Resonant nuclear scattering with synchrotron radiation

Add to my library

P2605 V2 Article

Resonant nuclear scattering with synchrotron radiation

Authors : Rudolf RÜFFER, Jacques TEILLET

Publication date: September 10, 2003 | Lire en français

Add to my library Add to my library

Logo Techniques de l'Ingenieur You do not have access to this resource.
Request your free trial access! Free trial

Already subscribed?

Overview

Read this article from a comprehensive knowledge base, updated and supplemented with articles reviewed by scientific committees.

Read the article

AUTHORS

  • Rudolf RÜFFER : Physicist at the European Synchrotron Radiation Facility (ESRF) in Grenoble, France - Nuclear resonant diffusion group

  • Jacques TEILLET : Professor at the University of Rouen, Faculty of ScienceMaterials Physics Group (UMR CNRS 6634)

 INTRODUCTION

Nuclear resonant scattering (NRS) using synchrotron radiation combines the exceptional properties of Mössbauer spectrometry (MS) with those of synchrotron radiation. Since its first observation in 1984, this technique and its applications have enjoyed rapid development. Nuclear resonant scattering is now a standard technique for all third-generation synchrotron radiation sources. Like Mössbauer spectrometry, it is a non-destructive, atomic-scale analysis method. It has the advantage of not requiring the use of radioactive sources of incident γ photons, which can be difficult to manufacture, of lifetimes that can be short and of obviously limited intensity.

Current applications mainly concern two fields: hyperfine spectroscopy and structural dynamics. In hyperfine spectroscopy, resonant nuclear scattering can measure the same quantities as Mössbauer spectrometry. However, it is superior in areas that exploit the specific properties of synchrotron radiation, such as very small samples, single crystals, high-pressure measurements, grazing incidence geometry for surfaces and multilayers. Structural dynamics on time scales ranging from nanoseconds to microseconds, such as free or jump scattering, can be measured in the time domain. In addition, the inelastic nuclear scattering technique provides, for the first time, a tool for directly accessing the density of phonon states, and thus for deducing the dynamic and thermodynamic properties of the lattice.

The nuclear resonant scattering technique presented here, which corresponds to the SM technique, is known as nuclear forward scattering (NFS). Current applications in physics and chemistry are described. NFS is compared with the usual SM technique, to highlight its advantages and disadvantages.

Readers are invited to consult the articles Spectrométrie Mössbauer and Synchrotron Radiation and Applications .

You do not have access to this resource.
Logo Techniques de l'Ingenieur

Exclusive to subscribers. 97% yet to be discovered!

You do not have access to this resource. Click here to request your free trial access!

Already subscribed?


Ongoing reading
Resonant nuclear scattering with synchrotron radiation

Article included in this offer

"Analysis and Characterization"

( 271 articles )

Complete knowledge base

Updated and enriched with articles validated by our scientific committees

Services

A set of exclusive tools to complement the resources

View offer details

Dans les ressources documentaires

Spectro-imagerie térahertz - Voir autrement

Les ondes électromagnétiques térahertz suscitent la curiosité et l'engouement à la fois des scientifiques...

Spectroscopie térahertz

La spectroscopie impulsionnelle apporte une quantité d'informations considérables sur les systèmes physic...

Tomographie à l'aide de rayons térahertz

La tomographie par rayonnement térahertz est une technique de contrôle non destructif (CND) permettant d'...

WhitePaper
4 December 2018
Caméra thermique : FLIRGFx320

Caméra infrarouge pour la détection des gaz à sécurité intrinsèque. Description produit de deux pages

Tous les livres blancs
Toutes les actualités
Contact us