Sample problem 2: Difference between revisions
| Line 1: | Line 1: | ||
''Suppose the Hamiltonian of a rigid rotator in the magnetic field perpendicular to the axis is of the form(Merzbacher 1970, problem 17-1)'' | ''Suppose the Hamiltonian of a rigid rotator in the magnetic field perpendicular to the axis is of the form(Merzbacher 1970, problem 17-1)'' | ||
== '''<math>H=AL^2+BL_{z}+CL_{y}</math>''' == | == '''<math>H=AL^2+BL_{z}+CL_{y}</math>''' == | ||
'''''if terms quadratic in the field are neglected. Assuming B, use Pertubation to the lowest nonvanishing order to get approximate energy eigenvalues text'''' | |||
we rotate the system in the direction which is in the Z' axis, thus, <math>H=AL^2+(B^2+C^2)L_{z}^{'}</math> where the angel between Z and Z' can be written | we rotate the system in the direction which is in the Z' axis, thus, <math>H=AL^2+(B^2+C^2)L_{z}^{'}</math> where the angel between Z and Z' can be written | ||
we can have The eigen state<math></math> | we can have The eigen state<math>\right l,m'\rangle</math> | ||
with eigen value | |||
<math>E=Al(l+1)\hbar^{2}+(B^2+C^2)^{1/2}m'\hbar</math> | <math>E=Al(l+1)\hbar^{2}+(B^2+C^2)^{1/2}m'\hbar</math> | ||
<math>\right l,m'\rangle</math> | |||
| Line 11: | Line 13: | ||
<math>H=AL^2+(B^2+C^2)L_{z}^{'}</math>should be considered as none pertubative Hamiltonian, and <math>CL_{y}</math> behaves as pertubative term. So the none pertubative eigen value and eigen states are<math>Insert formula here</math>and <math>E_{l,m}^{0}=A\hbar^2l(l+1)+Bm\hbar</math> | <math>H=AL^2+(B^2+C^2)L_{z}^{'}</math>should be considered as none pertubative Hamiltonian, and <math>CL_{y}</math> behaves as pertubative term. So the none pertubative eigen value and eigen states are<math>Insert formula here</math>and <math>E_{l,m}^{0}=A\hbar^2l(l+1)+Bm\hbar</math> | ||
and first order corrections to the eigenstates of a given Hamiltonian is zero because of <math>L_{y}</math> so the second order correction will be written in the following form | and first order corrections to the eigenstates of a given Hamiltonian is zero because of <math>L_{y}</math> so the second order correction will be written in the following form | ||
<math>E_{n}^{(2)}=A\hbar^2l(l+1)+Bm\hbar+C^2\sum_{l',m'\neq l,m}\frac{\left | | <math>E_{n}^{(2)}=A\hbar^2l(l+1)+Bm\hbar+C^2\sum_{l',m'\neq l,m}\frac{\langle l^{'},m^{'}\left | L_{y} \right |l,m\rangle^2}{E_{l,m}^{0}-E_{l',m'}^{0}}</math> | ||
We know that | |||
<math>L_{y}=\frac{1}{2i}(L_{+}-L_{-})</math> | |||
So, | |||
<math>E_{n}^{(2)}=A\hbar^2l(l+1)+Bm\hbar+\frac{C^2m \hbar}{2B} </math> | |||
By exact solution for B>>C we will get: | |||
<math>E=A\hbar^2l(l+1)+Bm'\hbar+\frac{C^2m' \hbar}{2B}</math> | |||
Revision as of 02:37, 26 April 2010
Suppose the Hamiltonian of a rigid rotator in the magnetic field perpendicular to the axis is of the form(Merzbacher 1970, problem 17-1)
if terms quadratic in the field are neglected. Assuming B, use Pertubation to the lowest nonvanishing order to get approximate energy eigenvalues text'
we rotate the system in the direction which is in the Z' axis, thus, where the angel between Z and Z' can be written we can have The eigen stateFailed to parse (SVG (MathML can be enabled via browser plugin): Invalid response ("Math extension cannot connect to Restbase.") from server "https://wikimedia.org/api/rest_v1/":): {\displaystyle \right l,m'\rangle} with eigen value Failed to parse (syntax error): {\displaystyle \right l,m'\rangle}
If,
should be considered as none pertubative Hamiltonian, and behaves as pertubative term. So the none pertubative eigen value and eigen states areand
and first order corrections to the eigenstates of a given Hamiltonian is zero because of so the second order correction will be written in the following form
We know that
So,
By exact solution for B>>C we will get:
