Difference between revisions of "Photon-atom interactions"

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This chapter begins our application of the optical Bloch equations to the exploration of interactions between photons and atoms. 
 
 
* [[Derivation of the QED Hamiltonian]]
 
** [https://cua-admin.mit.edu:8443/wiki/images/8/88/API_appendix_pp_621-639.pdf API Appendix]    [https://cua-admin.mit.edu:8443/wiki/images/3/37/QED.pdf Summary of formulae]
 
* [[Feynman diagrams and perturbative expansion of the time evolution operator]]
 
** [https://cua-admin.mit.edu:8443/wiki/images/9/9a/2009-03-20_Diagrams.pdf 2009 pdf]
 
* [[Van der Waals interaction]]
 
** [https://cua-admin.mit.edu:8443/wiki/images/f/f2/2009-03-30-van_der_Waals.pdf  2009 pdf]
 
* [[Resonant scattering]]
 
 
 
<categorytree mode=pages style="float:right; clear:right; margin-left:1ex; border:1px solid gray; padding:0.7ex; background-color:white;" hideprefix=auto>8.422</categorytree>
 
<categorytree mode=pages style="float:right; clear:right; margin-left:1ex; border:1px solid gray; padding:0.7ex; background-color:white;" hideprefix=auto>8.422</categorytree>
  
== Handouts (2007) ==
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This chapter explores interactions between photons and atoms, starting from the QED Hamiltonian, using at first a perturbative approach which can be depicted diagrammatically.  Specifically, we discuss the van der Waals and Casimir interactions as an illustration of this approach.  We then present an analysis of a two-level atom excited by light with a frequency nearly equal to that of the atomic transition, a scenario known as resonant scattering.  In this scenario, ordinary perturbation theory fails because of the resonant behavior of the system.  However, we show that the perturbative, diagramtic approach can be generalized by "factoring" out the physics of resonance.  In this manner, we also obtain a description of the physics of an atom interacting with the vacuum, and thus undergoing spontaneous emission.  The result shows both the exponential decay and the level shift expected from analysis of the same scenario using the optical Bloch equations.
  
* Casimir force    Lecture notes
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* [[Derivation of the QED Hamiltonian]] ([https://cua-admin.mit.edu:8443/wiki/images/8/86/2009-03-16-QED_Hamiltonian.pdf   2009 Class notes])
**                  [http://cua.mit.edu/8.422/HANDOUTS/Cavity%20quantum%20electrodynamics.pdf Copies from Serge Haroche’s summer school notes]
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* [[Feynman diagrams and perturbative expansion of the time evolution operator]]
**                 [http://cua.mit.edu/8.422/HANDOUTS/Jaffe2005_Casimir.pdf Jaffe paper on Casimir force and zero-point energy]
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** [https://cua-admin.mit.edu:8443/wiki/images/9/9a/2009-03-20_Diagrams.pdf 2009 Class notes]
* Interaction processes between photons and atoms
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**   see API pp. 15-21 and Complement A_I
** See API:
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* [[Van der Waals interaction]] ([https://cua-admin.mit.edu:8443/wiki/images/f/f2/2009-03-30-van_der_Waals.pdf  2009 Class notes])
***                  1 Feynman diagrams                              see pp. 15-21 and Complement A_I
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* [[Casimir interaction]] ([https://cua-admin.mit.edu:8443/wiki/images/c/ce/2009-04-01-Casimir.pdf 2009 Class notes])
***                  2 Absorption, emission, scattering                              see pp. 67-93
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* [[Resonant scattering]] ([https://cua-admin.mit.edu:8443/wiki/images/5/5f/2009-04-01-Resonant_interactions.pdf 2009 Class notes])
***                  3 Resonant scattering                            see pp. 93-97 and pp. 226 ff.
 
* Van der Waals Interaction
 
**                        see pp. 121-126 of API
 
**          [http://cua.mit.edu/8.422/HANDOUTS/VanDerWaalsInteraction.pdf four pages course notes from Dan Kleppner]
 
**          [http://cua.mit.edu/8.422/HANDOUTS/Retarded...long-range%20potentials.pdf Physics Today paper by L. Spruch (Nov. 1986, p. 37)]
 
  
 
[[Category:8.422|4]]
 
[[Category:8.422|4]]

Latest revision as of 14:50, 3 February 2011

This chapter explores interactions between photons and atoms, starting from the QED Hamiltonian, using at first a perturbative approach which can be depicted diagrammatically. Specifically, we discuss the van der Waals and Casimir interactions as an illustration of this approach. We then present an analysis of a two-level atom excited by light with a frequency nearly equal to that of the atomic transition, a scenario known as resonant scattering. In this scenario, ordinary perturbation theory fails because of the resonant behavior of the system. However, we show that the perturbative, diagramtic approach can be generalized by "factoring" out the physics of resonance. In this manner, we also obtain a description of the physics of an atom interacting with the vacuum, and thus undergoing spontaneous emission. The result shows both the exponential decay and the level shift expected from analysis of the same scenario using the optical Bloch equations.