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Introduction to Energy Loss Spectrometry Helmut Kohl Physikalisches Institut Interdisziplinäres Centrum für Elektronenmikroskopie und Mikroanalyse (ICEM)

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1 Introduction to Energy Loss Spectrometry Helmut Kohl Physikalisches Institut Interdisziplinäres Centrum für Elektronenmikroskopie und Mikroanalyse (ICEM) Westfälische Wilhelms-Universität Münster, Germany 1.Introduction 2.The scattering process 3.Inner shell losses 4.The low-loss regime 5.Relativistic effects 6.Summary and conclusion Contents:

2 1. Introduction integrated over the energy window and up to the acceptance angle Spectrum of BN (Ahn et al., EELS Atlas 1982)

3 2. The scattering process Assumptions: -weak scattering -non-relativistic -object initially in the ground state Fermis golden rule (1. order Born approximation)

4 Scattering geometry

5 plane wave state of the incident and outgoing electron initial and final state of the object interaction between the incident electron and the electrons in the object

6 After some calculations (Bethe, 1930) kinematics object function Scattering vector Å Fourier transformed density (operator) Bohrs radius dynamic form factor (vanHove, 1954)

7 More general case: coherent superposition of two incident waves Scattering of two coherent waves How can one calculate the dynamic form factor? Mixed dynamic form factor (MDFF; Rose,1974) P. Schattschneider, Thursday

8 3. Inner-shell losses Approximations: - free atoms - describe initial and final state as a Slater-determinant of single-electron atomic wave functions (not valid for open shells 3d, 4d: transition metals; 4f, 5f: lanthanides, actinides) single-electron matrix element. SIGMAK (Egerton, 1979), SIGMAL (Egerton, 1981) Hartree-Slater model (Rez et al.)

9 geometry: ; scattering angle For small scattering angles small scattering vectors dipole approximation

10 Example: - Ionisation of hydrogen - experiment for carbon photo absorption oscillator strength generalized oscillator strength (GOS): In solids the final states are not completely free. near-edge structure (ELNES) analogous to XANES extended fine structure (EXELFS) analogous to EXAFS

11 generalized oscillator strength for hydrogen (Inokuti, Rev. Mod. Phys. 43, (1971) 297)

12 double differential cross-section for carbon (Reimer & Rennekamp, Ultramicr. 28, (1989) 256)

13 C. Hébert, Wednesday

14 Spectrum of BN (Ahn et al., EELS Atlas 1982)

15 4. Low loss spectra For relatively low frequencies ( low energy losses) the free electron gas can partly follow the field of the incident electron  shielding Electron causes -field Acting field: Absorption: Imaginary part Relation to dynamic structure factor ? div

16 For In addition: surface plasmon losses O. Stephan, Thursday is response function Dissipation-fluctuation theorem: peaks for : volume plasmons Why don‘t we use that for higher energy losses ? Formally: describes fluctuations in the object (density-density correlation);

17 dielectric function of Ag (Ehrenreich & Philipp, Phys. Rev. 128 (1962) 1622)

18 dielectric functions of Cu (Ehrenreich & Philipp, Phys. Rev. 128 (1962) 1622)

19 5. Relativistic effects Non-relativistic: Incident electron causes Coulomb field field is instantaneously everywhere in space Relativistic: Incident (moving) electron causes an additional magnetic field fields move in space with the speed of light c ( retardation) Matrix elements are sums of an electric and a magnetic term In Coulomb gauge: electric term corresponds to the non-relativistic term, but with relativistic kinematics Double-differential cross-section in dipole-approximation

20 (Kurata at al., Proc. EUREM-11 (1996) I-206)

21 6) Summary and conclusions -quantitative interpretation of EEL-spectra requires knowledge of cross-sections -cross-section related to dynamic form factor -for inner-shell ionization these can be calculated using a one–electon model -large errors may occur when 3d, 4d, 4f, 5f shells are involved -for small scattering angles (dipole approximation) one obtains a Lorentzian angular shape -in dipole approximation the cross-section is closely related to the photoabsorption cross-section -near-edge and extended fine structures can be interpreted as in the X-ray case -the low-loss spectrum permits to determine the dielectric function -WARNING: relativistic effects are not included in the commonly used equations

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