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相关概念视频

Electron Orbital Model01:18

Electron Orbital Model

72.1K
Orbitals are the areas outside of the atomic nucleus where electrons are most likely to reside. They are characterized by different energy levels, shapes, and three-dimensional orientations. The location of electrons is described most generally by a shell or principal energy level, then by a subshell within each shell, and finally, by individual orbitals found within the subshells.
The first shell is closest to the nucleus, and it has only one subshell with a single spherical orbital called the...
72.1K
Ionic Bonding and Electron Transfer02:48

Ionic Bonding and Electron Transfer

49.0K
Ions are atoms or molecules bearing an electrical charge. A cation (a positive ion) forms when a neutral atom loses one or more electrons from its valence shell, and an anion (a negative ion) forms when a neutral atom gains one or more electrons in its valence shell. Compounds composed of ions are called ionic compounds (or salts), and their constituent ions are held together by ionic bonds: electrostatic forces of attraction between oppositely charged cations and anions. 
49.0K
Atomic Orbitals02:44

Atomic Orbitals

43.8K
An atomic orbital represents the three-dimensional regions in an atom where an electron has the highest probability to reside. The radial distribution function indicates the total probability of finding an electron within the thin shell at a distance r from the nucleus. The atomic orbitals have distinct shapes which are determined by l, the angular momentum quantum number. The orbitals are often drawn with a boundary surface, enclosing densest regions of the cloud.
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Molecular Orbital Theory II03:51

Molecular Orbital Theory II

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Molecular Orbital Energy Diagrams
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Molecular Orbital Theory I02:35

Molecular Orbital Theory I

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Overview of Molecular Orbital Theory
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The Energies of Atomic Orbitals03:21

The Energies of Atomic Orbitals

30.1K
In an atom, the negatively charged electrons are attracted to the positively charged nucleus. In a multielectron atom, electron-electron repulsions are also observed. The attractive and repulsive forces are dependent on the distance between the particles, as well as the sign and magnitude of the charges on the individual particles. When the charges on the particles are opposite, they attract each other. If both particles have the same charge, they repel each other.
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相关实验视频

Updated: Jan 29, 2026

All-electronic Nanosecond-resolved Scanning Tunneling Microscopy: Facilitating the Investigation of Single Dopant Charge Dynamics
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在绝缘体上使用道显微镜绘制电子转移的轨道变化

Laerte L Patera1, Fabian Queck2, Philipp Scheuerer2

  • 1Institute of Experimental and Applied Physics, University of Regensburg, Regensburg, Germany. laerte.patera@ur.de.

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|February 15, 2019
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概括

研究人员开发了一种新的原子力显微镜技术, 以可视化单个分子中的电子转移. 这种方法可以在非导电表面上绘制分子轨道结构和氧化还原状态,从而推进化学反应的研究.

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科学领域:

  • 表面科学
  • 分子光谱学
  • 纳米技术

背景情况:

  • 电子转移对于许多化学反应如光合作用和腐蚀至关重要.
  • 由于基质的局限性,在单分子水平上绘制氧化还原状态转换具有挑战性.
  • 像扫描道显微镜 (STM) 这样的现有技术需要导电基质,阻碍了氧化还原研究,而原子力显微镜 (AFM) 通常缺乏电子状态访问.

研究的目的:

  • 开发一种新的方法来绘制单分子轨道结构作为氧化还原状态的函数.
  • 在研究电子转移方面克服导电基质的局限性.
  • 在孤立的分子中可视化电子转换和极子形成.

主要方法:

  • 在AFM尖端和基板之间应用同步电压脉冲来引导电子道.
  • 尖端振荡与电压脉冲同步,使得在非导电基板上进行道实验.
  • 这种技术可以对分子轨道结构和电子状态进行分流分辨率映射.

主要成果:

  • 在非导电基板上成功进行了道实验,绘制了孤立分子的轨道结构.
  • 在太空和能源方面解决了以前无法获得的电子转换.
  • 视觉化了电子转移和极子形成对单个分子轨道的影响.

结论:

  • 开发的同步道AFM技术使单个分子的氧化还原状态解决电子结构映射成为可能.
  • 这种方法克服了基质的局限性,为研究电子转移动态开辟了新的途径.
  • 预计该方法对于研究复杂的氧化还原反应和高分辨率的充电现象具有价值.