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Adiabatic Processes for an Ideal Gas01:18

Adiabatic Processes for an Ideal Gas

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When an ideal gas is compressed adiabatically, that is, without adding heat, work is done on it, and its temperature increases. In an adiabatic expansion, the gas does work, and its temperature drops. Adiabatic compressions actually occur in the cylinders of a car, where the compressions of the gas-air mixture take place so quickly that there is no time for the mixture to exchange heat with its environment. Nevertheless, because work is done on the mixture during the compression, its...
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The Carnot Cycle01:30

The Carnot Cycle

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Converting work to heat is an irreversible process, and the purpose of a heat engine is to reverse the effect partially. Heat engines aim to increase the efficiency of the reversal, that is, maximize the work retrieved from heat. If the efficiency of a heat engine were 100%, it would imply reversing the process completely without introducing any other effect. Thus, it would violate the second law of thermodynamics.
What could be the theoretical limit to the efficiency of a heat engine? The...
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Efficiency of The Carnot Cycle01:16

Efficiency of The Carnot Cycle

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The hypothetical Carnot cycle consists of an ideal gas subjected to two isothermal and two adiabatic processes. Since the internal energy of an ideal gas depends only on its temperature, which is the same before and after the completion of the Carnot cycle, there is no change in its internal energy. Hence, using the first law of thermodynamics, the total heat exchanged by the ideal gas equals the total work done. Thus, we can quantify the efficiency of the Carnot cycle via the heat exchanged...
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First Law Of Thermodynamics: Problem-Solving01:21

First Law Of Thermodynamics: Problem-Solving

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The first law of thermodynamics states that the change in internal energy of the system is equal to the net heat transfer into the system minus the net work done by the system. This equation is a generalized form of energy conservation and can be applied to any thermodynamic process.
The following strategies can be used to solve any problem involving the first law of thermodynamics.
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Pressure and Volume in an Adiabatic Process01:27

Pressure and Volume in an Adiabatic Process

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Free expansion of a gas is an adiabatic process. However, there are few differences between free expansion and adiabatic expansion. During free expansion, no work is done, and there is no change in internal energy. But, for an adiabatic expansion, work is done, and there is a change in internal energy. During an adiabatic process, the relation between the pressure and volume is obtained from the condition for the adiabatic process, that is, 
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The Carnot Cycle and the Second Law of Thermodynamics01:20

The Carnot Cycle and the Second Law of Thermodynamics

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The Carnot engine works between two heat reservoirs of fixed temperatures. The Carnot cycle begs the following question: Is it possible to devise a heat engine that is more efficient than a Carnot engine between two fixed temperatures? The answer lies in designing a Carnot refrigerator.
Since the individual steps in a Carnot cycle can be reversed, the entire cycle is, thus, reversible. If a Carnot cycle is reversed, it becomes a Carnot refrigerator. It extracts heat Qc from a cold reservoir at...
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Related Experiment Video

Updated: Jul 16, 2025

Asymmetric Thermoelectrochemical Cell for Harvesting Low-grade Heat under Isothermal Operation
09:09

Asymmetric Thermoelectrochemical Cell for Harvesting Low-grade Heat under Isothermal Operation

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Adiabatic computing for optimal thermodynamic efficiency of information processing.

Salambô Dago1, Sergio Ciliberto1, Ludovic Bellon1

  • 1Univ Lyon, ENS de Lyon, CNRS, Laboratoire de Physique, F-69342 Lyon, France.

Proceedings of the National Academy of Sciences of the United States of America
|September 20, 2023
PubMed
Summary
This summary is machine-generated.

Erasing digital information requires energy. Underdamped systems minimize this energy cost during fast erasure, achieving adiabatic processes and reaching Landauer

Keywords:
Landauer’s boundadiabatic limitinformation theorystochastic thermodynamicsthermal noise

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Area of Science:

  • Thermodynamics
  • Information Theory
  • Statistical Mechanics

Background:

  • Landauer's principle establishes a fundamental link between information and thermodynamics.
  • Erasing one bit of information at temperature T necessitates energy exceeding kT.
  • Previous experiments achieved this limit using slow, quasistatic processes.

Purpose of the Study:

  • To investigate energy-efficient methods for fast information erasure.
  • To explore the role of underdamped systems in reducing erasure energy overhead.
  • To theoretically and experimentally validate adiabatic processes for fast erasure protocols.

Main Methods:

  • Utilizing underdamped systems to minimize energy dissipation during fast erasure.
  • Developing and applying a fast, optimal erasure protocol.
  • Conducting theoretical analysis and experimental validation of system dynamics.

Main Results:

  • Underdamped systems significantly reduce the energy overhead associated with fast information erasure.
  • Fast erasure protocols in the limit of vanishing dissipation are shown to be adiabatic, with no heat exchange.
  • A maximum adiabatic temperature of kT is achieved during optimal fast erasure, with the erasure bound becoming the adiabatic bound.

Conclusions:

  • Underdamped systems offer a viable strategy for energy-efficient fast information erasure.
  • Adiabaticity is key to achieving Landauer's limit during high-speed erasure.
  • This research bridges the gap between theoretical limits and practical implementations in thermodynamic computing.