Pixelated detectors and improved efficiency for magnetic imaging in STEM differential phase contrast

Krajnak, Matus; McGrouther, Damien; Maneuski, D.; Shea, Val O.; McVitie, S.

doi:10.1016/j.ultramic.2016.03.006

Cited by 139 publications

(114 citation statements)

References 22 publications

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“…Since the Sobel filter is a simple matrix, it can be applied across datasets without concern for effects caused by changing user defined thresholds, and is much faster and impartial than an iterative method. Sobel filtering has been shown to improve cross correlation accuracy of the forward scattered disk, useful in differential phase contrast imaging, but has not been robustly tested with diffracted disks containing dynamical contrast [26].…”

Section: Methods For Determining Diffraction Disk Positionsmentioning

confidence: 99%

Optimizing disk registration algorithms for nanobeam electron diffraction strain mapping

et al. 2017

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Scanning nanobeam electron diffraction strain mapping is a technique by which the positions of diffracted disks sampled at the nanoscale over a crystalline sample can be used to reconstruct a strain map over a large area. However, it is important that the disk positions are measured accurately, as their positions relative to a reference are directly used to calculate strain. In this study, we compare several correlation methods using both simulated and experimental data in order to directly probe susceptibility to measurement error due to non-uniform diffracted disk illumination structure. We found that prefiltering the diffraction patterns with a Sobel filter before performing cross correlation or performing a square-root magnitude weighted phase correlation returned the best results when inner disk structure was present. We have tested these methods both on simulated datasets, and experimental data from unstrained silicon as well as a twin grain boundary in 304 stainless steel.

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Section: Methods For Determining Diffraction Disk Positionsmentioning

confidence: 99%

Optimizing disk registration algorithms for nanobeam electron diffraction strain mapping

et al. 2017

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“…The recent progress in electron detectors, in particular in pixelated detectors with direct single-electron counting capabilities, have led recently to a new paradigm in transmission electron microscopy by improving the detection efficiency by orders of magnitude (Kü hlbrandt, 2014;McMullan et al, 2009). Indeed, the excellent results from McMullan et al (2007) and Nederlof et al (2013) have driven the very recent developments and the commercialization of hybrid pixel detectors in transmission electron microscopes (Quantum Detectors, 2017;Dectris, 2017;Amsterdam Scientific Instruments, 2017) and scanning transmission electron microscopes (Krajnak et al, 2016;Raighne et al, 2011) at high kinetic energies (40-300 keV) and less stringent vacuum constraints. Also, single-photon-counting pixel detectors like PILATUS (Kraft et al, 2009), EIGER (Dinapoli et al, 2011) and Medipix (Llopart et al, 2002;Gimenez et al, 2015) are widely used in photon science and synchrotron experiments.…”

Section: Introductionmentioning

confidence: 99%

The EIGER detector for low-energy electron microscopy and photoemission electron microscopy

et al. 2017

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EIGER is a single-photon-counting hybrid pixel detector developed at the Paul Scherrer Institut, Switzerland. It is designed for applications at synchrotron light sources with photon energies above 5 keV. Features of EIGER include a small pixel size (75 µm × 75 µm), a high frame rate (up to 23 kHz), a small dead-time between frames (down to 3 µs) and a dynamic range up to 32-bit. In this article, the use of EIGER as a detector for electrons in low-energy electron microscopy (LEEM) and photoemission electron microscopy (PEEM) is reported. It is demonstrated that, with only a minimal modification to the sensitive part of the detector, EIGER is able to detect electrons emitted or reflected by the sample and accelerated to 8-20 keV. The imaging capabilities are shown to be superior to the standard microchannel plate detector for these types of applications. This is due to the much higher signal-to-noise ratio, better homogeneity and improved dynamic range. In addition, the operation of the EIGER detector is not affected by radiation damage from electrons in the present energy range and guarantees more stable performance over time. To benchmark the detector capabilities, LEEM experiments are performed on selected surfaces and the magnetic and electronic properties of individual iron nanoparticles with sizes ranging from 8 to 22 nm are detected using the PEEM endstation at the Surface/Interface Microscopy (SIM) beamline of the Swiss Light Source.

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“…This diffraction contrast completely masks the magnetic contrast in standard DPC, however, the more advanced processing enabled by pixelated detectors can reduce this contrast and allow for successful quantitative imaging with DPC. [44][45][46] As outlined in existing studies, [45,46] the beam Lorentz deflection angle β from perpendicularly magnetized materials depends on the sample tilt and is proportional to B s . Figure 5a shows a DPC image from a 5 × 10 16 ions per cm 2 defect site on sample 1 in a field of 10 mT.…”

Section: Resultsmentioning

confidence: 99%

Controlled Individual Skyrmion Nucleation at Artificial Defects Formed by Ion Irradiation

Fallon

Hughes

Zeissler

et al. 2020

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Magnetic skyrmions are particle‐like deformations in a magnetic texture. They have great potential as information carriers in spintronic devices because of their interesting topological properties and favorable motion under spin currents. A new method of nucleating skyrmions at nanoscale defect sites, created in a controlled manner with focused ion beam irradiation, in polycrystalline magnetic multilayer samples with an interfacial Dzyaloshinskii–Moriya interaction, is reported. This new method has three notable advantages: 1) localization of nucleation; 2) stability over a larger range of external field strengths, including stability at zero field; and 3) existence of skyrmions in material systems where, prior to defect fabrication, skyrmions were not previously obtained by field cycling. Additionally, it is observed that the size of defect nucleated skyrmions is uninfluenced by the defect itself—provided that the artificial defects are controlled to be smaller than the inherent skyrmion size. All of these characteristics are expected to be useful toward the goal of realizing a skyrmion‐based spintronic device. This phenomenon is studied with a range of transmission electron microscopy techniques to probe quantitatively the magnetic behavior at the defects with applied field and correlate this with the structural impact of the defects.

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Pixelated detectors and improved efficiency for magnetic imaging in STEM differential phase contrast

Cited by 139 publications

References 22 publications

Optimizing disk registration algorithms for nanobeam electron diffraction strain mapping

Optimizing disk registration algorithms for nanobeam electron diffraction strain mapping

The EIGER detector for low-energy electron microscopy and photoemission electron microscopy

Controlled Individual Skyrmion Nucleation at Artificial Defects Formed by Ion Irradiation

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