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Thermodynamic Systems01:06

Thermodynamic Systems

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A thermodynamic system is a set of objects whose thermodynamic properties are of interest. The system is considered to be embedded in its surroundings or the environment. The system and its environment can exchange heat and do work on each other through a boundary that separates them. However, the immediate surroundings of the system interact with it directly and therefore have a much stronger influence on its behavior and properties.
Consider an example of  tea boiling in a kettle. The...
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The Quantum-Mechanical Model of an Atom02:45

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Shortly after de Broglie published his ideas that the electron in a hydrogen atom could be better thought of as being a circular standing wave instead of a particle moving in quantized circular orbits, Erwin Schrödinger extended de Broglie’s work by deriving what is now known as the Schrödinger equation. When Schrödinger applied his equation to hydrogen-like atoms, he was able to reproduce Bohr’s expression for the energy and, thus, the Rydberg formula governing hydrogen spectra.
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Third Law of Thermodynamics02:38

Third Law of Thermodynamics

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A pure, perfectly crystalline solid possessing no kinetic energy (that is, at a temperature of absolute zero, 0 K) may be described by a single microstate, as its purity, perfect crystallinity,and complete lack of motion means there is but one possible location for each identical atom or molecule comprising the crystal (W = 1). According to the Boltzmann equation, the entropy of this system is zero.
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Quantum Numbers02:43

Quantum Numbers

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It is said that the energy of an electron in an atom is quantized; that is, it can be equal only to certain specific values and can jump from one energy level to another but not transition smoothly or stay between these levels.
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Second Law of Thermodynamics02:49

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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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Second Law of Thermodynamics00:53

Second Law of Thermodynamics

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The Second Law of Thermodynamics states that entropy, or the amount of disorder in a system, increases each time energy is transferred or transformed. Each energy transfer results in a certain amount of energy that is lost—usually in the form of heat—that increases the disorder of the surroundings. This can also be demonstrated in a classic food web. Herbivores harvest chemical energy from plants and release heat and carbon dioxide into the environment. Carnivores harvest the...
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Related Experiment Video

Updated: Jan 24, 2026

Determination of the Photoisomerization Quantum Yield of a Hydrazone Photoswitch
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Determination of the Photoisomerization Quantum Yield of a Hydrazone Photoswitch

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Quantum thermodynamics and open-systems modeling.

Ronnie Kosloff1

  • 1The Institute of Chemistry and The Fritz Haber Centre for Theoretical Chemistry, The Hebrew University of Jerusalem, Jerusalem 9190401, Israel.

The Journal of Chemical Physics
|June 3, 2019
PubMed
Summary
This summary is machine-generated.

This study presents a thermodynamic approach for modeling open quantum systems. It details methods for quantum master equations and their implications for simulating quantum transport and control.

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Area of Science:

  • Quantum Physics
  • Thermodynamics
  • Computational Modeling

Background:

  • Open quantum systems require thermodynamic consistency.
  • Existing models lack comprehensive thermodynamic integration.
  • Understanding system-bath interactions is crucial.

Purpose of the Study:

  • To develop a unified thermodynamic framework for open quantum systems.
  • To explore methods for deriving quantum master equations.
  • To analyze the implications of thermodynamics on quantum simulations.

Main Methods:

  • Employing open quantum systems theory for system-bath partitioning.
  • Utilizing the Markovian master equation for isothermal partitions.
  • Describing weak coupling limit and repeated collision models.
  • Introducing surrogate Hamiltonians and stochastic approaches.

Main Results:

  • Highlighting the role of eigenoperators in driven systems.
  • Describing models leading to dephasing and coherence loss.
  • Demonstrating thermodynamic implications for transport and spectroscopy.
  • Analyzing time-dependent driving and self-averaging in large systems.

Conclusions:

  • The presented approach provides a thermodynamically consistent model for open quantum systems.
  • Methods discussed are crucial for accurate quantum simulations, including ultrafast spectroscopy and quantum control.
  • The framework is essential for understanding self-averaging in large quantum systems.