MATERIAL CHARACTERIZATION BY PDF AND RDF ANALYSIS

Introduction

Pair Distribution Function (PDF) and Radial Distribution Function (RDF) analyses can derive atomic distances and atomic coordinates from an X-ray diffuse scattering pattern regardless of the crystallinity of the materials. Therefore, it is possible to perform the analysis for amorphous materials and nanomaterials that present broad peaks called halos.

Measurements and Results

The X-ray scattering pattern from amorphous materials like amorphous carbon has much broader peaks compared to those of crystalline materials (Fig. 1). These peaks are caused by the X-ray diffuse scattering corresponding to the various C-C distances. Hence, real space information, such as atomic distances and atomic coordination numbers, can be obtained from the inverse Fourier transformation of the X-ray diffuse scattering. Fig. 2 shows an RDF profile, where the horizontal axis is the atomic distance and the vertical axis is the atomic coordination number. Peak positions and integrated intensities correspond to atomic distances and the atomic coordination number of carbon in the structure shown in Fig. 3.

Material characterization by pdf and rdf fig. 1

Fig. 1: X-ray scattering pattern


Material characterization by pdf and rdf fig. 2

Fig. 2: RDF profile from amorphous carbon

Material characterization by pdf and rdf fig. 3Fig. 3: Crystal structure of carbon

 

Recommended equipment and software
► Automated multipurpose X-ray diffractometer SmartLab + High-resolution and high-speed 1D detector D/tex Ultra250 HE + Ellipsoidal multilayer X-ray mirror CBO-E
► Integrated X-ray analysis software SmartLab Studio II (PDF plugin)

RIGAKU RECOMMENDS

SmartLab

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MULTIPURPOSE X-RAY DIFFRACTION SYSTEM WITH BUILT-IN INTELLIGENT GUIDANCE

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