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Phase Transitions02:31

Phase Transitions

20.3K
Whether solid, liquid, or gas, a substance's state depends on the order and arrangement of its particles (atoms, molecules, or ions). Particles in the solid pack closely together, generally in a pattern. The particles vibrate about their fixed positions but do not move or squeeze past their neighbors. In liquids, although the particles are closely spaced, they are randomly arranged. The position of the particles are not fixed—that is, they are free to move past their neighbors to...
20.3K
Phase Transitions: Sublimation and Deposition02:33

Phase Transitions: Sublimation and Deposition

18.0K
Some solids can transition directly into the gaseous state, bypassing the liquid state, via a process known as sublimation. At room temperature and standard pressure, a piece of dry ice (solid CO2) sublimes, appearing to gradually disappear without ever forming any liquid. Snow and ice sublimate at temperatures below the melting point of water, a slow process that may be accelerated by winds and the reduced atmospheric pressures at high altitudes. When solid iodine is warmed, the solid sublimes...
18.0K
Phase Transitions: Melting and Freezing02:39

Phase Transitions: Melting and Freezing

13.2K
Heating a crystalline solid increases the average energy of its atoms, molecules, or ions, and the solid gets hotter. At some point, the added energy becomes large enough to partially overcome the forces holding the molecules or ions of the solid in their fixed positions, and the solid begins the process of transitioning to the liquid state or melting. At this point, the temperature of the solid stops rising, despite the continual input of heat, and it remains constant until all of the solid is...
13.2K
States of Matter and Phase Changes00:59

States of Matter and Phase Changes

1.2K
The internal energy of a substance—the total kinetic energy of all its molecules and the potential energy of their associated forces—depends on the strength of the intermolecular forces in the condensed phases and the pressure exerted on the substance. The internal energy of a substance is the highest in the gaseous state, the lowest in the solid state, and intermediate in the liquid state. Phase transitions are caused by changes in physical conditions, such as temperature and...
1.2K
Phase Diagram01:19

Phase Diagram

6.1K
The phase of a given substance depends on the pressure and temperature. Thus, plots of pressure versus temperature showing the phase in each region provide considerable insights into the thermal properties of substances. Such plots are known as phase diagrams. For instance, in the phase diagram for water (Figure 1), the solid curve boundaries between the phases indicate phase transitions (i.e., temperatures and pressures at which the phases coexist).
6.1K
Phase Changes01:19

Phase Changes

4.5K
Phase transitions play an important theoretical and practical role in the study of heat flow. In melting or fusion, a solid turns into a liquid; the opposite process is freezing. In evaporation, a liquid turns into a gas; the opposite process is condensation.
A substance melts or freezes at a temperature called its melting point and boils or condenses at its boiling point. These temperatures depend on pressure. High pressure favors the denser form of the substance, so typically, high pressure...
4.5K

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Related Experiment Video

Updated: Sep 14, 2025

Orientational Transition in a Liquid Crystal Triggered by the Thermodynamic Growth of Interfacial Wetting Sheets
06:26

Orientational Transition in a Liquid Crystal Triggered by the Thermodynamic Growth of Interfacial Wetting Sheets

Published on: May 15, 2017

7.2K

Kinetic pathways of solid-solid phase transitions dictated by short-range interactions.

Hillary Pan1, Julia Dshemuchadse1

  • 1Department of Materials Science and Engineering, Cornell University, Ithaca, NY 14853.

Proceedings of the National Academy of Sciences of the United States of America
|July 23, 2025
PubMed
Summary
This summary is machine-generated.

Predicting crystal structure transformations is difficult. This study reveals distinct kinetic pathways between body-centered cubic (bcc) and face-centered cubic (fcc) phases, controlled by particle interactions, offering new material design routes.

Keywords:
Martensitic transformationmolecular dynamics simulationspair potentialssolid–solid phase transitions

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Phase Diagram Characterization Using Magnetic Beads as Liquid Carriers
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Phase Diagram Characterization Using Magnetic Beads as Liquid Carriers

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

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Last Updated: Sep 14, 2025

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

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Area of Science:

  • Materials Science
  • Condensed Matter Physics
  • Computational Chemistry

Background:

  • Crystallographic phase transformations are crucial for designing novel materials.
  • Predicting solid-solid phase transition pathways remains a significant challenge due to experimental limitations.

Purpose of the Study:

  • To investigate and elucidate distinct kinetic pathways during structural phase transformations between body-centered cubic (bcc) and face-centered cubic (fcc) crystal structures.
  • To demonstrate how particle interactions dictate these transformation pathways in minimal computational models.

Main Methods:

  • Utilized minimal computational models to simulate and analyze particle dynamics during phase transitions.
  • Resolved phase transformation pathways at a particle-by-particle level.

Main Results:

  • Identified three distinct kinetic pathways: direct bcc-to-fcc, a pathway via an intermediate body-centered tetragonal (bct) phase, and a microstructure-dependent pathway involving hexagonal close-packed (hcp) phases.
  • Established a direct correlation between the shape of particle-particle interactions and the observed kinetic pathways.

Conclusions:

  • The shape of inter-particle interactions fundamentally controls solid-solid phase transformation pathways.
  • Findings offer insights for controlling soft matter system transformations and generalize to various length scales.