Wenhui Xu , Shoucong Ning , Pengju Sheng , Huixiang Lin , Angus I Kirkland , Yong Peng , Fucai Zhang
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引用次数: 0
摘要
目前,层析成像技术已成为主流显微镜技术的一种工具,可在宽视场范围内进行定量和高分辨率成像。然而,在使用电子或实验室 X 射线源时,其最终性能不可避免地受到可用相干通量的限制。我们提出了一种通用的重建算法,对远场和近场层析成像的低相干性具有很高的容忍度。这种方法适用于部分时间和空间相干性,而且不需要事先了解光源特性。我们最初的可见光和电子数据表明,该方法能显著提高重建质量,并加快重建的收敛速度。这种方法还能很好地集成到现有的分色引擎中。它还能改进混合状态和数值单色化方法,需要更少的相干模式或更低维度的克雷洛夫子空间,同时提供更稳定和更快的收敛速度。我们认为,这种方法可以对弱散射样本的层析成像产生重大影响。
A high-performance reconstruction method for partially coherent ptychography
Ptychography is now integrated as a tool in mainstream microscopy allowing quantitative and high-resolution imaging capabilities over a wide field of view. However, its ultimate performance is inevitably limited by the available coherent flux when implemented using electrons or laboratory X-ray sources. We present a universal reconstruction algorithm with high tolerance to low coherence for both far-field and near-field ptychography. The approach is practical for partial temporal and spatial coherence and requires no prior knowledge of the source properties. Our initial visible-light and electron data show that the method can dramatically improve the reconstruction quality and accelerate the convergence rate of the reconstruction. The approach also integrates well into existing ptychographic engines. It can also improve mixed-state and numerical monochromatisation methods, requiring a smaller number of coherent modes or lower dimensionality of Krylov subspace while providing more stable and faster convergence. We propose that this approach could have significant impact on ptychography of weakly scattering samples.
期刊介绍:
Ultramicroscopy is an established journal that provides a forum for the publication of original research papers, invited reviews and rapid communications. The scope of Ultramicroscopy is to describe advances in instrumentation, methods and theory related to all modes of microscopical imaging, diffraction and spectroscopy in the life and physical sciences.