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Imperfections in Crystal Structure: Point, Line and Plane Defects01:25

Imperfections in Crystal Structure: Point, Line and Plane Defects

34
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...
34
Imperfections in Crystal Structure: Stoichiometric Point Defects01:26

Imperfections in Crystal Structure: Stoichiometric Point Defects

44
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...
44
Imperfections in Crystal Structure: Non-Stoichiometric Defects01:29

Imperfections in Crystal Structure: Non-Stoichiometric Defects

30
Non-stoichiometric defects refer to a type of defect in the crystal structure of a compound where the ratio of its constituent elements deviates from the ideal stoichiometric ratio. There are two main types of non-stoichiometric defects: metal excess defects and metal deficiency defects.Metal excess defects occur when there is a slight surplus of metal ions than what is required by the stoichiometric ratio of the compound. For example, heating a sodium chloride crystal in sodium vapor results...
30
Precipitate Formation and Particle Size Control01:16

Precipitate Formation and Particle Size Control

7.0K
In precipitation gravimetry, the precipitating agent should react specifically or selectively with the analyte. While a specific reagent reacts with the analyte alone, a selective reagent can react with a limited number of chemical species.
The obtained precipitate should be either a pure substance of known composition or easily converted to one by a simple process, such as ignition or drying. In addition, the precipitate should be insoluble and easily filterable. In general, filterability...
7.0K
The Colloidal State01:29

The Colloidal State

74
The formation of a colloidal system is exemplified by an aqueous solution containing Cl− ions is introduced to another containing Ag+ ions, resulting in the precipitation of solid AgCl as extremely tiny crystals. Instead of settling out as a filterable precipitate, these crystals remain suspended in the liquid, showcasing a colloidal system.A colloidal system involves colloidal particles within the approximate range of 1 to 1000 nm in at least one dimension, dispersed in a medium called...
74
Crystal Growth: Principles of Crystallization01:25

Crystal Growth: Principles of Crystallization

5.6K
Crystallization is a phase transformation process in which crystals are precipitated from a supersaturated solution or formed from other sources. During crystallization, atoms or molecules arrange themselves into a well-defined, rigid crystal lattice to minimize energy.
Initiating crystallization involves manipulating the concentration of the solute and the temperature of the solution. Since crystal growth occurs when the ratio of concentration and solubility of the solute in the solvent...
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Related Experiment Video

Updated: Mar 14, 2026

Confocal Imaging of Confined Quiescent and Flowing Colloid-polymer Mixtures
10:56

Confocal Imaging of Confined Quiescent and Flowing Colloid-polymer Mixtures

Published on: May 20, 2014

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Using particle shape to control defects in colloidal crystals on spherical interfaces.

Gabrielle N Jones1, Philipp W A Schönhöfer1, Sharon C Glotzer1,2

  • 1Department of Chemical Engineering, University of Michigan, Ann Arbor, MI, USA. sglotzer@umich.edu.

Soft Matter
|March 13, 2026
PubMed
Summary
This summary is machine-generated.

Colloidal particles on a sphere surface form ordered structures with defects. Particle shape controls defect type and distribution, enabling programmable defect generation for applications like vesicle buckling.

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Area of Science:

  • Colloid and Surface Science
  • Computational Physics
  • Materials Science

Background:

  • Dense packing of spherical particles on a sphere surface is limited by lattice and topological constraints, leading to defects.
  • Understanding defect structures is crucial for controlling colloidal assembly properties.

Purpose of the Study:

  • Investigate the impact of particle shape anisotropy and lattice preference on defect structures in colloidal assemblies confined to a sphere.
  • Determine how defect distribution changes with continuous variation of particle shape.

Main Methods:

  • Utilized hard particle Monte Carlo simulations.
  • Simulated colloidal assemblies of hard rounded polyhedra confined to a closed sphere surface.
  • Analyzed defect structures and their distribution.

Main Results:

  • Cube particles form a square assembly, overcoming incompatibility and distributing three-fold defects evenly.
  • Varying particle shape from cubes to spheres alters defect distribution symmetry from square antiprismatic to icosahedral.
  • Rounded tetrahedra exhibit diverse defect patterns in three, four, and six-fold symmetric lattices.

Conclusions:

  • Particle shape anisotropy and lattice preference significantly influence defect formation and distribution in confined colloidal systems.
  • Programmable defect generation is achievable by controlling particle shape.
  • Findings have implications for vesicle buckling modes using colloidal particle emulsions.