Das Elektronenmikroskop

Knoll, M.; Руска, Э.

doi:10.1007/bf01342199

Cited by 391 publications

(124 citation statements)

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“…This was demonstrated by experiments in 1927 that electrons can be diffracted by a nickel crystal following the Bragg's law [43]. Using this wave property of electrons, people started to develop electron microscopes [45]. Apparently, the behavior of electron is very similar to photon.…”

Section: Both Radiation and Matter Wave Are Excitation Waves Of The Vmentioning

confidence: 99%

A New Interpretation on the Non-Newtonian Properties of Particle Mass

Chang¹

2018

JMP

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It is well known that the mass of a particle has properties different from Newtonian mechanics. First, it is speed-dependent. Second, it is convertible to energy. These properties were generally thought to be derived from the principle of relativity (PR). We have conducted a careful examination of the historical records and found that the non-Newtonian properties of mass were derived not so much based on PR, but more based on Einstein's intuitive thinking that radiation and matters behave similarly. This gives us a hint: Since both photon and electron can behave as a particle as well as a wave, can such a wave nature account for the deviations from Newtonian mechanics? Thus, we have developed a wave model to describe the motion of a free particle with or without rest mass. We found that both the speed-dependence of mass and the mass-energy equivalence can indeed be derived based on the wave properties of a particle. This wave hypothesis has several advantages; it can naturally explain why particles can be created in the vacuum and why a particle cannot travel faster than the speed of light.

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Section: Both Radiation and Matter Wave Are Excitation Waves Of The Vmentioning

confidence: 99%

A New Interpretation on the Non-Newtonian Properties of Particle Mass

Chang¹

2018

JMP

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“…1 The fi rst lattice fringes were observed in the 1950s by Menter using an electron microscope, building on the developments of Ruska, 2 von Ardenne, 3 , 4 and others, 5 with gradually improving resolution over the following decades. Direct observation of individual atoms in scanning transmission electron microscopy (STEM) was achieved by Crewe and co-workers in the 1960s, 6 made possible by his development of the cold-fi eldemission gun.…”

Section: Introductionmentioning

confidence: 99%

Single-atom fabrication with electron and ion beams: From surfaces and two-dimensional materials toward three-dimensional atom-by-atom assembly

Kalinin

Pennycook

2017

MRS Bull.

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“…8 The first electron microscope, using accelerated electrons, was invented by Knoll and Ruska in the 1930s. 9 The images thus obtained were "static," i.e., a) E-mail: zewail@caltech.edu. Fax: +1 (626) 792-8456.…”

Section: Introductionmentioning

confidence: 99%

Perspective: 4D ultrafast electron microscopy—Evolutions and revolutions

Shorokhov

Zewail

2016

The Journal of Chemical Physics

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In this Perspective, the evolutionary and revolutionary developments of ultrafast electron imaging are overviewed with focus on the “single-electron concept” for probing methodology. From the first electron microscope of Knoll and Ruska [Z. Phys. 78, 318 (1932)], constructed in the 1930s, to aberration-corrected instruments and on, to four-dimensional ultrafast electron microscopy (4D UEM), the developments over eight decades have transformed humans’ scope of visualization. The changes in the length and time scales involved are unimaginable, beginning with the micrometer and second domains, and now reaching the space and time dimensions of atoms in matter. With these advances, it has become possible to follow the elementary structural dynamics as it unfolds in real time and to provide the means for visualizing materials behavior and biological functions. The aim is to understand emergent phenomena in complex systems, and 4D UEM is now central for the visualization of elementary processes involved, as illustrated here with examples from past achievements and future outlook.

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Das Elektronenmikroskop

Cited by 391 publications

References 0 publications

A New Interpretation on the Non-Newtonian Properties of Particle Mass

A New Interpretation on the Non-Newtonian Properties of Particle Mass

Single-atom fabrication with electron and ion beams: From surfaces and two-dimensional materials toward three-dimensional atom-by-atom assembly

Perspective: 4D ultrafast electron microscopy—Evolutions and revolutions

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