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Valence Photoemission Spectroscopy and the Many-Body Problem Nicholas S. Sirica December 10, 2012.

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Presentation on theme: "Valence Photoemission Spectroscopy and the Many-Body Problem Nicholas S. Sirica December 10, 2012."— Presentation transcript:

1 Valence Photoemission Spectroscopy and the Many-Body Problem Nicholas S. Sirica December 10, 2012

2 The Propagator within Many-Body Physical Interpretation: Probability Amplitude A few distinctions exist between the propagator of many-body and that of high energy physics Many-body propagator-create and annihilate excitations and holes

3 Photoemission Spectroscopy Photoemission spectroscopy-experimental analogue to single particle propagator Basic understanding of photoemission process: Focusing on optical excitation-relate absorption to transition rate

4 For photoemission being a single photon single electron process defines under Where taking Several simplifying assumptions can then be made

5 Ultimately defines an expression for the intensity of a photoemission spectrum Contained with in this expression is an important quantity: the single particle spectral function Physical interpretation-Probability which gives the distribution of spectral weight

6 Spectral Representation Does the spectral function have anything to do with the propagator? Yes, but you have to write it in the Lehmann representation Writing the Fourier transform Then gives

7 By definition of the single particle spectral function In separating real from imaginary components Results in

8 Dyson’s Equation In order to compare to spectra, we need an explicit expression for the propagator. Use definition of the propagator as a Green’s function For the free-particle propagator Including interactions via a potential V Or by multiplying through by the free- particle propagator

9 Find a solution by way of successive iterations

10 Quasiparticles Interpretation of valence photoelectron spectra nicely described in context of Fermi liquid theory Taken to be approximate single particle states in which a strongly interacting system can be mapped onto one which is weakly interacting FT Z k -quasiparticle residue. A measure of the strength of interactions

11 Relating Expanding the pole about the Fermi-level Under Possible to define quasiparticle residue in terms of an effective mass

12

13 Thanks So Much!

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