Publications in Scientific Journals:
P. Schattschneider, H. Lichte:
"Correlation and the density-matrix approach to inelastic electron holography in solid state plasmas";
Physical Review B,
71
(2005),
045130-1
- 045130-9.
English abstract:
Correlation and the density-matrix approach to inelastic electron holography in solid state plasmas
Peter Schattschneider
Laboratoire MSS-Mat-CNRS-UMR8579, Ecole Centrale Paris, F-92295 Châtenay-Malabry, France
Hannes Lichte
Institute of Structure Physics, Triebenberg-Laboratory, Dresden University, D-01062 Dresden, Germany
(Received 14 May 2004; revised 22 September 2004; published 31 January 2005)
Collective excitations in solid state plasmas are a good candidate to measure correlation lengths of conduction electrons. The method of choice seems to be energy filtered electron holography in the transmission electron microscope (TEM) since the interference fringes contain information on the partial coherence of those electrons. Previous experiments showed surprisingly high coherence. We calculate the density-density correlation function in the Al plasma excitation from the dynamic form factor and compare it to results based on similar arguments. For the Al plasma excitation, we find a small extension of 0.1-0.3 nm over which the movement of charges is correlated. Using the density-matrix formalism, the coherence length of plasmon scattered fast electrons in the TEM is calculated and found to agree with experiment. We show that the small correlation length of conduction electrons does not contradict the coherence length of > 10 nm found for fast probe electrons having excited a plasmon in Al. The difference of nearly two orders of magnitude can be traced back to the long-range Coulomb interaction between probe and target electrons. Two unexpected predictions ensue from the present approach: Inelastic holography experiments should show strongly increased contrast of interference fringes in vacuo, i.e., outside the specimen, and contrast inversion of fringes in inelastic holograms of very small particles.
©2005 The American Physical Society
URL: http://link.aps.org/abstract/PRB/v71/e045130
doi:10.1103/PhysRevB.71.045130
PACS: 71.45.Gm, 34.80.Pa, 82.80.Pv
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Online library catalogue of the TU Vienna:
http://aleph.ub.tuwien.ac.at/F?base=tuw01&func=find-c&ccl_term=AC05938074
Electronic version of the publication:
http://dx.doi.org/10.1103/PhysRevB.71.045130
Created from the Publication Database of the Vienna University of Technology.