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Transmission Electron Microscopy01:15

Transmission Electron Microscopy

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In 1931, physicist Ernst Ruska—building on the idea that magnetic fields can direct an electron beam just as lenses can direct a beam of light in an optical microscope—developed the first prototype of the electron microscope. This development led to the development of the field of electron microscopy. In the transmission electron microscope (TEM), electrons are produced by a hot tungsten element and accelerated by a potential difference in an electron gun, which gives them up to 400...
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X-ray Imaging01:24

X-ray Imaging

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German physicist Wilhelm Röntgen (1845–1923) was experimenting with electrical current when he discovered that a mysterious and invisible "ray" would pass through his flesh but leave an outline of his bones on a screen coated with a metal compound. In 1895, Röntgen made the first durable record of the internal parts of a living human: an "X-ray" image (as it came to be called) of his wife’s hand. Scientists worldwide quickly began their own experiments with...
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Overview of Electron Microscopy01:25

Overview of Electron Microscopy

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The wavelengths of visible light ultimately limit the maximum theoretical resolution of images created by light microscopes. Most light microscopes can only magnify 1000X, and a few can magnify up to 1500X. Electrons, like electromagnetic radiation, can behave like waves, but with wavelengths of 0.005 nm, they produce significantly greater resolution up to 0.05 nm as compared to 500 nm for visible light. An electron microscope (EM) can create a sharp image that is magnified up to 2,000,000X.
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Scanning Electron Microscopy01:07

Scanning Electron Microscopy

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A scanning electron microscope (SEM) is used to study the surface features of a sample by using an electron beam that scans the sample surface in a two-dimensional manner. Typically, areas between ~1 centimeter to 5 micrometers in width can be imaged. SEM can be used to image bacteria, viruses, tissues as well as larger samples like insects. Conventional SEM gives a magnification ranging from 20X to 30,000X and spatial resolution of 50 to 100 nanometers.
Fundamental Principles
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相关实验视频

Updated: Jun 7, 2025

Synchrotron X-ray Microdiffraction and Fluorescence Imaging of Mineral and Rock Samples
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Synchrotron X-ray Microdiffraction and Fluorescence Imaging of Mineral and Rock Samples

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一个通过快速微粒子流的紧的X射线源.

Rolf Behling1,2, Christopher Hulme3, Gavin Poludniowski4,5

  • 1Particle Physics, Astrophysics and Medical Imaging Department, KTH Royal Institute of Technology, Stockholm, Sweden. Rkobe@kth.se.

Communications engineering
|November 15, 2024
PubMed
概括
此摘要是机器生成的。

研究人员探索了一种新的X射线源概念,使用微粒代替传统的阳极. 这项创新旨在克服当前X射线管技术的局限性,以改善医学成像和癌症治疗.

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Dynamic Pore-scale Reservoir-condition Imaging of Reaction in Carbonates Using Synchrotron Fast Tomography
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High Spatial Resolution Chemical Imaging of Implant-Associated Infections with X-ray Excited Luminescence Chemical Imaging Through Tissue
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相关实验视频

Last Updated: Jun 7, 2025

Synchrotron X-ray Microdiffraction and Fluorescence Imaging of Mineral and Rock Samples
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Dynamic Pore-scale Reservoir-condition Imaging of Reaction in Carbonates Using Synchrotron Fast Tomography
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High Spatial Resolution Chemical Imaging of Implant-Associated Infections with X-ray Excited Luminescence Chemical Imaging Through Tissue
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科学领域:

  • 医疗成像医学成像
  • 材料科学 材料科学 材料科学
  • 物理 物理学 物理

背景情况:

  • 传统的X射线管面临着由于高功率输入的阳极侵蚀导致的时空分辨率的限制.
  • 探测器技术的进步需要改进的X射线源,以更小的焦点进行增强的医学成像.
  • 目前的高输出X射线管技术,依赖于旋转阳极,已经达到了发展瓶.

研究的目的:

  • 研究一种替代的X射线目标概念,以克服当前X射线管技术的局限性.
  • 探索微粒子流与电子束相交的潜力,作为一种新的X射线源.
  • 为满足医疗成像和癌症治疗中改善X射线输出的需求.

主要方法:

  • 为了探索一种新的目标概念,使用一系列快速离散的金属微粒进行了模拟.
  • 模拟涵盖了与切割电子束的微粒子流相关的关键不确定性.
  • 概述了未来X射线源开发的技术实施方案.

主要成果:

  • 这项研究探索了使用离散金属微粒进行X射线生成的新范式.
  • 模拟表明了微粒子流概念对于X射线生成的可行性.
  • 提出的概念为传统旋转阳极的局限性提供了潜在的解决方案.

结论:

  • 微粒子流目标概念代表了X射线源开发中的潜在范式转变.
  • 这种新的方法预计将对诊断成像,放射性癌症治疗和非破坏性测试产生重大影响.
  • 基于这一概念的进一步技术开发可能会导致下一代X射线源.