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Phase Transitions: Sublimation and Deposition02:33

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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...
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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...
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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...
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A phase transition is the process in which a substance changes from one state of matter to another, like from a solid to a liquid, liquid to gas, or vice versa, at a specific temperature and under given pressure conditions. This change is spontaneous and is affected by alterations in temperature and pressure. These parameters impact the strength of the forces between molecules (intermolecular forces) in the substance.During a phase transition, both the initial and final phases of the substance...
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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.
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The physical form of a substance changes on changing its temperature. For example, raising the temperature of a liquid causes the liquid to vaporize (convert into vapor). The process is called vaporization—a surface phenomenon. Vaporization occurs when the thermal motion of the molecules overcome the intermolecular forces, and the molecules (at the surface) escape into the gaseous state. When a liquid vaporizes in a closed container, gas molecules cannot escape. As these gas phase...
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Related Experiment Video

Updated: Apr 25, 2026

Optimizing Magnetic Force Microscopy Resolution and Sensitivity to Visualize Nanoscale Magnetic Domains
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Thermal phase transitions in artificial spin ice.

Demian Levis1, Leticia F Cugliandolo1, Laura Foini1

  • 1Université Pierre et Marie Curie-Paris 6, Laboratoire de Physique Théorique et Hautes Energies, 4, Place Jussieu, Tour 13, 5ème étage, 75252 Paris Cedex 05, France.

Physical Review Letters
|August 29, 2014
PubMed
Summary

We used a sixteen-vertex model to analyze artificial spin ice, finding excellent agreement between experimental data and model predictions. This confirms the samples are in thermal equilibrium, away from a critical point.

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Area of Science:

  • Condensed Matter Physics
  • Materials Science
  • Statistical Mechanics

Background:

  • Artificial spin ice systems offer a platform for studying magnetic phenomena.
  • Understanding the thermodynamic behavior of these systems is crucial for their application.

Purpose of the Study:

  • To describe bidimensional artificial spin ice using the sixteen-vertex model.
  • To investigate the thermal equilibrium and phase transitions in these systems.

Main Methods:

  • Utilizing the sixteen-vertex model for theoretical description.
  • Comparing model predictions with experimental vertex densities from 15 distinct samples.

Main Results:

  • Achieved excellent agreement between experimental vertex densities and model predictions.
  • Demonstrated that the artificial spin ice samples are in thermal equilibrium.
  • Identified a critical point separating disordered and antiferromagnetic phases.

Conclusions:

  • The sixteen-vertex model accurately describes artificial spin ice.
  • A second-order phase transition is predicted, warranting further study of near-critical systems.
  • Investigating long-range correlations in near-critical artificial spin ice is recommended.