In-Lens Band-Pass Filter for Secondary Electrons in Ultrahigh Resolution SEM

Konvalina, Ivo; Mika, Filip; Krátký, Stanislav; Mikmeková, Eliška; Müllerová, Ilona

doi:10.3390/ma12142307

Cited by 11 publications

(12 citation statements)

References 29 publications

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“…The SEMs we used allow observing samples in four imaging modes. Two modes of objective lens, namely high resolution (HR) and ultra-high resolution (UHR), differ by their resolution and by the presence or absence of a magnetic field around the sample [ 9 , 44 ]. If the beam deceleration (BD) mode is chosen, then an electrostatic field around the sample is added and two further microscope modes HR+BD and UHR+BD, become available.…”

Section: Methodsmentioning

confidence: 99%

Quantification of STEM Images in High Resolution SEM for Segmented and Pixelated Detectors

et al. 2021

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The segmented semiconductor detectors for transmitted electrons in ultrahigh resolution scanning electron microscopes allow observing samples in various imaging modes. Typically, two standard modes of objective lens, with and without a magnetic field, differ by their resolution. If the beam deceleration mode is selected, then an electrostatic field around the sample is added. The trajectories of transmitted electrons are influenced by the fields below the sample. The goal of this paper is a quantification of measured images and theoretical study of the capability of the detector to collect signal electrons by its individual segments. Comparison of measured and ray-traced simulated data were difficult in the past. This motivated us to present a new method that enables better comparison of the two datasets at the cost of additional measurements, so-called calibration curves. Furthermore, we also analyze the measurements acquired using 2D pixel array detector (PAD) that provide a more detailed angular profile. We demonstrate that the radial profiles of STEM and/or 2D-PAD data are sensitive to material composition. Moreover, scattering processes are affected by thickness of the sample as well. Hence, comparing the two experimental and simulation data can help to estimate composition or the thickness of the sample.

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Section: Methodsmentioning

confidence: 99%

Quantification of STEM Images in High Resolution SEM for Segmented and Pixelated Detectors

et al. 2021

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“…However, in situ experiments are not possible and nanodomain switching cannot be captured, and the added conductive layer can limit further investigations with other microscopy techniques, such as conductive or electrostatic force microscopy . The pilot experiments were performed within a high-resolution SEM, Magellan 400 L, equipped with the beam-deceleration mode . Its schematic sketch with the detector position is illustrated in Figure a.…”

Section: Methodsmentioning

confidence: 99%

Imaging Ferroelectric Nanodomains in Strained BiFeO₃ Nanoscale Films Using Scanning Low-Energy Electron Microscopy: Implications for Low-Power Devices

Mikmeková

Konvalina

et al. 2021

ACS Appl. Nano Mater.

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Precise control of ferroelectric and multiferroic domain states at the nanoscale is of considerable interest due to the potential to boost the development of next-generation low-energy-consumption nanoelectronic components. Progress in this field is closely related to advances in spatially resolved characterization methods. In this regard, scanning electron microscopy (SEM) as a powerful and highly versatile imaging technique with diversified inner detectors possesses huge potential for scale-bridging microscopy studies (spanning from micrometers to nanometers). Here, both the phase variants and the ordered ferroelectric nanodomains of the tetragonal-like (T) phase in the rhombohedral-like (R) and T mixed-phase BiFeO3 nanoscale film are acquired simultaneously using the surface-sensitive scanning low-energy electron microscopy (SLEEM) for the first time. In particular, backscattered electron (BSE) signals, which bring abundant polarization information, can be utilized to discern polarized discrepancy in mixed-phase BiFeO3 nanoscale films. Furthermore, it is demonstrated that the polarization contrast of nanodomains increases with increasing ratio of the low-loss BSEs in the collected signal. Electron trajectories simulation enables us to optimize and separate morphological and polarization contrast in angle-selective BSEs imaging in the presence of a deceleration field. SLEEM combines with other nanocharacterization and fabrication techniques, such as three-dimensional (3D) atom probe tomography, opening up new opportunities for tackling the complex nanoscale physics and defect chemistry of ferroelectric nanomaterials.

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“…The electrical potential of the mirror electrode and the suction tube can be adjusted to alter the detection characteristic of the TLD. More details of the TLD capabilities are outlined by Konvalina et al [19]. In contrast to the previously mentioned detector, the concentric backscatter detector (CBS), mirror detector (MD) and in-column detector (ICD) are solid-state semiconductor detectors designed for capturing backscattered electrons.…”

Section: Original Research Papermentioning

confidence: 99%

Optimization of Material Contrast for Efficient FIB‐SEM Tomography of Solid Oxide Fuel Cells

et al. 2020

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Focused ion beam (FIB)-scanning electron microscopy (SEM) serial sectioning tomography has become an important tool for three-dimensional microstructure reconstruction of solid oxide fuel cells (SOFC) to obtain an understanding of fabrication-related effects and SOFC performance. By sequential FIB milling and SEM imaging a stack of cross-section images across all functional SOFC layers was generated covering a large volume of 3.5Á10 4 μm 3. One crucial step is image segmentation where regions with different image intensities are assigned to different material phases within the SOFC. To analyze all relevant SOFC materials, it was up to now mandatory to acquire several images by scanning the same region with different imaging parameters because sufficient material contrast could otherwise not be achieved. In this work we obtained high-contast SEM images from a single scan to reconstract all functional SOFC layers consisting of a Ni/Y 2 O 3-doped ZrO 2 (YDZ) cermet anode, YDZ electrolyte and (La,Sr)MnO 3 /YDZ cathode. This was possible by using different, simultaneous read-out detectors installed in a stateof-the-art scanning electron microscope. In addition, we used a deterministic approach for the optimization of imaging parameters by employing Monte Carlo simulations rather than trial-and-error tests. We also studied the effect of detection geometry, detecting angle range and detector type.

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In-Lens Band-Pass Filter for Secondary Electrons in Ultrahigh Resolution SEM

Cited by 11 publications

References 29 publications

Quantification of STEM Images in High Resolution SEM for Segmented and Pixelated Detectors

Quantification of STEM Images in High Resolution SEM for Segmented and Pixelated Detectors

Imaging Ferroelectric Nanodomains in Strained BiFeO₃ Nanoscale Films Using Scanning Low-Energy Electron Microscopy: Implications for Low-Power Devices

Optimization of Material Contrast for Efficient FIB‐SEM Tomography of Solid Oxide Fuel Cells

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In-Lens Band-Pass Filter for Secondary Electrons in Ultrahigh Resolution SEM

Cited by 11 publications

References 29 publications

Quantification of STEM Images in High Resolution SEM for Segmented and Pixelated Detectors

Quantification of STEM Images in High Resolution SEM for Segmented and Pixelated Detectors

Imaging Ferroelectric Nanodomains in Strained BiFeO3 Nanoscale Films Using Scanning Low-Energy Electron Microscopy: Implications for Low-Power Devices

Optimization of Material Contrast for Efficient FIB‐SEM Tomography of Solid Oxide Fuel Cells

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Imaging Ferroelectric Nanodomains in Strained BiFeO₃ Nanoscale Films Using Scanning Low-Energy Electron Microscopy: Implications for Low-Power Devices