X-Ray Absorption Spectroscopy Joachim Stöhr Stanford Synchrotron Radiation Laboratory http://www-ssrl.slac.stanford.edu/stohr J. Stöhr, NEXAFS SPECTROSCOPY, Springer Series in Surface Sciences 25, (Springer, Heidelberg, 1992). J.

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Transcript X-Ray Absorption Spectroscopy Joachim Stöhr Stanford Synchrotron Radiation Laboratory http://www-ssrl.slac.stanford.edu/stohr J. Stöhr, NEXAFS SPECTROSCOPY, Springer Series in Surface Sciences 25, (Springer, Heidelberg, 1992). J.

X-Ray Absorption Spectroscopy
Joachim Stöhr
Stanford Synchrotron Radiation Laboratory
http://www-ssrl.slac.stanford.edu/stohr
J. Stöhr,
NEXAFS SPECTROSCOPY,
Springer Series in Surface Sciences 25, (Springer, Heidelberg, 1992).
J. Stöhr and H. C. Siegmann
MAGNETISM: FROM FUNDAMENTALS TO NANOSCALE DYNAMICS,
Springer Series in Solid State Sciences 152, (Springer, Heidelberg, 2006)
Physical Processes
Quantum Theoretical X-Ray Interactions with Matter: The Basic Processes
Fermi's
Golden rule
KramersHeisenberg
relation
Tunable x- rays offer large interaction cross sections
optical
light
electrons
Photoemission
neutrons
X-Ray Absorption and Scattering Cross Sections per Atom
Thomson Cross section
Fe atom
Experiment
Fe metal
Kortright and Kim,
Phys. Rev. B 62, 12216 (2000)
f1 and f2 tabulated Henke-Gullikson factors
http://www-cxro.lbl.gov/index.php?content=/tools.html
X-ray Absorption Spectra in a Nutshell
tabulated
Henke-Gullikson
Absolute absorption coefficients from experimental spectra
(from Henke-Gullikson
compilation)
Names: XAFS – NEXAFS –XANES - EXAFS
or XANES
Interference of
outgoing
photoelectron and
scattered waves
Nearest neighbor distances
Number of neighbors
Tunable x-rays offer elemental specificity
Experimental Soft X-rayTechniques
Experimental X-Ray Absorption Techniques
X-Ray Absorption versus Photoemission
Electron Yield Sampling Depth
Surface sensitivity of total and Auger yield
total yield
Some Fundamental X-Ray Absorption Spectra
-- soft x-rays --
NEXAFS spectra of polymers: building block picture
Chemical Sensitivity
Core level shifts
and
Molecular orbital shifts
NEXAFS of Transition Metals
Dipole selection rule
l  1
2p
2p
“white
lines”
3d - strong
4s - weak
Ebert et. al. Phys.
Rev. B 53, 16067
(1996).
Total intensity reflect
number of empty holes
Polarized X-Rays - Dichroism
“dichroism” = pol. dep. absorption
Polarization definitions (high energy physics)
Historical note:
different “handedness” definitions in optics (space) versus high energy physics (time)
Polarized x-rays offer orientation sensitivity
Orientational order
Antiferromagnetic
order
Chirality
Ferromagnetic order
X-Ray Natural Linear Dichroism
Linear Charge Dichroism in a d-electron system
C. T. Chen et al. PRL 68, 2543 (1992)
J. Stöhr et al., Science 292, 2299 (2001)
X-Ray Magnetic Linear Dichroism
Magnetic field
splits p-orbitals
sum
XMLD – spectra below and above TN
Lüning et al. Phys. Rev. B 67, 214433 (2003)
XMLD spectra of two oxides
XMLD effects especially strong in multiplet peaks
(Ni 2+,d8)
(Ni 1+,d9)
X-ray Magnetic Circular Dichroism
Magnetic Circular Dichroism
Soft x-rays are best for magnetism
XMCD spectra of the pure ferromagnetic metals
The sum rules
X-ray Natural Circular Dichroism
l
s
k=k0 w/c
Dipole
=0 for x-rays
Chirality
Pasteur’s and Faraday’s experiments