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Bragg Ptychography : When Crystallography Meets Microscopy

par Caroline CHAMPENOIS - publié le

séminaire du laboratoire
mardi 12 septembre, 11:00, service 322 campus Saint-Jérôme

Virginie Chamard,

Institut Fresnel (AMU-CNRS-ECM, Marseille)

abstract : (talk in English, depending on the audience, présentation en français en fonction du public)

Imaging complex crystalline materials at the nanoscale is a major challenge of nanoscience, which calls for a microscopy method combining sensitivity to the crystalline properties, 3D imaging capability, in situ compatibility and high spatial resolution. In this context, the recent advents of x-ray lensless imaging methods, based on Bragg coherent diffraction, have opened promising perspectives [1] filling the gap between direct microscopies (AFM, SEM, TEM) and reciprocal-space based x-ray Bragg diffraction analysis.
3D Bragg ptychography microscopy [2] is a coherent diffraction imaging method developed at third generation synchrotron sources, and which merges concepts developed in inverse microscopy and crystallography. This modality is based on the acquisition of far-field Bragg coherent intensity patterns ; It exploits the partially redundant information obtained by scanning a finite beam spot size transversally to the sample, while measuring the corresponding 3D far-field intensity diffraction pattern by scanning angularly the sample along the rocking curve. Instead of lenses, numerical tools are employed to retrieve the phase of the field, which is lost during intensity measurements [3]. The back-propagation of the field gives access to the complex-valued sample scattering contrast. Thereby, truly quantitative information is obtained, such as the crystalline displacement field, from which the 3D strain component and crystalline plane rotations can be derived, with nanoscale spatial resolution. 3D imaging of extended crystalline samples is then possible [2, 4], opening Bragg coherent diffraction microscopy to a large range of applications.
In this presentation, the general concepts of Bragg ptychography will be first detailed, illustrated by recently proposed developments [2-7]. We will further describe how Bragg ptychography can be exploited to bring new insights on a specific class of materials, the biominerals, which are characterized by a complex hierarchical crystalline structure. Perspectives with respects to the understanding of the biomineralization mechanisms will be finally presented [8].

This project has received funding from the European Research Council (ERC) under the European Union’s Horizon H2020 research and innovation program grant agreement No 695093.

[1] M. A. Pfeifer, et al., Nature 442, 63 (2006). A. Ulvestad, et al., Science 348, 1344-1347 (2015).
[2] P. Godard, et al., Nature Communications 2, 568 (2011).
[3] P. Godard, et al., Optics Express 20, 25914 (2012).
[4] F. Berenguer, et al., Physical Review B 88, 144101 (2013).
[5] A. I. Pateras, et al., Physical Review B 92, 205305 (2015).
[6] V. Chamard, et al., Scientific Reports 5, 9827 (2015).
[7] S. O. Hruszkewycz, et al., Nature Materials 16 244 (2017).
[8] F. Mastropietro, et al., Nature Materials 16, 946 (2017).

contact : Caroline Champenois


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