Three-dimensional phase contrast imaging of multiply-scattering samples in X-ray and electron microscopy is extremely challenging, due to small numerical apertures, the unavailability of wavefront shaping optics, and the highly nonlinear inversion required from intensity-only measurements. In this work, we present a new algorithm using the scattering matrix formalism to solve the scattering from a non-crystalline medium from scanning diffraction measurements, and recover the illumination aberrations. Our method will enable 3D imaging and materials characterization at high resolution for a wide range of materials
It is demonstrated that the usual theorem of diffraction tomography may, in many cases, be replaced ...
The imaging of crystal defects by high-resolution transmission electron microscopy or with the help ...
Free-electron lasers now have the ability to collect X-ray diffraction patterns from individual mole...
Three-dimensional phase-contrast imaging of multiply-scattering samples in x-ray and electron micros...
Recent work has revived interest in the scattering matrix formulation of electron scattering in tran...
Electron tomography is used in both materials science and structural biology to image features well ...
A unified method for three-dimensional reconstruction of objects from transmission images collected ...
An iterated projection algorithm (N-Phaser) is developed that reconstructs a scattering potential fr...
International audienceThe three-dimensional characterization method described herein is based on dif...
International audienceTomographic diffraction microscopy is a three-dimensional quantitative optical...
Abstract: A solution to the phase problem for diffraction by twodimensional crystalline slabs is des...
Progress in nanotechnology and biotechnology are propelled by our ability to manipulate and resolve ...
Imaging an object hidden behind a highly scattering medium is difficult since the wave has gone thro...
Electron holography and other wave reconstruction techniques allow one to directly determine the sca...
In coherent X-ray diffraction microscopy the diffraction pattern generated by a sample illuminated w...
It is demonstrated that the usual theorem of diffraction tomography may, in many cases, be replaced ...
The imaging of crystal defects by high-resolution transmission electron microscopy or with the help ...
Free-electron lasers now have the ability to collect X-ray diffraction patterns from individual mole...
Three-dimensional phase-contrast imaging of multiply-scattering samples in x-ray and electron micros...
Recent work has revived interest in the scattering matrix formulation of electron scattering in tran...
Electron tomography is used in both materials science and structural biology to image features well ...
A unified method for three-dimensional reconstruction of objects from transmission images collected ...
An iterated projection algorithm (N-Phaser) is developed that reconstructs a scattering potential fr...
International audienceThe three-dimensional characterization method described herein is based on dif...
International audienceTomographic diffraction microscopy is a three-dimensional quantitative optical...
Abstract: A solution to the phase problem for diffraction by twodimensional crystalline slabs is des...
Progress in nanotechnology and biotechnology are propelled by our ability to manipulate and resolve ...
Imaging an object hidden behind a highly scattering medium is difficult since the wave has gone thro...
Electron holography and other wave reconstruction techniques allow one to directly determine the sca...
In coherent X-ray diffraction microscopy the diffraction pattern generated by a sample illuminated w...
It is demonstrated that the usual theorem of diffraction tomography may, in many cases, be replaced ...
The imaging of crystal defects by high-resolution transmission electron microscopy or with the help ...
Free-electron lasers now have the ability to collect X-ray diffraction patterns from individual mole...