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Entropy and the Second Law of Thermodynamics01:20

Entropy and the Second Law of Thermodynamics

3.3K
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...
3.3K
Entropy Change in Reversible Processes01:10

Entropy Change in Reversible Processes

2.8K
In the Carnot engine, which achieves the maximum efficiency between two reservoirs of fixed temperatures, the total change in entropy is zero. The observation can be generalized by considering any reversible cyclic process consisting of many Carnot cycles. Thus, it can be stated that the total entropy change of any ideal reversible cycle is zero.
The statement can be further generalized to prove that entropy is a state function. Take a cyclic process between any two points on a p-V diagram.
2.8K
Thermodynamic Systems01:06

Thermodynamic Systems

5.8K
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...
5.8K
Cyclic Processes And Isolated Systems01:19

Cyclic Processes And Isolated Systems

3.0K
A thermodynamic system with zero heat exchange and work is an isolated system. For these systems, the internal energy remains constant.
In the case of a non-isolated system, the change in the internal energy is zero only if the process is cyclic. A thermodynamic process is considered cyclic if the system undergoes a series of changes and returns to its initial state. 
Consider a cyclic process that returns to its initial state, undergoing a four-step process. The heat transfer along each...
3.0K
Maxwell-Boltzmann Distribution: Problem Solving01:20

Maxwell-Boltzmann Distribution: Problem Solving

1.8K
Individual molecules in a gas move in random directions, but a gas containing numerous molecules has a predictable distribution of molecular speeds, which is known as the Maxwell-Boltzmann distribution, f(v).
This distribution function f(v) is defined by saying that the expected number N (v1,v2) of particles with speeds between v1 and v2 is given by
1.8K
First Law: Particles in One-dimensional Equilibrium01:10

First Law: Particles in One-dimensional Equilibrium

7.2K
Newton's first law of motion states that a body at rest remains at rest, or if in motion, remains in motion at constant velocity, unless acted on by a net external force. It also states that there must be a cause for any change in velocity (a change in either magnitude or direction) to occur. This cause is a net external force. For example, consider what happens to an object sliding along a rough horizontal surface. The object quickly grinds to a halt, due to the net force of friction. If...
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Related Experiment Video

Updated: Oct 9, 2025

An Analog Macroscopic Technique for Studying Molecular Hydrodynamic Processes in Dense Gases and Liquids
11:03

An Analog Macroscopic Technique for Studying Molecular Hydrodynamic Processes in Dense Gases and Liquids

Published on: December 4, 2017

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Statistical Physics of Evolving Systems.

Arto Annila1

  • 1Department of Physics, University of Helsinki, 00014 Helsinki, Finland.

Entropy (Basel, Switzerland)
|December 24, 2021
PubMed
Summary
This summary is machine-generated.

Physics explains evolution as a universal process driven by the principle of least-time energy leveling. This fundamental law governs all systems, leading to predictable patterns and a teleological drive toward equilibrium.

Keywords:
dissipative systemsevolutionfree energynatural selectionpower lawsquantum of action

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Area of Science:

  • Physics
  • Statistical Mechanics
  • Thermodynamics
  • Evolutionary Theory

Background:

  • Evolution is traditionally viewed as a biological phenomenon.
  • A physics-based perspective suggests evolution is a universal principle applicable to all systems.
  • The concept of quanta of action underlies physical descriptions of evolving systems.

Purpose of the Study:

  • To formulate evolution as a process governed by physical laws.
  • To demonstrate how statistical physics explains universal evolutionary patterns.
  • To identify the least-time free energy consumption as the teleological driver of evolution.

Main Methods:

  • Application of statistical physics principles to systems of quanta.
  • Analysis of energy flux and its role in system evolution.
  • Mathematical formulation of the evolutionary equation and its non-deterministic nature.

Main Results:

  • Systems evolve towards thermodynamic balance with their surroundings.
  • The least-time principle for leveling energy differences generates universal patterns such as power laws and oscillations.
  • Evolutionary processes are inherently non-deterministic due to inseparable variables and energy consumption.

Conclusions:

  • Evolution, when viewed through the lens of physics, is a universal process.
  • The drive towards minimal free energy consumption over the least time dictates evolutionary trajectories.
  • System trajectories become computable only upon reaching a state of thermodynamic equilibrium.