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X-ray Raman scattering
X-ray Raman scattering (XRS) is non-resonant inelastic scattering of x-rays from core electrons. It is analogous to Raman scattering, which is a largely-used tool in optical spectroscopy, with the difference being that the wavelengths of the exciting photons fall in the x-ray regime and the corresponding excitations are from deep core electrons.

XRS is an element-specific spectroscopic tool for studying the electronic structure of matter. In particular, it probes the excited-state density of states (DOS) of an atomic species in a sample.

Description
XRS is an inelastic x-ray scattering process, in which a high-energy x-ray photon gives energy to a core electron, exciting it to an unoccupied state. The process is in principle analogous to x-ray absorption, but the energy transfer plays the role of the x-ray photon energy absorbed in x-ray absorption, exactly as in Raman scattering in optics vibrational low-energy excitations can be observed by studying the spectrum of light scattered from a molecule.

Because the energy (i.e. wavelength) of the probing x-ray can be chosen freely and is usually in the hard x-ray regime, certain constraints of soft x-rays in the studies of electronic structure of the material are overcome. For example, soft x-ray studies may be surface sensitive and they require a vacuum environment. This makes studies of e.g. many liquids impossible using soft x-ray absorption. One of the most notable applications in which x-ray Raman scattering is superior to soft x-ray absorption is the study of soft x-ray absorption edges in high pressure. Whereas high-energy x rays may pass through a high-pressure apparatus like a diamond anvil cell and reach the sample inside the cell, soft x-rays would be absorbed by the cell itself.

History
In his report of finding of a new type of scattering, Chandrasekhara Venkata Raman proposed that a similar effect should be found also in the x-ray regime. Around the same time, B. Davis and D. Mitchell reported in 1928 on the fine-structure of the scattered radiation from graphite and noted that they had lines that seemed to be in agreement with carbon K shell energy. Several researchers attempted similar experiments in the late 1920's and early 1930's but the results could not always be confirmed. Often the first unambiguous observations of the XRS effect is credited to K. Das Gupta (reported findings 1959) and Tadasu Suzuki (reported 1964). It was soon realized that the XRS effect in solids was broadened by the solid-state effects and it appeared as a band. The potential of the technique was limited until the advent of synchrotron radiation sources became available due to the very small XRS probability of the incident photons. Today, the technique is rapidly growing in importance. It can be used to study near-edge x-ray absorption fine structure (NEXAFS or XANES) as well as extended x-ray absorption fine structure (EXAFS).

Brief theory of XRS
XRS belongs to the class of nonresonant inelastic x-ray scattering, which has a cross section of

$${d^2 \sigma \over d \Omega d E}= ({ d \sigma \over d \Omega })_{\rm Th} \times S(q,E)$$.

Here, $$(d \sigma / d \Omega )_{\rm Th}$$ is the Thomson cross section, which signifies that the scattering is that of electronmagnetic waves from electrons. The physics of the system under study is buried in the dynamic structure factor $$S(q,E)$$, which is a function of momentum transfer $$q$$ and energy transfer $$E$$. The dynamic structure factor contains all non-resonant electronic excitations, including the core-electron excitations observed in XRS.

Similarity to x-ray absorption
It was shown by Yukio Mizuno and Yoshihiro Ohmura in 1967 that at small momentum transfers $$q$$ the XRS contribution of the dynamic structure factor is proportional to the x-ray absorption spectrum. The main difference is that while the polarization vector of light couples to momentum of the absorbing electron in XAS, in XRS the momentum of the incident photon couples to the charge of the electron. Because of this, the momentum transfer of XRS plays the role of photon polarization of XAS.