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Crystal Field Theory - Octahedral Complexes02:58

Crystal Field Theory - Octahedral Complexes

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Crystal Field Theory
To explain the observed behavior of transition metal complexes (such as colors), a model involving electrostatic interactions between the electrons from the ligands and the electrons in the unhybridized d orbitals of the central metal atom has been developed. This electrostatic model is crystal field theory (CFT). It helps to understand, interpret, and predict the colors, magnetic behavior, and some structures of coordination compounds of transition metals.
CFT focuses on...
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Ions and Ionic Charges03:27

Ions and Ionic Charges

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In ordinary chemical reactions, the nucleus — which contains the protons and neutrons of each atom and thus identifies the element — remains unchanged. Electrons, however, can be added to atoms by transfer from other atoms, lost by transfer to other atoms, or shared with other atoms. The transfer and sharing of electrons among atoms govern the chemistry of the elements. During the formation of some compounds, atoms gain or lose electrons to form electrically charged particles called...
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Crystal Field Theory - Tetrahedral and Square Planar Complexes02:46

Crystal Field Theory - Tetrahedral and Square Planar Complexes

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Tetrahedral Complexes
Crystal field theory (CFT) is applicable to molecules in geometries other than octahedral. In octahedral complexes, the lobes of the dx2−y2 and dz2 orbitals point directly at the ligands. For tetrahedral complexes, the d orbitals remain in place, but with only four ligands located between the axes. None of the orbitals points directly at the tetrahedral ligands. However, the dx2−y2 and dz2 orbitals (along the Cartesian axes) overlap with the ligands less than the dxy,...
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Potential Due to a Polarized Object01:29

Potential Due to a Polarized Object

454
A neutral atom consists of a positively charged nucleus surrounded by a negatively charged electron cloud. When placed in an external electric field, the external electric force pulls the electrons and nucleus apart, opposite to the intrinsic attraction between the nucleus and the electrons. The opposing forces balance each other with a slight shift between the center of masses of the nucleus and the electron cloud, resulting in a polarized atom. On the other hand, a few molecules, like water,...
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Electron Affinity03:07

Electron Affinity

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The electron affinity (EA) is the energy change for adding an electron to a gaseous atom to form an anion (negative ion).
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Ionization Energy03:12

Ionization Energy

34.1K
The amount of energy required to remove the most loosely bound electron from a gaseous atom in its ground state is called its first ionization energy (IE1). The first ionization energy for an element, X, is the energy required to form a cation with 1+ charge:
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Related Experiment Video

Updated: Aug 16, 2025

Building Langmuir Probes and Emissive Probes for Plasma Potential Measurements in Low Pressure, Low Temperature Plasmas
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Building Langmuir Probes and Emissive Probes for Plasma Potential Measurements in Low Pressure, Low Temperature Plasmas

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Effect of Negative Ion Generation on Complex Plasma Structure Properties.

Andrey V Zobnin1, Andrey M Lipaev1, Alexander D Usachev1

  • 1Joint Institute for High Temperatures, Russian Academy of Sciences, 125412 Moscow, Russia.

Molecules (Basel, Switzerland)
|December 23, 2022
PubMed
Summary

A new dusty plasma model with oxygen shows high negative ion concentrations. These ions push charged dust from the plasma center, explaining experimental observations and offering a new theoretical perspective.

Keywords:
complex plasmagas dischargenegative ions

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Area of Science:

  • Plasma Physics
  • Complex Plasmas
  • Dusty Plasma Physics

Background:

  • Complex plasmas exhibit unique behaviors due to the presence of dust particles.
  • Oxygen admixture can significantly alter plasma properties.
  • Understanding negative ion kinetics is crucial in dusty plasma environments.

Purpose of the Study:

  • To develop a low-density discharge plasma model incorporating oxygen admixture.
  • To investigate the role of negative ions in complex (dusty) plasmas under these conditions.
  • To provide an alternative explanation for experimental observations in dusty plasmas.

Main Methods:

  • Development of a low-density discharge plasma model.
  • Numerical simulations to analyze plasma kinetics.
  • Inclusion of oxygen admixture effects.
  • Analysis of negative ion concentration and behavior.

Main Results:

  • Simulations reveal a very high concentration of negative ions.
  • Negative ions significantly influence the overall plasma kinetics.
  • The ambipolar diffusion electric field concentrates negative ions.
  • High negative ion density expels charged dust from the plasma center by altering electric fields and thermophoretic forces.

Conclusions:

  • The proposed plasma model qualitatively supports observed experimental phenomena.
  • The model provides a new mechanism for understanding dust particle behavior in oxygen-admixed dusty plasmas.
  • High negative ion concentrations are a key factor in dust particle dynamics within this plasma regime.