Silja Flenner, Johannes Hagemann, Felix Wittwer, Elena Longo, Adam Kubec, André Rothkirch, Christian David, Martin Müller, Imke Greving
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引用次数: 0
Abstract
Full-field X-ray nanoimaging is a widely used tool in a broad range of scientific areas. In particular, for low-absorbing biological or medical samples, phase contrast methods have to be considered. Three well established phase contrast methods at the nanoscale are transmission X-ray microscopy with Zernike phase contrast, near-field holography and near-field ptychography. The high spatial resolution, however, often comes with the drawback of a lower signal-to-noise ratio and significantly longer scan times, compared with microimaging. In order to tackle these challenges a single-photon-counting detector has been implemented at the nanoimaging endstation of the beamline P05 at PETRA III (DESY, Hamburg) operated by Helmholtz-Zentrum Hereon. Thanks to the long sample-to-detector distance available, spatial resolutions of below 100 nm were reached in all three presented nanoimaging techniques. This work shows that a single-photon-counting detector in combination with a long sample-to-detector distance allows one to increase the time resolution for in situ nanoimaging, while keeping a high signal-to-noise level.
全场 X 射线纳米成像是广泛应用于各种科学领域的工具。特别是对于低吸收的生物或医学样品,必须考虑采用相衬方法。在纳米尺度上有三种成熟的相衬方法,即带 Zernike 相衬的透射 X 射线显微镜法、近场全息法和近场层析成像法。然而,与显微成像相比,高空间分辨率往往具有信噪比低和扫描时间长的缺点。为了应对这些挑战,亥姆霍兹中心(Helmholtz-Zentrum Hereon)在 PETRA III(汉堡 DESY)P05 光束线的纳米成像端站安装了单光子计数探测器。由于样品到探测器之间的距离较长,所有三种纳米成像技术的空间分辨率都低于 100 纳米。这项工作表明,单光子计数探测器与较长的样品到探测器距离相结合,可以提高原位纳米成像的时间分辨率,同时保持较高的信噪比水平。
期刊介绍:
Synchrotron radiation research is rapidly expanding with many new sources of radiation being created globally. Synchrotron radiation plays a leading role in pure science and in emerging technologies. The Journal of Synchrotron Radiation provides comprehensive coverage of the entire field of synchrotron radiation and free-electron laser research including instrumentation, theory, computing and scientific applications in areas such as biology, nanoscience and materials science. Rapid publication ensures an up-to-date information resource for scientists and engineers in the field.