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Entropy01:18

Entropy

The first law of thermodynamics is quantitatively formulated via an equation relating the internal energy of a system, the heat exchanged by it, and the work done on it. A quantitative formulation of the second law of thermodynamics leads to defining a state function, the entropy.
When an ideal gas expands isothermally, the disorder in the gas increases. From the molecular perspective, the gas molecules have more volume to move around in.
Consider an infinitesimal step in the expansion, which...
Entropy02:39

Entropy

Salt particles that have dissolved in water never spontaneously come back together in solution to reform solid particles. Moreover, a gas that has expanded in a vacuum remains dispersed and never spontaneously reassembles. The unidirectional nature of these phenomena is the result of a thermodynamic state function called entropy (S). Entropy is the measure of the extent to which the energy is dispersed throughout a system, or in other words, it is proportional to the degree of disorder of a...
The Entropy as a State Function01:14

The Entropy as a State Function

Consider an arbitrary process that moves between two specific states (A and B) in a cyclic manner. This process is reversible and broken down into smaller parts that each follow a Carnot cycle. A Carnot cycle has two isothermal (constant temperature) processes. During these processes, the ratio of the amount of heat transferred to their respective temperature remains constant. The other two processes in the Carnot cycle are also reversible but adiabatic, which means they occur without any heat...
Entropy and the Second Law of Thermodynamics01:20

Entropy and the Second Law of Thermodynamics

The second law of thermodynamics can be stated quantitatively using the concept of entropy. Entropy is the measure of disorder of the system.
The relation  between entropy and disorder can be illustrated with the example of the phase change of ice to water. In ice, the molecules are located at specific sites giving a solid state, whereas, in a liquid form, these molecules are much freer to move. The molecular arrangement has therefore become more randomized. Although the change in average...
Entropy and the Second Law of Thermodynamics01:26

Entropy and the Second Law of Thermodynamics

Consider an isolated system in which a hot object is placed in contact with a cold one. This is an irreversible process that eventually leads both objects to reach the same equilibrium temperature. It is crucial to note that the constituents of any substance exhibit increased disorder at higher temperatures. As a cold substance absorbs heat, its constituents become more disordered. The energy transfer from a hotter object to a cooler one increases the system's disorder or randomness. This...
Second Law of Thermodynamics02:49

Second Law of Thermodynamics

In the quest to identify a property that may reliably predict the spontaneity of a process, a promising candidate has been identified: entropy. Processes that involve an increase in entropy of the system (ΔS > 0) are very often spontaneous; however, examples to the contrary are plentiful. By expanding consideration of entropy changes to include the surroundings, a significant conclusion regarding the relation between this property and spontaneity may be reached. In thermodynamic models, the...

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Related Experiment Video

Updated: Jun 22, 2026

Unraveling Entropic Rate Acceleration Induced by Solvent Dynamics in Membrane Enzymes
09:42

Unraveling Entropic Rate Acceleration Induced by Solvent Dynamics in Membrane Enzymes

Published on: January 16, 2016

Relations between entropies produced in nondeterministic thermodynamic processes.

S Turgut1

  • 1Department of Physics, Middle East Technical University, 06531 Ankara, Turkey.

Physical Review. E, Statistical, Nonlinear, and Soft Matter Physics
|June 13, 2009
PubMed
Summary

This study generalizes Landauer's erasure principle to nondeterministic processes with multiple logical states. It derives restrictions on heat exchange for these complex systems, showing the original principle is a special case.

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Last Updated: Jun 22, 2026

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Area of Science:

  • Thermodynamics
  • Information Theory
  • Statistical Mechanics

Background:

  • Landauer's erasure principle establishes a fundamental link between information and thermodynamics.
  • The principle, in its original form, applies to deterministic erasure of information in systems with two logical states.

Purpose of the Study:

  • To generalize Landauer's erasure principle to nondeterministic processes.
  • To extend the principle to systems with an arbitrary number of nonsymmetrical logical states.
  • To derive the complete set of restrictions on heat exchange for such generalized processes.

Main Methods:

  • Generalization of Landauer's principle to nondeterministic processes.
  • Statistical analysis of phase-space flow induced by information processing.
  • Derivation of heat exchange restrictions for systems with multiple, asymmetric logical states.

Main Results:

  • A generalized form of Landauer's erasure principle is established for nondeterministic processes.
  • Restrictions on individual heat exchanges are derived for systems with arbitrary, nonsymmetrical logical states.
  • The original Landauer's erasure principle is shown to be a special case of the derived restrictions.

Conclusions:

  • The generalized principle provides a broader understanding of the thermodynamic costs of information erasure.
  • The derived restrictions are crucial for analyzing heat dissipation in complex, probabilistic information processing systems.
  • This work extends the fundamental connection between information theory and thermodynamics to more complex computational models.