Thermodynamics
'''Thermodynamics''' (Greek: thermos = heat and dynamic = change) is the physics of energy, heat, work, entropy and the spontaneity of processes. Thermodynamics is closely related to statistical mechanics from which many thermodynamic relationships can be derived. While dealing with processes in which systems exchange matter or energy, classical thermodynamics is not concerned with the rate at which such processes take place, termed kinetics. For this reason, the use of the term "thermodynamics" usually refers to equilibrium thermodynamics. In this connection, a central concept in thermodynamics is that of quasistatic processes, which are idealized, "infinitely slow" processes. Time-dependent thermodynamic processes are studied by non-equilibrium thermodynamics. Because thermodynamics is not concerned with the concept of time, it has been suggested that a better name for equilibrium thermodynamics would have been thermostatics. Thermodynamic laws are of very general validity, and they do not depend on the details of the interactions or the systems being studied. This means they can be applied to systems about which one knows nothing other than the balance of energy and matter transfer between them and the environment. Examples of this include Einstein's prediction of spontaneous emission around the turn of the 20th century and the current research into the thermodynamics of black holes.
The basic concepts of Thermodynamics
The basic abstraction of thermodynamics is the division of the world into systems delimited by real or ideal boundaries. The systems not directly under consideration are lumped into the environment. It is possible to subdivide a system into subsystems, or to group several systems together into a larger system. Usually systems can be assigned a well-defined state which can be summarized by a small number of parameters.Thermodynamic Systems
A thermodynamic system is that part of the universe that is under consideration. A real or imaginary boundary separates the system from the rest of the universe, which is referred to as the environment. A useful classification of thermodynamic systems is based on the nature of the boundary and the flows of matter, energy and entropy through it. There are three kinds of systems depending on the kinds of exchanges taking place between a system and its environment:- isolated systems: not exchanging heat, matter or work with their environment. An example of an isolated system would be an insulated container, such as an insulated gas cylinder.
- closed systems: exchanging energy (heat and work) but not matter with their environment. A greenhouse is an example of a closed system exchanging heat but not work with its environment. Whether a system exchanges heat, work or both is usually thought of as a property of its boundary, which can be
- * adiabatic boundary: not allowing heat exchange;
- * rigid boundary: not allowing exchange of work.
- open systems: exchanging energy (heat and work) and matter with their environment. A boundary allowing matter exchange is called permeable. The ocean would be an example of an open system.
Thermodynamic state
When a system is at equilibrium under a given set of conditions, it is said to be in a definite state (or state of the system). For a given thermodynamic state, many of the system's properties are specified. Properties that doesn't depend on the path by which the system arrived at that state, are so-called functions of the state of the system. Note, that further in this section we consider only properties, which are functions of a state. The minimal number of properties that must be specified to describe the state of a given system is given by Gibbs phase rule. Usually we deal with bigger amount of system's properties, than this minimal number. Let's describe a state by specifying enough number of properties. Now that the state is determined, all the other properties are automatically determined. Note, that we have determined those other properties by specifying some chosen properties. So it is possible to develop relationships between various state properties. Equations of state are examples of such relationships.The Laws of Thermodynamics
Alternative statements that are mathematically equivalent can be given for each law.- Zeroth law: Thermodynamic equilibrium. When two systems are put in contact with each other, there will be a net exchange of energy and/or matter between them unless they are in thermodynamic equilibrium. Two systems are in thermodynamic equilibrium with each other if they stay the same after being put in contact. The zeroth law is stated as
- 1st Law: Conservation of energy. This is a fundamental principle of mechanics, and more generally of physics. In thermodynamics, it is used to give a precise definition of heat. It is stated as follows:
- 2nd Law: A far reaching and powerful law, it is typically stated in one of two ways:
- 3rd Law: This law explains why it is so hard to cool something to absolute zero:
More about the 2nd Law
The Second Law is exhibited (coarsely) by a box of electrical cables. Cables added from time to time tangle, inside the closed system (cables in a box) by adding and then removing cables. The best way to untangle is to start by taking the cables out of the box and placing them stretched out. The cables in a closed system (the box) will never untangle, but giving them some extra space starts the process of untangling (by going outside the closed system). C.P._Snow said the following in a Rede Lecture in 1959 entitled "The Two Cultures and the Scientific Revolution." "A good many times I have been present at gatherings of people who, by the standards of the traditional culture, are thought highly educated and who have with considerable gusto been expressing their incredulity at the illiteracy of scientists. Once or twice I have been provoked and have asked the company how many of them could describe the Second Law of Thermodynamics. The response was cold: it was also negative."The Laws of Thermodynamics and Mechanics
The First Law of thermodynamics is an exact consequence of the laws of mechanics - classical or quantum. The Fluctuation Theorem shows that the Second Law of Thermodynamics is also an exact consequence of the laws of mechanics except that it is only rigorous valid in the large system or long time limit.Basics
The following is a list of the major concepts in thermodynamics, together with the algebraic symbols used to represent them.| Internal energy | U |
| Temperature | T |
| Entropy | S |
| Pressure | P |
| Volume | V |
| Density | ρ |
| Helmholtz free energy | F, or A |
| Gibbs free energy | G |
| Enthalpy | H |
| Chemical potential | μ |
| Particle number | N |
| Phase (matter) | |
| Intensive variable | |
| Extensive variable | |
| State function |
Examples
Substances describable by temperature alone
Blackbody radiation is an example, since photon number is not conserved. Such a state is completely described by its temperature, although if phase transitions or spontaneous symmetry breaking occur other variables may be needed to discriminate among the phases. (This problem does not arise for blackbody radiation.) Given the internal energy as a function of temperature, we can define F = U - TS.Substances describable by temperature and pressure alone
Most "pure" nonmagnetic substances fall into this category. This state is completely described by its temperature and pressure, except at phase transitions and perhaps spontaneous symmetry breaking in the ordered phase. Given U and V (or the density ρ) as a function of T and P, we can define the Helmholtz energy as before and the Gibbs energy as G = U - TS + PV and the enthalpy as H = U + PV.Substances describable by temperature, pressure and chemical potential
If there are more than one kind of atom/molecule, a substance would fall into this category. This state is completely described by its temperature, pressure and chemical potentials, except at phase transitions and perhaps spontaneous symmetry breaking in the ordered phase.Substances describable by temperature and magnetic field
If a substance is a ferromagnet or a superconductor, for example, it would fall into this category. It is completely described by its temperature and magnetic field, except at phase transitions and perhaps spontaneous symmetry breaking in the ordered phase.See also
- Thermodynamic properties
- Thermodynamic equations
- important publications in thermodynamics
- Onsager reciprocal relations - sometimes called the Fourth Law of Thermodynamics
- Statistical Mechanics
- Legendre transformation
- Thermodynamics also touches upon the fields of:
- *Phase equilibrium
- *Fluid dynamics
- *Calorimetry
- *Thermal analysis
- *Thermochemistry also known as chemical thermodynamics
Quotes
"Thermodynamics is the only physical theory of universal content which, within the framework of the applicability of its basic concepts, I am convinced will never be overthrown." — Albert Einstein "In this house, we obey the laws of thermodynamics!" (after Lisa constructs a perpetual motion machine whose energy increases with time) — Homer Simpson "Any given thing gets less energy than it puts in, perpetual motion, therefore, is impossible."Units
Wikibooks
| General subfields within physics | |||||||
| Classical mechanics | Condensed matter physics > Continuum mechanics | Electromagnetism > General relativity | Particle physics > Quantum field theory | Quantum mechanics > Solid state physics | Special relativity > Statistical mechanics | Thermodynamics | |
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