Background, status and future of the Transmission Electron Aberration-corrected Microscope project

Dahmen, U.; Erni, Rolf; Radmilović, Velimir; Ksielowski, Christian; Rossell, Marta D.; Denes, P.

doi:10.1098/rsta.2009.0094

Cited by 90 publications

(75 citation statements)

References 31 publications

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“…Meanwhile various commercial microscopes are/ or can be optionally equipped with objective lens and/or electron probe correctors (e.g.,TEM/STEMs: FEI Titan, JEOL JEM2200 FS, JEM -ARM200F, dedicated STEMs: Nion UltraSTEM 100 and 200, HITACHI HD-2700). State of the art instruments were developed in the TEAM (Transmission Electron Aberration-corrected Microscope) project, where the microscopes TEAM 0.5 and TEAM I were delivered [38]. The TEAM 0.5 microscope is equipped with a monochromated field emission gun, has two CEOS hexapole correctors for the objective lens and the electron probe and a GATAN GIF Tridiem energy-filter.…”

Section: Discussionmentioning

confidence: 99%

Advanced microstructure diagnostics and interface analysis of modern materials by high-resolution analytical transmission electron microscopy

Neumann¹,

Kirmse²,

Häusler³

et al. 2010

Bulletin of the Polish Academy of Sciences: Technical Sciences

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Abstract. Transmission electron microscopy (TEM) is a powerful diagnostic tool for the determination of structure/property relationships of materials. A comprehensive analysis of materials requires a combined use of a variety of complementary electron microscopical techniques of imaging, diffraction and spectroscopy at an atomic level of magnitude. The possibilities and limitations of quantitative TEM analysis will be demonstrated for interface studies of the following materials and materials systems: Nickel-based superalloy CMSX-10, (Zn,Cd)O/ZnO/Al2O3, (Al,Ga)N/AlN/Al2O3, GaN/LiAlO2 and FeCo-based nanocrystalline alloys.

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Section: Discussionmentioning

confidence: 99%

Advanced microstructure diagnostics and interface analysis of modern materials by high-resolution analytical transmission electron microscopy

Neumann¹,

Kirmse²,

Häusler³

et al. 2010

Bulletin of the Polish Academy of Sciences: Technical Sciences

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“…TEM characterization was carried-out using a Philips CM300 FEG TEM/STEM (Cs ¼ 0.65 mm) and the double-aberration-corrected FEI TEAM 0.5 TEM/STEM (Cs ¼ 0.005 mm), both with UltraTwin pole pieces and operated at 300 kV without monochromation to ensure comparable information limits (0.8 Å). The TEAM 0.5 microscope is a modified FEI Titan TEM/STEM equipped with two CEOS hexapole-type spherical aberration correctors (0.8 Å information limit without monochromation [26]). Appropriate illumination conditions were established wherein a constant/low electron dose did not modify the Au NP during TEM examination.…”

Section: Methodsmentioning

confidence: 99%

Statistical analysis of support thickness and particle size effects in HRTEM imaging of metal nanoparticles

et al. 2016

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a b s t r a c tHigh-resolution transmission electron microscopy (HRTEM) examination of nanoparticles requires their placement on some manner of support -either TEM grid membranes or part of the material itself, as in many heterogeneous catalyst systems -but a systematic quantification of the practical imaging limits of this approach has been lacking. Here we address this issue through a statistical evaluation of how nanoparticle size and substrate thickness affects the ability to resolve structural features of interest in HRTEM images of metallic nanoparticles on common support membranes. The visibility of lattice fringes from crystalline Au nanoparticles on amorphous carbon and silicon supports of varying thickness was investigated with both conventional and aberration-corrected TEM. Over the 1-4 nm nanoparticle size range examined, the probability of successfully resolving lattice fringes differed significantly as a function both of nanoparticle size and support thickness. Statistical analysis was used to formulate guidelines for the selection of supports and to quantify the impact a given support would have on HRTEM imaging of crystalline structure. For nanoparticles Z1 nm, aberration-correction was found to provide limited benefit for the purpose of visualizing lattice fringes; electron dose is more predictive of lattice fringe visibility than aberration correction. These results confirm that the ability to visualize lattice fringes is ultimately dependent on the signal-to-noise ratio of the HRTEM images, rather than the point-to-point resolving power of the microscope. This study provides a benchmark for HRTEM imaging of crystalline supported metal nanoparticles and is extensible to a wide variety of supports and nanostructures.

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“…In the USA, a major grouping has an ambitious 5-year programme (TEAM) that will culminate in an instrument fitted with spherical aberration correctors both pre-and post-specimen, a post-specimen chromatic aberration corrector, a monochromator, a new high-brightness gun and a novel specimen stage. The current state of this project was reported by Dahmen et al (2009).…”

Section: New Possibilities With Aberration-corrected Electron Microscopymentioning

confidence: 99%

New possibilities with aberration-corrected electron microscopy

Cockayne

Kirkland

Nellist

et al. 2009

Phil. Trans. R. Soc. A.

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Unlike light microscopy, where resolution is diffraction limited, the achievable resolution of electron microscopes is limited by lens aberrations so severe that the practical resolution is orders of magnitude worse than the diffraction limit. About 10 years ago, the first practical electron lens spherical aberration correctors were developed, and in the past decade, their performance, versatility and practical usefulness have been steadily improved. Commercial aberration-corrected instruments are available, and experiments previously deemed impossible are now being undertaken.

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Background, status and future of the Transmission Electron Aberration-corrected Microscope project

Cited by 90 publications

References 31 publications

Advanced microstructure diagnostics and interface analysis of modern materials by high-resolution analytical transmission electron microscopy

Advanced microstructure diagnostics and interface analysis of modern materials by high-resolution analytical transmission electron microscopy

Statistical analysis of support thickness and particle size effects in HRTEM imaging of metal nanoparticles

New possibilities with aberration-corrected electron microscopy

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