Electrostatic subframing and compressive-sensing video in transmission electron microscopy.

IF 2.3 2区 物理与天体物理 Q3 CHEMISTRY, PHYSICAL
Structural Dynamics-Us Pub Date : 2019-09-23 eCollection Date: 2019-09-01 DOI:10.1063/1.5115162
B W Reed, A A Moghadam, R S Bloom, S T Park, A M Monterrosa, P M Price, C M Barr, S A Briggs, K Hattar, J T McKeown, D J Masiel
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引用次数: 11

Abstract

We present kilohertz-scale video capture rates in a transmission electron microscope, using a camera normally limited to hertz-scale acquisition. An electrostatic deflector rasters a discrete array of images over a large camera, decoupling the acquisition time per subframe from the camera readout time. Total-variation regularization allows features in overlapping subframes to be correctly placed in each frame. Moreover, the system can be operated in a compressive-sensing video mode, whereby the deflections are performed in a known pseudorandom sequence. Compressive sensing in effect performs data compression before the readout, such that the video resulting from the reconstruction can have substantially more total pixels than that were read from the camera. This allows, for example, 100 frames of video to be encoded and reconstructed using only 15 captured subframes in a single camera exposure. We demonstrate experimental tests including laser-driven melting/dewetting, sintering, and grain coarsening of nanostructured gold, with reconstructed video rates up to 10 kHz. The results exemplify the power of the technique by showing that it can be used to study the fundamentally different temporal behavior for the three different physical processes. Both sintering and coarsening exhibited self-limiting behavior, whereby the process essentially stopped even while the heating laser continued to strike the material. We attribute this to changes in laser absorption and to processes inherent to thin-film coarsening. In contrast, the dewetting proceeded at a relatively uniform rate after an initial incubation time consistent with the establishment of a steady-state temperature profile.

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透射电子显微镜中的静电亚分支和压缩传感视频。
我们在透射电子显微镜中展示了千赫兹级的视频捕获率,使用的相机通常仅限于赫兹级的采集。静电偏转器在大型相机上光栅化离散的图像阵列,使每个子帧的采集时间与相机读出时间解耦。总变化正则化允许重叠子帧中的特征被正确地放置在每个帧中。此外,该系统可以在压缩感测视频模式下操作,从而以已知的伪随机序列执行偏转。压缩感测实际上在读出之前执行数据压缩,使得重建产生的视频可以具有比从相机读取的总像素多得多的总像素。例如,这允许在单个相机曝光中仅使用15个捕获的子帧来编码和重建100帧视频。我们展示了包括激光驱动的纳米结构金的熔化/去湿、烧结和晶粒粗化在内的实验测试,重建的视频速率高达10 kHz。结果表明,该技术可以用于研究三种不同物理过程的根本不同的时间行为,从而证明了该技术的威力。烧结和粗化都表现出自限制行为,即使加热激光继续照射材料,该过程也基本停止。我们将此归因于激光吸收的变化以及薄膜粗化所固有的过程。相反,在与稳态温度曲线的建立一致的初始孵育时间后,去湿以相对均匀的速率进行。
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来源期刊
Structural Dynamics-Us
Structural Dynamics-Us CHEMISTRY, PHYSICALPHYSICS, ATOMIC, MOLECU-PHYSICS, ATOMIC, MOLECULAR & CHEMICAL
CiteScore
5.50
自引率
3.60%
发文量
24
审稿时长
16 weeks
期刊介绍: Structural Dynamics focuses on the recent developments in experimental and theoretical methods and techniques that allow a visualization of the electronic and geometric structural changes in real time of chemical, biological, and condensed-matter systems. The community of scientists and engineers working on structural dynamics in such diverse systems often use similar instrumentation and methods. The journal welcomes articles dealing with fundamental problems of electronic and structural dynamics that are tackled by new methods, such as: Time-resolved X-ray and electron diffraction and scattering, Coherent diffractive imaging, Time-resolved X-ray spectroscopies (absorption, emission, resonant inelastic scattering, etc.), Time-resolved electron energy loss spectroscopy (EELS) and electron microscopy, Time-resolved photoelectron spectroscopies (UPS, XPS, ARPES, etc.), Multidimensional spectroscopies in the infrared, the visible and the ultraviolet, Nonlinear spectroscopies in the VUV, the soft and the hard X-ray domains, Theory and computational methods and algorithms for the analysis and description of structuraldynamics and their associated experimental signals. These new methods are enabled by new instrumentation, such as: X-ray free electron lasers, which provide flux, coherence, and time resolution, New sources of ultrashort electron pulses, New sources of ultrashort vacuum ultraviolet (VUV) to hard X-ray pulses, such as high-harmonic generation (HHG) sources or plasma-based sources, New sources of ultrashort infrared and terahertz (THz) radiation, New detectors for X-rays and electrons, New sample handling and delivery schemes, New computational capabilities.
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