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Perturbation Theory Lecture 3.

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Presentation on theme: "Perturbation Theory Lecture 3."— Presentation transcript:

1 Perturbation Theory Lecture 3

2 Interaction picture: Used when Hamiltonian is
function of t. Here state vectors and operators both evolve with t. We write -----(1) State vector in Interaction picture state vector in Schr. picture

3 Differentiating (i) w.r.t t
Using and in (2), we get... -----(2) -----(3)

4 -----(4) which is S.E. In interaction picture.

5 Equation of motion for operator :
Operator in interaction picture is related to operator In Schrödinger picture through Eq. Of motion will be -----(5) -----(6)

6 Time dependent perturbation theory
Hamiltonian is split into two parts: time independent part and time dependent part ----(1) Exactly solvable part satisfy Sol is: ----(2) ----(3)

7 System is subjected to perturbation
And Schrodinger eq will be When system interact with ,system emit or absorb the energy and make transition from one unperturbed state to other. ----(4) ----(5)

8 ----(5) Time evolution eq In I.P. ----(6) ----(7) ----(8)
We solve (5) in interaction picture ----(5) Time evolution eq In I.P. ----(6) ----(7) ----(8)

9 Using (7) in (5), we get Solution of above eq. will be Above eq.is solved iteratively. First order approx. Using in (10), ------(11) ----(9) Initial condition ----(10)

10 Using in (11), we get ------(12) which is 2nd app. Repeating above process, we will get Above series is known as Dyson series used to calculate state vectors in perturbation theory.

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