark.
 
Thanks, but l in that equation gives you the length of the string. I still don't see how you can get the height..
 
bon said:
Thanks, but l in that equation gives you the length of the string. I still don't see how you can get the height..

Again, just a shot in the dark, but by height I'm guessing you mean the height the mass reaches at it's full swing?
You know its 3 cm far, and l long. The height is x= 3 /(tan ( 90 - arctan(3/l))
 
ok thanks so i get h = 1.79 x 10^-3m

is this right?

This means E total = mgh = 0.2 * 9.8 * h = 3.5 x 10^-3 J

so now do i set (n+1/2) h/2pi w = 3.5 x 10^-3 ?

This gives n as something ridiculously large (5.29 x 10 ^30). Is this right?
 
The equation I gave was wrong, sorry man. I have a new relation:

9 - 2Lx + x^2 = 0

which gives

x = L +- sqrt(4L^2 - 36) / 2This comes from considering it's equilibrium and max and getting an isosceles triangle.
You split it into 2 right angle triangles. Use pythagoras to get 3^2 + (L-x)^2 = L^2
 
Oh ok - i worked it out myself, using a different method, but i think the answer is the same, right?

Is my final answer correct then (to someone who knows about the quantum side of the question as well...)?
 
it just seems the number n is too big... have i interpreted the question correctly?