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thermodynamic system
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{{short description|Body of matter in a state of internal equilibrium}}{{Use dmy dates|date=January 2020}}(File:Diagram Systems.svg|thumb|Properties of isolated, closed, and open thermodynamic systems in exchanging energy and matter)A thermodynamic system is a body of matter and/or radiation separate from its surroundings that can be studied using the laws of thermodynamics. Thermodynamic systems can be passive and active according to internal processes. According to internal processes, passive systems and active systems are distinguished: passive, in which there is a redistribution of available energy, active, in which one type of energy is converted into another.Depending on its interaction with the environment, a thermodynamic system may be an isolated system, a closed system, or an open system. An isolated system does not exchange matter or energy with its surroundings. A closed system may exchange heat, experience forces, and exert forces, but does not exchange matter. An open system can interact with its surroundings by exchanging both matter and energy.The physical condition of a thermodynamic system at a given time is described by its state, which can be specified by the values of a set of thermodynamic state variables. A thermodynamic system is in thermodynamic equilibrium when there are no macroscopically apparent flows of matter or energy within it or between it and other systems.{{sfn|Rex|Finn|2017|p=1–4}}(File:system boundary2.svg|200px|thumb)- the content below is remote from Wikipedia
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Overview
{{Thermodynamics|cTopic=Systems}}Thermodynamic equilibrium is characterized by absence of flow of mass or energy. Equilibrium thermodynamics, as a subject in physics, considers macroscopic bodies of matter and energy in states of internal thermodynamic equilibrium. It uses the concept of thermodynamic processes, by which bodies pass from one equilibrium state to another by transfer of matter and energy between them. The term ‘thermodynamic system’ is used to refer to bodies of matter and energy in the special context of thermodynamics. The possible equilibria between bodies are determined by the physical properties of the walls that separate the bodies. Equilibrium thermodynamics in general does not measure time. Equilibrium thermodynamics is a relatively simple and well settled subject. One reason for this is the existence of a well defined physical quantity called ‘the entropy of a body’.Non-equilibrium thermodynamics, as a subject in physics, considers bodies of matter and energy that are not in states of internal thermodynamic equilibrium, but are usually participating in processes of transfer that are slow enough to allow description in terms of quantities that are closely related to thermodynamic state variables. It is characterized by presence of flows of matter and energy. For this topic, very often the bodies considered have smooth spatial inhomogeneities, so that spatial gradients, for example a temperature gradient, are well enough defined. Thus the description of non-equilibrium thermodynamic systems is a field theory, more complicated than the theory of equilibrium thermodynamics. Non-equilibrium thermodynamics is a growing subject, not an established edifice. In general, it is not possible to find an exactly defined entropy for non-equilibrium problems. For many non-equilibrium thermodynamical problems, an approximately defined quantity called ‘time rate of entropy production’ is very useful. Non-equilibrium thermodynamics is mostly beyond the scope of the present article.Another kind of thermodynamic system is considered in most engineering. It takes part in a flow process. The account is in terms that approximate, well enough in practice in many cases, equilibrium thermodynamical concepts. This is mostly beyond the scope of the present article, and is set out in other articles, for example the article Flow process.History
The classification of thermodynamic systems arose with the development of thermodynamics as a science.Theoretical studies of thermodynamic processes in the period from the first theory of heat engines (Saadi Carnot, France, 1824) to the theory of dissipative structures (Ilya Prigozhin, Belgium, 1971) mainly concerned the patterns of interaction of thermodynamic systems with the environment.At the same time, thermodynamic systems were mainly classified as isolated, closed and open, with corresponding properties in various thermodynamic states, for example, in states close to equilibrium, nonequilibrium and strongly nonequilibrium.In 2010, Boris Dobroborsky (Israel, Russia) proposed a classification of thermodynamic systems according to internal processes consisting in energy redistribution (passive systems) and energy conversion (active systems).Passive systems
If there is a temperature difference inside the thermodynamic system, for example in a rod, one end of which is warmer than the other, then thermal energy transfer processes occur in it, in which the temperature of the colder part rises and the warmer part decreases. As a result, after some time, the temperature in the rod will equalize â the rod will come to a state of thermodynamic equilibrium.Active systems
If the process of converting one type of energy into another takes place inside a thermodynamic system, for example, in chemical reactions, in electric or pneumatic motors, when one solid body rubs against another, then the processes of energy release or absorption will occur, and the thermodynamic system will always tend to a non-equilibrium state with respect to the environment.Systems in equilibrium
In isolated systems it is consistently observed that as time goes on internal rearrangements diminish and stable conditions are approached. Pressures and temperatures tend to equalize, and matter arranges itself into one or a few relatively homogeneous phases. A system in which all processes of change have gone practically to completion is considered in a state of thermodynamic equilibrium.{{sfn|Rex|Finn|2017|p=1–2}} The thermodynamic properties of a system in equilibrium are unchanging in time. Equilibrium system states are much easier to describe in a deterministic manner than non-equilibrium states. In some cases, when analyzing a thermodynamic process, one can assume that each intermediate state in the process is at equilibrium. Such a process is called quasistatic.{{sfn|Rex|Finn|2017|p=20}}For a process to be reversible, each step in the process must be reversible. For a step in a process to be reversible, the system must be in equilibrium throughout the step. That ideal cannot be accomplished in practice because no step can be taken without perturbing the system from equilibrium, but the ideal can be approached by making changes slowly.The very existence of thermodynamic equilibrium, defining states of thermodynamic systems, is the essential, characteristic, and most fundamental postulate of thermodynamics, though it is only rarely cited as a numbered law.{{sfn|Bailyn|1994|p=20}}{{sfn|Tisza|1966|p=119}}Marsland, R. {{math|III}}, Brown, H.R., Valente, G. (2015). Time and irreversibility in axiomatic thermodynamics, Am. J. Phys., 83(7): 628â634. According to Bailyn, the commonly rehearsed statement of the zeroth law of thermodynamics is a consequence of this fundamental postulate.{{sfn|Bailyn|1994|p=22}} In reality, practically nothing in nature is in strict thermodynamic equilibrium, but the postulate of thermodynamic equilibrium often provides very useful idealizations or approximations, both theoretically and experimentally; experiments can provide scenarios of practical thermodynamic equilibrium.In equilibrium thermodynamics the state variables do not include fluxes because in a state of thermodynamic equilibrium all fluxes have zero values by definition. Equilibrium thermodynamic processes may involve fluxes but these must have ceased by the time a thermodynamic process or operation is complete bringing a system to its eventual thermodynamic state. Non-equilibrium thermodynamics allows its state variables to include non-zero fluxes, which describe transfers of mass or energy or entropy between a system and its surroundings.Eu, B.C. (2002). Generalized Thermodynamics. The Thermodynamics of Irreversible Processes and Generalized Hydrodynamics, Kluwer Academic Publishers, Dordrecht, {{ISBN|1-4020-0788-4}}.Walls{|class“wikitable” align“right“|+Types of transfers permitted|+by types of wall
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Surroundings
{{See also|Environment (systems)}}The system is the part of the universe being studied, while the surroundings is the remainder of the universe that lies outside the boundaries of the system. It is also known as the environment or the reservoir. Depending on the type of system, it may interact with the system by exchanging mass, energy (including heat and work), momentum, electric charge, or other conserved properties. The environment is ignored in the analysis of the system, except in regards to these interactions.Closed system
In a closed system, no mass may be transferred in or out of the system boundaries. The system always contains the same amount of matter, but (sensible) heat and (boundary) work can be exchanged across the boundary of the system. Whether a system can exchange heat, work, or both is dependent on the property of its boundary.- Adiabatic boundary â not allowing any heat exchange: A thermally isolated system
- Rigid boundary â not allowing exchange of work: A mechanically isolated system
Delta U=Q-W
where Udenotes the internal energy of the system, Q heat added to the system, W the work done by the system. For infinitesimal changes the first law for closed systems may stated:
mathrm d U= delta Q -delta W.
If the work is due to a volume expansion by mathrm d V at a pressure P then:
delta W = Pmathrm d V.
For a quasi-reversible heat transfer, the second law of thermodynamics reads:
delta Q = T mathrm d S
where T denotes the thermodynamic temperature and S the entropy of the system. With these relations the fundamental thermodynamic relation, used to compute changes in internal energy, is expressed as:
mathrm d U=Tmathrm d S-Pmathrm d V.
For a simple system, with only one type of particle (atom or molecule), a closed system amounts to a constant number of particles. For systems undergoing a chemical reaction, there may be all sorts of molecules being generated and destroyed by the reaction process. In this case, the fact that the system is closed is expressed by stating that the total number of each elemental atom is conserved, no matter what kind of molecule it may be a part of. Mathematically:
sum_{j=1}^m a_{ij}N_j=b_i^0
where N_j denotes the number of j-type molecules, a_{ij} the number of atoms of element i in molecule j, and b_i^0 the total number of atoms of element i in the system, which remains constant, since the system is closed. There is one such equation for each element in the system.Isolated system
An isolated system is more restrictive than a closed system as it does not interact with its surroundings in any way. Mass and energy remains constant within the system, and no energy or mass transfer takes place across the boundary. As time passes in an isolated system, internal differences in the system tend to even out and pressures and temperatures tend to equalize, as do density differences. A system in which all equalizing processes have gone practically to completion is in a state of thermodynamic equilibrium.Truly isolated physical systems do not exist in reality (except perhaps for the universe as a whole), because, for example, there is always gravity between a system with mass and masses elsewhere.BOOK, Thermodynamics of Spontaneous and Non-Spontaneous Processes, I.M.Kolesnikov, V.A.Vinokurov, S.I.Kolesnikov, 136,books.google.com/books?id=2RzE2pCfijYC&pg=PA136, 978-1-56072-904-4, 2001, Nova science Publishers, WEB, A System and Its Surroundings, ChemWiki, University of California - Davis,chemwiki.ucdavis.edu/Physical_Chemistry/Thermodynamics/A_System_And_Its_Surroundings#Isolated_System, 9 May 2012, WEB, Hyperphysics, The Department of Physics and Astronomy of Georgia State University,hyperphysics.phy-astr.gsu.edu/hbase/conser.html#isosys, 9 May 2012, WEB, Open, Closed and Isolated Systems in Physical Chemistry, Foundations of Quantum Mechanics and Physical Chemistry, Bryan Sanctuary, McGill University (Montreal),quantummechanics.mchmultimedia.com/2011/physical-chemistry/open-closed-and-isolated-systems-in-chemistry/, 9 May 2012, 30 May 2012,quantummechanics.mchmultimedia.com/2011/physical-chemistry/open-closed-and-isolated-systems-in-chemistry/," title="web.archive.org/web/20120530190200quantummechanics.mchmultimedia.com/2011/physical-chemistry/open-closed-and-isolated-systems-in-chemistry/,">web.archive.org/web/20120530190200quantummechanics.mchmultimedia.com/2011/physical-chemistry/open-closed-and-isolated-systems-in-chemistry/, dead, BOOK, Material and Energy Balances for Engineers and Environmentalists, 7, Imperial College Press,www.icpress.co.uk/etextbook/p631/p631_chap01.pdf, 9 May 2012, dead,www.icpress.co.uk/etextbook/p631/p631_chap01.pdf," title="web.archive.org/web/20090815150041www.icpress.co.uk/etextbook/p631/p631_chap01.pdf,">web.archive.org/web/20090815150041www.icpress.co.uk/etextbook/p631/p631_chap01.pdf, 15 August 2009, However, real systems may behave nearly as an isolated system for finite (possibly very long) times. The concept of an isolated system can serve as a useful model approximating many real-world situations. It is an acceptable idealization used in constructing mathematical models of certain natural phenomena.In the attempt to justify the postulate of entropy increase in the second law of thermodynamics, Boltzmann’s H-theorem used equations, which assumed that a system (for example, a gas) was isolated. That is all the mechanical degrees of freedom could be specified, treating the walls simply as mirror boundary conditions. This inevitably led to Loschmidt’s paradox. However, if the stochastic behavior of the molecules in actual walls is considered, along with the randomizing effect of the ambient, background thermal radiation, Boltzmann’s assumption of molecular chaos can be justified.The second law of thermodynamics for isolated systems states that the entropy of an isolated system not in equilibrium tends to increase over time, approaching maximum value at equilibrium. Overall, in an isolated system, the internal energy is constant and the entropy can never decrease. A closed system’s entropy can decrease e.g. when heat is extracted from the system.Isolated systems are not equivalent to closed systems. Closed systems cannot exchange matter with the surroundings, but can exchange energy. Isolated systems can exchange neither matter nor energy with their surroundings, and as such are only theoretical and do not exist in reality (except, possibly, the entire universe).’Closed system’ is often used in thermodynamics discussions when ‘isolated system’ would be correct â i.e. there is an assumption that energy does not enter or leave the system.Selective transfer of matter
For a thermodynamic process, the precise physical properties of the walls and surroundings of the system are important, because they determine the possible processes.An open system has one or several walls that allow transfer of matter. To account for the internal energy of the open system, this requires energy transfer terms in addition to those for heat and work. It also leads to the idea of the chemical potential.A wall selectively permeable only to a pure substance can put the system in diffusive contact with a reservoir of that pure substance in the surroundings. Then a process is possible in which that pure substance is transferred between system and surroundings. Also, across that wall a contact equilibrium with respect to that substance is possible. By suitable thermodynamic operations, the pure substance reservoir can be dealt with as a closed system. Its internal energy and its entropy can be determined as functions of its temperature, pressure, and mole number.A thermodynamic operation can render impermeable to matter all system walls other than the contact equilibrium wall for that substance. This allows the definition of an intensive state variable, with respect to a reference state of the surroundings, for that substance. The intensive variable is called the chemical potential; for component substance {{math|i}} it is usually denoted {{math|μ’i}}. The corresponding extensive variable can be the number of moles {{math|N’i}} of the component substance in the system.For a contact equilibrium across a wall permeable to a substance, the chemical potentials of the substance must be same on either side of the wall. This is part of the nature of thermodynamic equilibrium, and may be regarded as related to the zeroth law of thermodynamics.{{sfn|Bailyn|1994|p=19â23}}Open system
{{Expand section|date=September 2016}}In an open system, there is an exchange of energy and matter between the system and the surroundings. The presence of reactants in an open beaker is an example of an open system. Here the boundary is an imaginary surface enclosing the beaker and reactants. It is named closed, if borders are impenetrable for substance, but allow transit of energy in the form of heat, and isolated, if there is no exchange of heat and substances. The open system cannot exist in the equilibrium state. To describe deviation of the thermodynamic system from equilibrium, in addition to constitutive variables that was described above, a set of internal variables xi_1, xi_2,ldots have been introduced. The equilibrium state is considered to be stable and the main property of the internal variables, as measures of non-equilibrium of the system, is their trending to disappear; the local law of disappearing can be written as relaxation equation for each internal variable{{NumBlk|:|frac{dxi_i}{dt} = - frac{1}{tau_i} , left(xi_i - xi_i^{(0)} right),quad i =1,,2,ldots ,See also
- Dynamical system
- Energy system
- Isolated system
- Mechanical system
- Physical system
- Quantum system
- Thermodynamic cycle
- Thermodynamic process
- Two-state quantum system
References
{{reflist}}Sources
- BOOK, M.M., Abbott, H. G., van Hess, Thermodynamics with Chemical Applications, 2nd, McGraw Hill, 1989,
- BOOK, Bailyn, M., 1994, A Survey of Thermodynamics, American Institute of Physics Press, New York, 0-88318-797-3,
- BOOK, Herbert Callen, Callen, H. B., 1960, 1985, Thermodynamics and an Introduction to Thermostatistics, 2nd, Wiley, New York, 0-471-86256-8,
- Carnot, Sadi (1824). Réflexions sur la puissance motrice du feu et sur les machines propres à développer cette puissance (in French). Paris: Bachelier.
- BOOK, Haase, R., 1971, Survey of Fundamental Laws, 1â97, Thermodynamics, Physical Chemistry: An Advanced Treatise, 1, H., Eyring, D., Henderson, W., Jost, Academic Press, New York, 73-117081,
- Dobroborsky B.S. Machine safety and the human factor / Edited by Doctor of Technical Sciences, prof. S.A. Volkov. â St. Petersburg: SPbGASU, 2011. â pp. 33-35. â 114 p. â ISBN 978-5-9227-0276-8. (Ru)
- BOOK, Halliday, David, Robert, Resnick, Jearl, Walker, Fundamentals of Physics, 8th, Wiley, 2008,
- BOOK, Moran, Michael J., Howard N., Shapiro, Fundamentals of Engineering Thermodynamics, 6th, Wiley, 2008,
- BOOK, Rex, Andrew, Finn, C. B. P., Finn’s Thermal Physics, 3rd, Taylor & Francis, 2017, 978-1-498-71887-5,
- BOOK, László Tisza, Tisza, László, 1966, Generalized Thermodynamics, MIT Press,
- BOOK, Tschoegl, N. W., 2000, Fundamentals of Equilibrium and Steady-State Thermodynamics, Elsevier, Amsterdam, 0-444-50426-5,
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