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Crystal Field Theory - Octahedral Complexes02:58

Crystal Field Theory - Octahedral Complexes

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...
Crystal Field Theory - Tetrahedral and Square Planar Complexes02:46

Crystal Field Theory - Tetrahedral and Square Planar Complexes

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,...
Imperfections in Crystal Structure: Stoichiometric Point Defects01:26

Imperfections in Crystal Structure: Stoichiometric Point Defects

Schottky defects arise when some lattice points in a crystal, such as those in NaCl, remain unoccupied, creating lattice vacancies without disturbing the overall electrical neutrality of the crystal. This defect is common in ionic crystals where the positive and negative ions are similar in size, as seen in sodium chloride and cesium chloride. The presence of Schottky defects enables the crystal to conduct electricity to a small extent through an ionic mechanism. Electric fields cause nearby...
Imperfections in Crystal Structure: Point, Line and Plane Defects01:25

Imperfections in Crystal Structure: Point, Line and Plane Defects

A perfect crystal, in theory, has a uniform structure with the same unit cell and lattice points throughout. However, any deviation from this periodic arrangement is known as an imperfection or defect. These defects can be categorized into three types: point, line, and plane defects.Point defects occur when there is a deviation from the ideal due to missing atoms, displaced atoms, or additional atoms. These imperfections might occur due to imperfect packing during crystallization or because of...
Spin–Spin Coupling: Three-Bond Coupling (Vicinal Coupling)01:22

Spin–Spin Coupling: Three-Bond Coupling (Vicinal Coupling)

Vicinal or three-bond coupling is commonly observed between protons attached to adjacent carbons. Here, nuclear spin information is primarily transferred via electron spin interactions between adjacent C‑H bond orbitals. This generally favors the antiparallel arrangement of spins, so 3J values are usually positive.
The extent of coupling depends on the C‑C bond length, the two H‑C‑C angles, any electron-withdrawing substituents, and the dihedral angle between the involved orbitals. The...
Spin–Spin Coupling: One-Bond Coupling01:17

Spin–Spin Coupling: One-Bond Coupling

Coupling interactions are strongest between NMR-active nuclei bonded to each other, where spin information can be transmitted directly through the pair of bonding electrons. While nuclei polarize their electrons to the opposite spins, the bonding electron pair has opposite spins. Configurations with antiparallel nuclear spins are expected to be lower in energy. When coupling makes antiparallel states more favorable, J is considered to have a positive value. The one-bond coupling constant, 1J,...

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Related Experiment Video

Updated: May 14, 2026

Methods of Ex Situ and In Situ Investigations of Structural Transformations: The Case of Crystallization of Metallic Glasses
08:55

Methods of Ex Situ and In Situ Investigations of Structural Transformations: The Case of Crystallization of Metallic Glasses

Published on: June 7, 2018

Scale-coupling and interface-pinning effects in the phase-field-crystal model.

Zhi-Feng Huang1

  • 1Department of Physics and Astronomy, Wayne State University, Detroit, Michigan 48201, USA.

Physical Review. E, Statistical, Nonlinear, and Soft Matter Physics
|February 16, 2013
PubMed
Summary

Scale coupling in the phase-field-crystal (PFC) model reveals nonadiabatic effects on crystal growth. These findings introduce a generalized Gibbs-Thomson relation and explain lattice pinning phenomena.

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Area of Science:

  • Materials Science
  • Condensed Matter Physics
  • Computational Physics

Background:

  • The phase-field-crystal (PFC) model describes materials at atomic length scales.
  • Understanding liquid-solid interfaces is crucial for materials processing and crystal growth.

Purpose of the Study:

  • To investigate the effects of scale coupling between mesoscopic and microscopic structures in the PFC model.
  • To derive effective sharp-interface equations incorporating crystalline lattice effects.
  • To analyze crystal growth dynamics, including pinning and depinning phenomena.

Main Methods:

  • Utilizing the phase-field-crystal (PFC) model to study scale coupling.
  • Deriving nonadiabatic amplitude equations and coarse-graining for effective sharp-interface equations.
  • Identifying a generalized Gibbs-Thomson relation and a driven sine-Gordon equation with KPZ nonlinearity.
  • Applying the model to crystal layer growth and presenting analytic solutions.

Main Results:

  • Scale coupling introduces nonadiabatic corrections to PFC amplitude equations, intensifying with lower temperatures.
  • A generalized Gibbs-Thomson relation accounting for lattice coupling and pinning is identified.
  • Universal scaling behaviors for pinning strength, surface tension, and kinetic coefficients are determined.
  • Analytic solutions demonstrate lattice pinning/depinning and continuous vs. nucleated growth modes.

Conclusions:

  • The study provides a unified framework for liquid-solid interface dynamics across various scales.
  • The derived equations and identified scaling laws offer insights into crystal growth mechanisms.
  • This work bridges the gap between microscopic lattice structure and macroscopic interface evolution.