利用级偏置电位对探测光束进行减速,提高了连续块面扫描电镜图像的分辨率

James C. Bouwer, Thomas J. Deerinck, Eric Bushong, Vadim Astakhov, Ranjan Ramachandra, Steven T. Peltier, Mark H. Ellisman
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引用次数: 26

摘要

连续块面扫描电子显微镜(SBEM)正迅速成为跨空间尺度探索三维生物结构的重要成像工具。探测束电子能量为2.0?keV或更低,轴向分辨率应提高,因为有较少的初级电子渗透到块面。更具体地说,在这些较低的能量下,相互作用体积要小得多,因此,表面细节的分辨率更高。然而,在这些较低的能量下,金属造影剂的背散射电子产率和背散射电子探测器的灵敏度都不是最佳的,从而抵消了轴向分辨率的增益。我们发现,将负电压(反转电位)应用于改进的SBEM级,可以在样品处产生可调谐的电场。利用该场可以降低探测波束的着陆能量,同时改变信号的轨迹,增加探测器采集到的信号。随着低着陆能电子的减速,我们观察到探针束的电子穿透深度减少到小于30?纳米在环氧树脂包埋的生物标本。同时,由于偏压场中的bse向探测器所在的目标极片重新加速,记录的信号大量增加。通过调整偏置场,我们能够操纵主电子和次级电子的轨迹,使这些信号的空间辨别使用先进的?环形疯牛病探测器配置或标准单片疯牛病探测器与阻塞孔径耦合。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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Deceleration of probe beam by stage bias potential improves resolution of serial block-face scanning electron microscopic images

Serial block-face scanning electron microscopy (SBEM) is quickly becoming an important imaging tool to explore three-dimensional biological structure across spatial scales. At probe-beam-electron energies of 2.0?keV or lower, the axial resolution should improve, because there is less primary electron penetration into the block face. More specifically, at these lower energies, the interaction volume is much smaller, and therefore, surface detail is more highly resolved. However, the backscattered electron yield for metal contrast agents and the backscattered electron detector sensitivity are both sub-optimal at these lower energies, thus negating the gain in axial resolution. We found that the application of a negative voltage (reversal potential) applied to a modified SBEM stage creates a tunable electric field at the sample. This field can be used to decrease the probe-beam-landing energy and, at the same time, alter the trajectory of the signal to increase the signal collected by the detector. With decelerated low landing-energy electrons, we observed that the probe-beam-electron-penetration depth was reduced to less than 30?nm in epoxy-embedded biological specimens. Concurrently, a large increase in recorded signal occurred due to the re-acceleration of BSEs in the bias field towards the objective pole piece where the detector is located. By tuning the bias field, we were able to manipulate the trajectories of the ?primary and secondary electrons, enabling the spatial discrimination of these signals using an advanced?ring-type BSE detector configuration or a standard monolithic BSE detector coupled with a blocking aperture.

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Advanced Structural and Chemical Imaging
Advanced Structural and Chemical Imaging Medicine-Radiology, Nuclear Medicine and Imaging
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