Phy5646: Difference between revisions
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where <math>\mathcal{H}_0</math> is exactly soluble and <math>\mathcal{H}'</math> makes it insoluble. | where <math>\mathcal{H}_0</math> is exactly soluble and <math>\mathcal{H}'</math> makes it insoluble. | ||
To do this we first consider an auxiliary problem, parameterized by \lambda: | |||
<math> H = H_0 + \lambda H^'</math> | |||
Attempt to find eigenstates <math>|\Psi(\lambda)\rangle</math> and eigenvalues <math>E_n</math>, and assume that they can be expanded in terms of <math>\lambda</math>: | Attempt to find eigenstates <math>|\Psi(\lambda)\rangle</math> and eigenvalues <math>E_n</math>, and assume that they can be expanded in terms of <math>\lambda</math>: | ||
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<math>E(\lambda) = E_0 + \lambda E_1 + ... + \lambda^n E_n</math> | <math>E(\lambda) = E_0 + \lambda E_1 + ... + \lambda^n E_n</math> | ||
<math>|\Psi\rangle = |0\rangle + \lambda|1\rangle + \lambda^2 |2\rangle + ...</math> | <math>|\Psi\rangle = |0\rangle + \lambda|1\rangle + \lambda^2 |2\rangle + ... \lambda^n |n> + ...</math> | ||
Assume that the exact state is |N>, and that | |||
<math> \langle n | n \rangle = 1</math>. | |||
Then in general |N> will not be normalized. | |||
== Time dependent perturbation theory in Quantum Mechanics == | == Time dependent perturbation theory in Quantum Mechanics == | ||
Revision as of 21:58, 12 January 2009
Welcome to the Quantum Mechanics B PHY5646 Spring 2009
This is the second semester of a two-semester graduate level sequence, the first being PHY5645 Quantum A. Its goal is to explain the concepts and mathematical methods of Quantum Mechanics, and to prepare a student to solve quantum mechanics problems arising in different physical applications. The emphasis of the courses is equally on conceptual grasp of the subject as well as on problem solving. This sequence of courses builds the foundation for more advanced courses and graduate research in experimental or theoretical physics.
The key component of the course is the collaborative student contribution to the course Wiki-textbook. Each team of students (see Phy5646 wiki-groups) is responsible for BOTH writing the assigned chapter AND editing chapters of others.
This course's website can be found here.
Outline of the course:
Stationary state perturbation theory in Quantum Mechanics
Very often, quantum mechanical problems cannot be solved exactly. We have seen last semester that an approximate technique can be very useful since it gives us quantitative insight into a larger class of problems which do not admit exact solutions. The technique we used last semester was WKB, which holds in the asymptotic limit .
Perturbation theory s another very useful technique, which is also approximate, and attempts to find corrections to exact solutions in powers of the terms in the Hamiltonian which render the problem insoluble.
Typically, the (Hamiltonian) problem has the following structure
where is exactly soluble and makes it insoluble.
To do this we first consider an auxiliary problem, parameterized by \lambda:
Attempt to find eigenstates and eigenvalues , and assume that they can be expanded in terms of :
Assume that the exact state is |N>, and that .
Then in general |N> will not be normalized.
Time dependent perturbation theory in Quantum Mechanics
Interaction of radiation and matter
Quantization of electromagnetic radiation
Additional Reading
- Experimental observation of a Lamb-like shift in a solid state setup Science 322, 1357 (2008).