Small angle neutron scattering
نویسنده
چکیده
Small Angle Neutron Scattering (SANS) is a technique that enables to probe the 3-D structure of materials on a typical size range lying from ∼ 1 nm up to ∼ a few 100 nm, the obtained information being statistically averaged on a sample whose volume is ∼ 1 cm3. This very rich technique enables to make a full structural characterization of a given object of nanometric dimensions (radius of gyration, shape, volume or mass, fractal dimension, specific area. . . ) through the determination of the form factor as well as the determination of the way objects are organized within in a continuous media, and therefore to describe interactions between them, through the determination of the structure factor. The specific properties of neutrons (possibility of tuning the scattering intensity by using the isotopic substitution, sensitivity to magnetism, negligible absorption, low energy of the incident neutrons) make it particularly interesting in the fields of soft matter, biophysics, magnetic materials and metallurgy. In particular, the contrast variation methods allow to extract some informations that cannot be obtained by any other experimental techniques. This course is divided in two parts. The first one is devoted to the description of the principle of SANS: basics (formalism, coherent scattering/incoherent scattering, notion of elementary scatterer), form factor analysis (I(q→0), Guinier regime, intermediate regime, Porod regime, polydisperse system), structure factor analysis (2nd Virial coefficient, integral equations, characterization of aggregates), and contrast variation methods (how to create contrast in an homogeneous system, matching in ternary systems, extrapolation to zero concentration, Zero Averaged Contrast). It is illustrated by some representative examples. The second one describes the experimental aspects of SANS to guide user in its future experiments: description of SANS spectrometer, resolution of the spectrometer, optimization of spectrometer configurations, optimization of sample characteristics prior to measurements (thickness, volume, hydrogen content. . . ), standards measurements to be made and principle of data reduction. Résumé. (La Diffusion de Neutrons aux petits angles (DNPA) est une technique permettant de sonder la structure 3-D de matériaux sur une gamme typique de taille comprise entre ∼1 nm) et ∼ quelques 100 nm, les informations obtenues étant statistiquement moyennées sur la taille de l’échantillon dont le volume est d’environ 1 cm3. C’est une technique très puissante car elle permet de faire une caractérisation complète de la structure d’un objet donné de dimensions nanométriques (rayon de giration, forme, volume, masse, dimension fractale, surface spécifique. . . ) grâce à la détermination du facteur de forme, ainsi que la détermination de la manière dont les objets sont organisés au sein d’un milieu continu, et donc de décrire les interactions entre les objets, par la détermination du facteur de structure. Les propriétés spécifiques de neutrons (possibilité de moduler le contraste par substitution isotopique, sensibilité au magnétisme, absorption négligeable, faible énergie des neutrons incidents) la rendent This is an Open Access article distributed under the terms of the Creative Commons Attribution License 4.0, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. Article available at http://www.epj-conferences.org or http://dx.doi.org/10.1051/epjconf/201510401004 EPJ Web of Conferences particulièrement intéressante dans les domaines de la matière molle, de la biophysique, des matériaux magnétiques et de la métallurgie. En particulier, les techniques de variation de contraste permettent d’extraire des informations qui ne peuvent être obtenues par aucune autre technique expérimentale. Ce cours est divisé en deux parties. La première est consacrée à la description du principe de la DNPA : bases de la technique (formalisme, diffusion cohérente/diffusion incohérente, notion de diffuseur élémentaire, analyse du facteur de forme (I (q → 0), régime de Guinier, régime intermédiaire, régime de Porod, système polydisperse), analyse du facteur de structure (2nd coefficient du Viriel, équations intégrales, caractérisation d’agrégats), et méthode de variation de contraste (comment créer un contraste dans un système homogène, annulation de contraste dans un système ternaire, extrapolation à concentration nulle, contraste moyen nul). La seconde partie décrit les aspects expérimentaux de la DNPA afin de guider l’utilisateur dans ses expériences futures: description d’un spectromètre de DNPA, résolution d’un spectromètre, optimisation des configurations du spectromètre, optimisation des caractéristiques de l’échantillon avant les mesures (épaisseur, volume, teneur en hydrogène. . . ), mesures standards à effectuer et principe de la réduction des données.
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تاریخ انتشار 2015