Effect of fibrin sealant on blood loss following total knee arthroplasty: A systematic review and meta-analysis

The ability of electron microscopes to analyze all the atoms in individual nanostructures is limited by lens aberrations. However, recent advances in aberration-correcting electron optics have led to greatly enhanced instrument performance and new techniques of electron microscopy. The development of an ultrastable electron microscope with aberration-correcting optics and a monochromated high-brightness source has significantly improved instrument resolution and contrast. In the present work, we report information transfer beyond 50 pm and show images of single gold atoms with a signal-to-noise ratio as large as 10. The instrument's new capabilities were exploited to detect a buried Sigma3 {112} grain boundary and observe the dynamic arrangements of single atoms and atom pairs with sub-angstrom resolution. These results mark an important step toward meeting the challenge of determining the three-dimensional atomic-scale structure of nanomaterials.

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Transmission electron microscopy at 20kV for imaging and spectroscopy

Kaiser

et al. 2011

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Chromatic Aberration Correction for Atomic Resolution TEM Imaging from 20 to 80 kV

et al. 2016

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Atomic resolution in transmission electron microscopy of thin and light-atom materials requires a rigorous reduction of the beam energy to reduce knockon damage. However, at the same time, the chromatic aberration deteriorates the resolution of the TEM image dramatically. Within the framework of the SALVE project, we introduce a newly developed C_{c}/C_{s} corrector that is capable of correcting both the chromatic and the spherical aberration in the range of accelerating voltages from 20 to 80 kV. The corrector allows correcting axial aberrations up to fifth order as well as the dominating off-axial aberrations. Over the entire voltage range, optimum phase-contrast imaging conditions for weak signals from light atoms can be adjusted for an optical aperture of at least 55 mrad. The information transfer within this aperture is no longer limited by chromatic aberrations. We demonstrate the performance of the microscope using the examples of 30 kV phase-contrast TEM images of graphene and molybdenum disulfide, showing unprecedented contrast and resolution that matches image calculations.

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First application of Cc-corrected imaging for high-resolution and energy-filtered TEM

Kabius¹,

Hartel²,

Haider³

et al. 2009

Journal of Electron Microscopy

126

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Contrast-transfer calculations indicate that C(c) correction should be highly beneficial for high-resolution and energy-filtered transmission electron microscopy. A prototype of an electron optical system capable of correcting spherical and chromatic aberration has been used to verify these calculations. A strong improvement in resolution at an acceleration voltage of 80 kV has been measured. Our first C(c)-corrected energy-filtered experiments examining a (LaAlO(3))(0.3)(Sr(2)AlTaO(6))(0.7)/LaCoO(3) interface demonstrated a significant gain for the spatial resolution in elemental maps of La.

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Information Transfer in a TEM Corrected for Spherical and Chromatic Aberration

et al. 2010

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For the transmission electron aberration-corrected microscope (TEAM) initiative of five U.S. Department of Energy laboratories in the United States, a correction system for the simultaneous compensation of the primary axial aberrations, the spherical aberration Cs, and the chromatic aberration Cc has been developed and successfully installed. The performance of the resulting Cc /Cs-corrected TEAM instrument has been investigated thoroughly. A significant improvement of the linear contrast transfer can be demonstrated. The information about the instrument one obtains using Young's fringe method is compared for uncorrected, Cs-corrected, and Cc /Cs-corrected instruments. The experimental results agree well with simulations. The conclusions might be useful to others in understanding the process of image formation in a Cc /Cs-corrected transmission electron microscope.

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Advancing the Hexapole C_s-Corrector for the Scanning Transmission Electron Microscope

et al. 2006

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Aberration correctors using hexapole fields have proven useful to correct for the spherical aberration in electron microscopy. We investigate the limits of the present design for the hexapole corrector with respect to minimum probe size for the scanning transmission electron microscope and discuss several ways in which the design could be improved by rather small and incremental design changes for the next generation of advanced probe-forming systems equipped with a gun monochromator.

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Thermal Magnetic Field Noise Limits Resolution in Transmission Electron Microscopy

et al. 2013

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The resolving power of an electron microscope is determined by the optics and the stability of the instrument. Recently, progress has been obtained towards subångström resolution at beam energies of 80 kV and below but a discrepancy between the expected and achieved instrumental information limit has been observed. Here we show that magnetic field noise from thermally driven currents in the conductive parts of the instrument is the root cause for this hitherto unexplained decoherence phenomenon. We demonstrate that the deleterious effect depends on temperature and at least weakly on the type of material.

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Prerequisites for a Cc/Cs-corrected ultrahigh-resolution TEM

et al. 2008

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Heiko Müller

Detection of Single Atoms and Buried Defects in Three Dimensions by Aberration-Corrected Electron Microscope with 0.5-Å Information Limit

Transmission electron microscopy at 20kV for imaging and spectroscopy

Chromatic Aberration Correction for Atomic Resolution TEM Imaging from 20 to 80 kV

First application of Cc-corrected imaging for high-resolution and energy-filtered TEM

Information Transfer in a TEM Corrected for Spherical and Chromatic Aberration

Advancing the Hexapole C_s-Corrector for the Scanning Transmission Electron Microscope

Thermal Magnetic Field Noise Limits Resolution in Transmission Electron Microscopy

Prerequisites for a Cc/Cs-corrected ultrahigh-resolution TEM

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Heiko Müller

Detection of Single Atoms and Buried Defects in Three Dimensions by Aberration-Corrected Electron Microscope with 0.5-Å Information Limit

Transmission electron microscopy at 20kV for imaging and spectroscopy

Chromatic Aberration Correction for Atomic Resolution TEM Imaging from 20 to 80 kV

First application of Cc-corrected imaging for high-resolution and energy-filtered TEM

Information Transfer in a TEM Corrected for Spherical and Chromatic Aberration

Advancing the Hexapole Cs-Corrector for the Scanning Transmission Electron Microscope

Thermal Magnetic Field Noise Limits Resolution in Transmission Electron Microscopy

Prerequisites for a Cc/Cs-corrected ultrahigh-resolution TEM

Contact Info

Product

Resources

About

Advancing the Hexapole C_s-Corrector for the Scanning Transmission Electron Microscope