2021
DOI: 10.1017/s1431927621012125
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Advances and Applications of Atomic-Resolution Scanning Transmission Electron Microscopy

Abstract: Although scanning transmission electron microscopy (STEM) images of individual heavy atoms were reported 50 years ago, the applications of atomic-resolution STEM imaging became wide spread only after the practical realization of aberration correctors on field-emission STEM/TEM instruments to form sub-Ångstrom electron probes. The innovative designs and advances of electron optical systems, the fundamental understanding of electron–specimen interaction processes, and the advances in detector technology all play… Show more

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Cited by 18 publications
(8 citation statements)
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References 631 publications
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“…Figure a and b show STEM images of the C1F2(90)–LF14(90) and C3(90)–LF06(90) nanocomposites, revealing a pillar and matrix geometry in the cross-section. As the contrast in the HAADF STEM images is approximately proportional to the atomic number, Z 1.7 , LFO appears brighter than CFO because of the heavy rare earth element Lu ( Z = 71) compared to Co ( Z = 27). The vertical microstructures revealed in cross-section are typical of vertically aligned nanostructures with a range of thicknesses. ,, …”
Section: Results and Discussionmentioning
confidence: 99%
“…Figure a and b show STEM images of the C1F2(90)–LF14(90) and C3(90)–LF06(90) nanocomposites, revealing a pillar and matrix geometry in the cross-section. As the contrast in the HAADF STEM images is approximately proportional to the atomic number, Z 1.7 , LFO appears brighter than CFO because of the heavy rare earth element Lu ( Z = 71) compared to Co ( Z = 27). The vertical microstructures revealed in cross-section are typical of vertically aligned nanostructures with a range of thicknesses. ,, …”
Section: Results and Discussionmentioning
confidence: 99%
“…67−69 The three proposed pathways to circumvent the aberrations of static rotationally symmetric lenses include: (i) incorporating noncircular or multipole lenses that can cancel the positive C s aberration of the round lens by generating a negative C s value, (ii) deploying time-varying fields and (iii) inserting a charge on-axis. 67,70 In the 1990s, multipole correctors based on two designs of octupole/quadrupole and hexapole (sextupole) assemblies were successfully implemented and the first prototypes of C s aberration corrected EM were developed. 68,71−75 The invention of aberration correctors is considered a revolutionary step toward atomic-resolution imaging.…”
Section: Fundamental Principles Of Transmission Electron Microscopymentioning
confidence: 99%
“…The aberrations, mainly spherical aberration ( C s ), chromatic aberrations ( C c ), in rotationally symmetric lenses are unavoidable (Scherzer’s theorem). In 1947, Scherzer proposed three major schemes to compensate for the aberrations, serving as a roadmap toward developing aberration corrected S/TEMs. The three proposed pathways to circumvent the aberrations of static rotationally symmetric lenses include: (i) incorporating noncircular or multipole lenses that can cancel the positive C s aberration of the round lens by generating a negative C s value, (ii) deploying time-varying fields and (iii) inserting a charge on-axis. , In the 1990s, multipole correctors based on two designs of octupole/quadrupole and hexapole (sextupole) assemblies were successfully implemented and the first prototypes of C s aberration corrected EM were developed. , …”
Section: Fundamental Principles Of Transmission Electron Microscopymentioning
confidence: 99%
“…Scanning transmission electron microscopy (STEM) has emerged as one of the primary nanoscale materials characterization tools 1 . A STEM experiment focuses an electron beam on to a sample, with the probe dimensions ranging from tens of nanometers down to the atomic scale, which is made possible by hardware aberration correction 2,3 .…”
Section: Introductionmentioning
confidence: 99%