Progress toward an aberration-corrected low energy electron microscope for DNA sequencing and surface analysis.

IF 1.5 4区 工程技术 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC
Marian Mankos, Khashayar Shadman, Alpha T N'diaye, Andreas K Schmid, Henrik H J Persson, Ronald W Davis
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引用次数: 0

Abstract

Monochromatic, aberration-corrected, dual-beam low energy electron microscopy (MAD-LEEM) is a novel imaging technique aimed at high resolution imaging of macromolecules, nanoparticles, and surfaces. MAD-LEEM combines three innovative electron-optical concepts in a single tool: a monochromator, a mirror aberration corrector, and dual electron beam illumination. The monochromator reduces the energy spread of the illuminating electron beam, which significantly improves spectroscopic and spatial resolution. The aberration corrector is needed to achieve subnanometer resolution at landing energies of a few hundred electronvolts. The dual flood illumination approach eliminates charging effects generated when a conventional, single-beam LEEM is used to image insulating specimens. The low landing energy of electrons in the range of 0 to a few hundred electronvolts is also critical for avoiding radiation damage, as high energy electrons with kilo-electron-volt kinetic energies cause irreversible damage to many specimens, in particular biological molecules. The performance of the key electron-optical components of MAD-LEEM, the aberration corrector combined with the objective lens and a magnetic beam separator, was simulated. Initial results indicate that an electrostatic electron mirror has negative spherical and chromatic aberration coefficients that can be tuned over a large parameter range. The negative aberrations generated by the electron mirror can be used to compensate the aberrations of the LEEM objective lens for a range of electron energies and provide a path to achieving subnanometer spatial resolution. First experimental results on characterizing DNA molecules immobilized on Au substrates in a LEEM are presented. Images obtained in a spin-polarized LEEM demonstrate that high contrast is achievable at low electron energies in the range of 1-10 eV and show that small changes in landing energy have a strong impact on the achievable contrast. The MAD-LEEM approach promises to significantly improve the performance of a LEEM for a wide range of applications in the biosciences, material sciences, and nanotechnology where nanometer scale resolution and analytical capabilities are required. In particular, the microscope has the potential of delivering images of unlabeled DNA strands with nucleotide-specific contrast. This simplifies specimen preparation and significantly eases the computational complexity needed to assemble the DNA sequence from individual reads.

用于 DNA 测序和表面分析的畸变校正低能电子显微镜的研究进展。
单色、像差校正、双光束低能电子显微镜(MAD-LEEM)是一种新型成像技术,旨在对大分子、纳米粒子和表面进行高分辨率成像。MAD-LEEM 将三个创新的电子光学概念融合在一个工具中:单色器、镜像像差校正器和双电子束照明。单色仪可减少照明电子束的能量扩散,从而显著提高光谱和空间分辨率。为了在几百电子伏特的着陆能量下实现亚纳米分辨率,需要使用像差校正器。双泛光照明方法消除了传统单光束 LEEM 在对绝缘试样成像时产生的充电效应。0 到几百电子伏特范围内的低电子着陆能量对于避免辐射损伤也至关重要,因为动能达到千电子伏特的高能电子会对许多标本,特别是生物分子造成不可逆的损伤。对 MAD-LEEM 的关键电子光学组件--结合物镜的像差校正器和磁束分离器--的性能进行了模拟。初步结果表明,静电电子镜具有负球差和色差系数,可以在很大的参数范围内进行调整。电子镜产生的负像差可用于补偿 LEEM 物镜在一定电子能量范围内的像差,并为实现亚纳米级空间分辨率提供了途径。本文首次介绍了在 LEEM 中鉴定固定在金基底上的 DNA 分子的实验结果。在自旋极化 LEEM 中获得的图像表明,在 1-10 eV 的低电子能量范围内可以实现高对比度,并表明着陆能量的微小变化对可实现的对比度有很大影响。MAD-LEEM 方法有望显著提高 LEEM 的性能,广泛应用于生物科学、材料科学和纳米技术等需要纳米级分辨率和分析能力的领域。特别是,该显微镜可提供具有核苷酸特异性对比度的未标记 DNA 链图像。这不仅简化了标本制备过程,还大大降低了从单个读数组装 DNA 序列所需的计算复杂性。
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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来源期刊
CiteScore
2.70
自引率
0.00%
发文量
146
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