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'''Thermodynamics''' (from the ] ''thermos'' meaning heat and ''dynamis'' meaning power) is a branch of ] that studies the effects of temperature, pressure, and volume changes on ]s at the ] scale. In simpler terms, heat means ‘energy in transit’ and dynamics relates to ‘movement’. Thus, in essence thermodynamics studies how energy instills movement. | |||
{{Short description|Physics of heat, work, and temperature}} | |||
{{Use dmy dates|date=February 2016}} | |||
{{Thermodynamics}} | |||
'''Thermodynamics''' is a branch of ] that deals with ], ], and ], and their relation to ], ], and the physical properties of ] and ]. The behavior of these quantities is governed by the four ], which convey a quantitative description using measurable macroscopic ], but may be explained in terms of ] constituents by ]. Thermodynamics applies to a wide variety of topics in ] and ], especially ], ], ] and ], but also in other complex fields such as ]. | |||
The starting point for most thermodynamic considerations are the ]. These laws postulate that ] can be exchanged between physical systems in the form of ] and ], as well as the existence of a quantity named ], which can be associated with every system. | |||
Historically, thermodynamics developed out of a desire to increase the ] of early ]s, particularly through the work of French physicist ] (1824) who believed that engine efficiency was the key that could help France win the ].<ref>{{cite book | last = Clausius | first = Rudolf | title = On the Motive Power of Heat, and on the Laws which can be deduced from it for the Theory of Heat | publisher = Poggendorff's Annalen der Physik, LXXIX (Dover Reprint) | year = 1850 | isbn = 978-0-486-59065-3}}</ref> Scots-Irish physicist ] was the first to formulate a concise definition of thermodynamics in 1854<ref name="kelvin1854">{{cite book | |||
From its inception, thermodynamics developed out of the need to increase the ] of early ]. The first engine constructed was the 1698 Savery engine as shown below: | |||
|title=Mathematical and Physical Papers | |||
]] | |||
|author=William Thomson, LL.D. D.C.L., F.R.S. | |||
|location=London, Cambridge | |||
|year=1882 | |||
|volume=1 | |||
|page=232 | |||
|publisher=C.J. Clay, M.A. & Son, Cambridge University Press | |||
|isbn=978-0-598-96004-7 | |||
|url=https://books.google.com/books?id=nWMSAAAAIAAJ&q=On+an+Absolute+Thermometric+Scale+Founded+on+Carnot%E2%80%99s+Theory&pg=PA100 | |||
|access-date=2 November 2020 | |||
|archive-date=18 April 2021 | |||
|archive-url=https://web.archive.org/web/20210418220146/https://books.google.com/books?id=nWMSAAAAIAAJ&q=On+an+Absolute+Thermometric+Scale+Founded+on+Carnot%E2%80%99s+Theory&pg=PA100 | |||
|url-status=live | |||
}}</ref> which stated, "Thermo-dynamics is the subject of the relation of heat to forces acting between contiguous parts of bodies, and the relation of heat to electrical agency." German physicist and mathematician ] restated Carnot's principle known as the ] and gave to the ] a truer and sounder basis. His most important paper, "On the Moving Force of Heat",<ref name="Theory of Heat">{{cite book|last=Clausius|first=R.|title=The Mechanical Theory of Heat – with its Applications to the Steam Engine and to Physical Properties of Bodies|year=1867|publisher=John van Voorst|location=London|url=https://archive.org/details/mechanicaltheor04claugoog|quote=editions:PwR_Sbkwa8IC.|access-date=19 June 2012}} Contains English translations of many of his other works.</ref> published in 1850, first stated the ]. In 1865 he introduced the concept of entropy. In 1870 he introduced the ], which applied to heat.<ref>{{cite journal | last = Clausius | first = RJE | year = 1870 | title = On a Mechanical Theorem Applicable to Heat | journal = Philosophical Magazine |series=4th Series | volume = 40 | pages = 122–127}}</ref> | |||
The initial application of thermodynamics to ]s was quickly extended to the study of chemical compounds and chemical reactions. ] studies the nature of the role of entropy in the process of ]s and has provided the bulk of expansion and knowledge of the field. Other formulations of thermodynamics emerged. ], or statistical mechanics, concerns itself with ] predictions of the collective motion of particles from their microscopic behavior. In 1909, ] presented a purely mathematical approach in an ] formulation, a description often referred to as ''geometrical thermodynamics''. | |||
== Overview == | |||
Thermodynamics in most regards is held to be a difficult subject. In ] for example, which teaches one of the more rigorous variations of such, thermodynamics is considered a weeder course. One of the better ways to learn thermodynamics is to follow a ground up development of its concepts and principles, beginning with ] as SI and English, ] as pressure, temperature, and volume, etc., properties of substances as gas, vapor, liquid, and solid, etc., ], the laws of thermodynamics, ], continuing onward through such advanced subjects as multi-phase reaction thermodynamics, high-speed gas flow thermodynamics, or molecular thermodynamics, etc. | |||
==Introduction== | |||
A difficult concept in thermodynamics is that of "]". In particular, the entropy of a system exchanging no ] with the outside can never decrease with ]. As such, entropy allows predictions on the transformations and energy exchanges that are accessible to a given system. Related to entropy, ] or ] is one of the underlying theories that sustain thermodynamics; it provides a way to predict the entropy of a thermodynamic system, based on the ] analysis of the fluctuations the system experiences over a set of ]s | |||
A description of any thermodynamic system employs the four ] that form an axiomatic basis. ] specifies that energy can be transferred between physical systems as ], as ], and with transfer of matter.<ref>{{cite book | author=Van Ness, H.C. | title=Understanding Thermodynamics | publisher=Dover Publications, Inc. | year=1983 | orig-year=1969 | isbn=9780486632773 | oclc=8846081 | url-access=registration | url=https://archive.org/details/understandingthe00vann }}</ref> ] defines the existence of a quantity called ], that describes the direction, thermodynamically, that a system can evolve and quantifies the state of order of a system and that can be used to quantify the useful work that can be extracted from the system.<ref>{{cite book | author=Dugdale, J.S. | title=Entropy and its Physical Meaning | publisher=Taylor and Francis | year=1998 | isbn=978-0-7484-0569-5 | oclc=36457809}}</ref> | |||
In thermodynamics, interactions between large ensembles of objects are studied and categorized. Central to this are the concepts of the thermodynamic '']'' and its '']''. A system is composed of particles, whose average motions define its properties, and those properties are in turn related to one another through ]. Properties can be combined to express ] and ]s, which are useful for determining conditions for ] and ]es. | |||
== History == | |||
{{main|History of thermodynamics}} | |||
] | |||
A short history of thermodynamics begins with the British physicist and chemist ] who in 1656, in coordination with English scientist ], invented the air pump. Using this pump, Boyle and Hooke noticed the pressure-temperature-volume correlation. In time, the ] was formulated. Soon thereafter, in 1679, based on these concepts, an associate of Boyle's named ] built a bone digester, which is a closed vessel with a tightly fitting lid that confines steam until a high pressure is generated. | |||
With these tools, thermodynamics can be used to describe how systems respond to changes in their environment. This can be applied to a wide variety of topics in ] and ], such as ]s, ]s, ]s, ], and even ]s. The results of thermodynamics are essential for other fields of ] and for ], ], ], ], ], ], ], ], and ], to name a few.<ref>{{Cite book | last1=Smith | first1=J.M. | last2=Van Ness | first2=H.C. | last3=Abbott | first3=M.M. | title=Introduction to Chemical Engineering Thermodynamics | journal=Journal of Chemical Education | page=584 | year=2005 | volume=27 | issue=10 | doi=10.1021/ed027p584.3 | isbn=978-0-07-310445-4 | oclc=56491111| bibcode=1950JChEd..27..584S | edition=7th | url=http://www3.ub.tu-berlin.de/ihv/000471510.pdf }}</ref><ref>{{cite book | author=Haynie, Donald T. | title=Biological Thermodynamics | publisher=Cambridge University Press | year=2001 | isbn=978-0-521-79549-4 | oclc=43993556}}</ref> | |||
Later designs implemented a steam release valve to keep the machine from exploding. By watching the valve rhythmically move up and down, Papin conceived of the idea of a piston and cylinder engine. He did not however follow through with his design. Nevertheless, in 1698, based on Papin’s designs, engineer ] built the first engine. These early engines being crude and inefficient attracted the attention of the leading scientists of the time. One such scientist was ], the “father of thermodynamics”, who in 1824 published ''“Reflections on the Motive Power of Fire”,'' a discourse on heat, power, and engine efficiency. This marks the start of thermodynamics as a modern science. | |||
<br style="clear:both;" /> | |||
This article is focused mainly on classical thermodynamics which primarily studies systems in ]. ] is often treated as an extension of the classical treatment, but statistical mechanics has brought many advances to that field. | |||
== Thermodynamic systems == | |||
{{main|System (thermodynamics)}} | |||
==History== | |||
Of most importance in thermodynamics is the concept of the “system”. A system is the region of the universe under study. A system is separated from the remainder of the universe by a boundary which may be imaginary or not, but which, by convention delimits a finite volume. The possible exchanges of ], ], or ] between the system and the surroundings take place across this boundary. There are four dominate classes of systems: | |||
]s of the original eight founding schools of thermodynamics. The schools with the most-lasting influence on the modern versions of thermodynamics are the Berlin school, particularly ]'s 1865 textbook ''The Mechanical Theory of Heat'', the Vienna school, with the ] of ], and the Gibbsian school at Yale University of ]' 1876 and his book '']'' which launched ].<ref name="auto"> {{Webarchive|url=https://web.archive.org/web/20171207151102/http://www.eoht.info/page/Schools+of+thermodynamics|date=7 December 2017}} – EoHT.info.</ref>]]The ] as a scientific discipline generally begins with ] who, in 1650, built and designed the world's first ] and demonstrated a ] using his ]. Guericke was driven to make a vacuum in order to disprove ]'s long-held supposition that 'nature abhors a vacuum'. Shortly after Guericke, the Anglo-Irish physicist and chemist ] had learned of Guericke's designs and, in 1656, in coordination with English scientist ], built an air pump.<ref>{{cite book | author=Partington, J.R. | title=A Short History of Chemistry | url=https://archive.org/details/shorthistoryofch0000part_q6h4 | url-access=registration | publisher=Dover | year=1989 | oclc=19353301| author-link=J. R. Partington }}</ref> Using this pump, Boyle and Hooke noticed a correlation between ], ], and ]. In time, ] was formulated, which states that pressure and volume are ]. Then, in 1679, based on these concepts, an associate of Boyle's named ] built a ], which was a closed vessel with a tightly fitting lid that confined steam until a high pressure was generated. | |||
] | |||
#''Isolated Systems'' – matter and energy may not cross the boundary. | |||
#''Adiabatic Systems'' – heat and matter may not cross the boundary. | |||
#''Closed Systems'' – matter may not cross the boundary. | |||
#''Open Systems'' – heat, work, and matter may cross the boundary. | |||
Later designs implemented a steam release valve that kept the machine from exploding. By watching the valve rhythmically move up and down, Papin conceived of the idea of a ] and a cylinder engine. He did not, however, follow through with his design. Nevertheless, in 1697, based on Papin's designs, engineer ] built the first engine, followed by ] in 1712. Although these early engines were crude and inefficient, they attracted the attention of the leading scientists of the time. | |||
For closed systems, as time goes by, internal differences in the system tend to even out; pressures and temperatures tend to equalize, as do density differences. A system in which all equalizing processes have gone practically to completion, is considered to be in a ] of ]. | |||
The fundamental concepts of ] and ], which were necessary for the development of thermodynamics, were developed by Professor ] at the University of Glasgow, where ] was employed as an instrument maker. Black and Watt performed experiments together, but it was Watt who conceived the idea of the ] which resulted in a large increase in ] efficiency.<ref>The Newcomen engine was improved from 1711 until Watt's work, making the efficiency comparison subject to qualification, but the increase from the 1865 version was on the order of 100%.</ref> Drawing on all the previous work led ], the "father of thermodynamics", to publish '']'' (1824), a discourse on heat, power, energy and engine efficiency. The book outlined the basic energetic relations between the ], the ], and motive power. It marked the start of thermodynamics as a modern science.<ref name="Perrot">{{cite book |author=Perrot, Pierre |title=A to Z of Thermodynamics |publisher=Oxford University Press |year=1998 |isbn=978-0-19-856552-9 |oclc=123283342}}</ref> | |||
In thermodynamic equilibrium, a system's properties are, by definition, unchanging in time. Systems in equilibrium are much simpler and easier to understand than systems which are not in equilibrium. Often, when analyzing a thermodynamic process, it can be assumed that each intermediate state in the process is at equilibrium. This will also considerably simplify the situation. Thermodynamic processes which develop so slowly as to allow each intermediate step to be an equilibrium state are said to be ] processes. | |||
The first thermodynamic textbook was written in 1859 by ], originally trained as a physicist and a civil and mechanical engineering professor at the ].<ref>{{cite book |author1=Cengel, Yunus A. |author2=Boles, Michael A. | title=Thermodynamics – an Engineering Approach | publisher=McGraw-Hill | year=2005 | isbn=978-0-07-310768-4}}</ref> The first and second laws of thermodynamics emerged simultaneously in the 1850s, primarily out of the works of William Rankine, ], and ] (Lord Kelvin). | |||
== Thermodynamic parameters == | |||
The foundations of statistical thermodynamics were set out by physicists such as ], ], ], ] and ]. | |||
{{main|Conjugate variables (thermodynamics)}} | |||
Clausius, who first stated the basic ideas of the second law in his paper "On the Moving Force of Heat",<ref name="Theory of Heat"/> published in 1850, and is called "one of the founding fathers of thermodynamics",<ref>{{Citation | author=Cardwell, D.S.L. | title=From Watt to Clausius: The Rise of Thermodynamics in the Early Industrial Age | location=London | publisher=Heinemann | year=1971 | isbn=978-0-435-54150-7}}</ref> introduced the concept of ] in 1865. | |||
The central concept of thermodynamics is that of ], the ability to do ]. As stipulated by the ], the total energy of the system and its surroundings is conserved. It may be transferred into a body by heating, compression, or addition of matter, and extracted from a body either by expansion, cooling, or extraction of matter. Just as in ], energy transfer is effected by a force causing a displacement, with the product of the two being the amount of energy transferred. In a similar way, thermodynamic systems can be thought of as transferring energy as the result of a generalized force causing a generalized displacement, with the product of the two being the amount of energy transferred. These thermodynamic force-displacement pairs are known as ]. The most common conjugate thermodynamic variables are pressure-volume (mechanical parameters), temperature-entropy (thermal parameters), and chemical potential-particle number (material parameters). | |||
During the years 1873–76 the American mathematical physicist ] published a series of three papers, the most famous being '']'',<ref name="Gibbs 1876">{{cite book |author=Gibbs, Willard, J. |url=https://archive.org/details/transactions03conn |title=Transactions of the Connecticut Academy of Arts and Sciences |publisher=New Haven |year=1874–1878 |volume=III |pages=–248, 343–524}}</ref> in which he showed how ], including ]s, could be graphically analyzed, by studying the ], ], ], ] and ] of the ] in such a manner, one can determine if a process would occur spontaneously.<ref>{{cite book | author=Gibbs, Willard | title=The Scientific Papers of J. Willard Gibbs, Volume One: Thermodynamics | publisher=Ox Bow Press | year=1993 | isbn=978-0-918024-77-0 | oclc=27974820}}</ref> Also ] in the 19th century wrote about chemical thermodynamics.<ref name="Duhem 1886">Duhem, P.M.M. (1886). ''Le Potential Thermodynamique et ses Applications'', Hermann, Paris.</ref> During the early 20th century, chemists such as ], ],<ref name="Lewis Randall 1923">{{cite book |last1=Lewis |first1=Gilbert N. |url=https://archive.org/details/thermodynamicsfr00gnle |title=Thermodynamics and the Free Energy of Chemical Substances |last2=Randall |first2=Merle |publisher=McGraw-Hill Book Co. Inc. |year=1923}}</ref> and ]<ref name="Guggenheim 1933">Guggenheim, E.A. (1933). ''Modern Thermodynamics by the Methods of J.W. Gibbs'', Methuen, London.</ref><ref name="Guggenheim 1949/1967">Guggenheim, E.A. (1949/1967). ''Thermodynamics. An Advanced Treatment for Chemists and Physicists'', 1st edition 1949, 5th edition 1967, North-Holland, Amsterdam.</ref> applied the mathematical methods of Gibbs to the analysis of chemical processes. | |||
== Thermodynamic instruments == | |||
{{main|Thermodynamic instruments}} | |||
==Etymology== | |||
There are two types of thermodynamic instruments, the '''meter''' and the '''reservoir'''. A thermodynamic meter is any device which measures any parameter of a ]. In some cases, the thermodynamic parameter is actually defined in terms of an idealized measuring instrument. For example, the ] states that if two bodies are in thermal equilibrium with a third body, they are also in thermal equilibrium with each other. This principle, as noted by ] in 1872, asserts that it is possible to measure temperature. An idealized ] is a sample of an ideal gas at constant pressure. From the ] ''PV=NRT'', the volume of such a sample can be used as an indicator of temperature; in this manner it defines temperature. Although pressure is defined mechanically, a pressure-measuring device, called a ] may also be constructed from a sample of an ideal gas held at a constant temperature. A ] is a device which is used to measure and define the internal energy of a system. | |||
<!-- the history of the term is rich, more needs to be added--> | |||
''Thermodynamics'' has an intricate etymology.<ref name="eoht">{{cite web | |||
|url=https://www.eoht.info/page/Thermodynamics+(etymology) | |||
|title=Thermodynamics (etymology) | |||
|publisher=EoHT.info | |||
|access-date=29 October 2023 | |||
|archive-date=29 October 2023 | |||
|archive-url=https://web.archive.org/web/20231029004136/https://www.eoht.info/page/Thermodynamics%20(etymology) | |||
|url-status=live | |||
}}</ref> | |||
By a surface-level analysis, the word consists of two parts that can be traced back to Ancient Greek. Firstly, {{wikt-lang|en|thermo-}} ("of heat"; used in words such as '']'') can be traced back to the root ] ''therme'', meaning "heat". Secondly, the word {{wikt-lang|en|dynamics}} ("science of force ")<ref>{{cite book|last=Thompson|first=Silvanus |title=The Life of William Thomson, Baron Kelvin of Largs|volume= 1|year=1910|publisher=MacMillan and Co., Limited |page=|url=https://archive.org/details/b31360403_0001|quote=the fundamental subject of Natural Philosophy is Dynamics, or the ''science of force'' .... Every phenomenon in nature is a manifestation of force.}}</ref> can be traced back to the root ] ''dynamis'', meaning "power".<ref>{{cite book | |||
A thermodynamic reservoir is a system which is so large that it does not appreciably alter its state parameters when brought into contact with the test system. It is used to impose a particular value of a state parameter upon the system. For example, a pressure reservoir is a system at a particular pressure, which imposes that pressure upon any test system that it is mechanically connected to. The earths atmosphere is often used as a pressure reservoir. | |||
|title=Biological Thermodynamics | |||
|url=https://archive.org/details/biologicalthermo0000hayn | |||
|url-access=registration | |||
|edition=2 | |||
|author=Donald T. Haynie | |||
|publisher=Cambridge University Press | |||
|year=2008 | |||
|page= | |||
}}</ref> | |||
In 1849, the adjective ''thermo-dynamic'' is used by William Thomson.<ref name="kelvin1849">Kelvin, William T. (1849) "An Account of Carnot's Theory of the Motive Power of Heat – with Numerical Results Deduced from Regnault's Experiments on Steam." ''Transactions of the Edinburg Royal Society, XVI. January 2.'' {{Webarchive|url=https://web.archive.org/web/20170724100855/http://www.archive.org/stream/mathematicaland01kelvgoog |date=24 July 2017 }}</ref><ref name="smith77" /> | |||
== Thermodynamic states == | |||
{{main|Thermodynamic state}} | |||
In 1854, the noun ''thermo-dynamics'' is used by Thomson and William Rankine to represent the science of generalized heat engines.<ref name=smith77>{{cite journal |last1=Smith |first1=Crosbie W. |title=William Thomson and the Creation of Thermodynamics: 1840-1855 |journal=Archive for History of Exact Sciences |date=1977 |volume=16 |issue=3 |pages=231–288 |doi=10.1007/BF00328156 |jstor=41133471 |s2cid=36609995 |url=https://www.jstor.org/stable/41133471 |issn=0003-9519}}</ref><ref name="eoht" /> | |||
When a system is at equilibrium under a given set of conditions, it is said to be in a definite ''state''. The state of the system can be described by a number of ]s and ]s. The properties of the system can be described by an ] which specifies the relationship between these variables. State may be thought of as the instantaneous quantitative description of a system with a set number of variables held constant. | |||
Pierre Perrot claims that the term ''thermodynamics'' was coined by ] in 1858 to designate the science of relations between heat and power,<ref name="Perrot" /> however, Joule never used that term, but used instead the term ''perfect thermo-dynamic engine'' in reference to Thomson's 1849<ref name="kelvin1849" /> phraseology.<ref name="eoht" /> | |||
== Thermodynamic processes == | |||
{{main|Thermodynamic processes}} | |||
==Branches of thermodynamics== | |||
A '''thermodynamic process''' may be defined as the energetic evolution of a thermodynamic system proceeding from an initial state to a final state. Typically, each thermodynamic process is distinguished from other processes, in energetic character, according to what parameters, as temperature, pressure, or volume, etc., are held fixed. Furthermore, it is useful to group these processes into pairs, in which each variable held constant is one member of a ] pair. The five most common thermodynamic processes are shown below: | |||
The study of thermodynamical systems has developed into several related branches, each using a different fundamental model as a theoretical or experimental basis, or applying the principles to varying types of systems. | |||
===Classical thermodynamics=== | |||
#An ] occurs at constant pressure. | |||
Classical thermodynamics is the description of the states of thermodynamic systems at near-equilibrium, that uses macroscopic, measurable properties. It is used to model exchanges of energy, work and heat based on the ]. The qualifier ''classical'' reflects the fact that it represents the first level of understanding of the subject as it developed in the 19th century and describes the changes of a system in terms of macroscopic empirical (large scale, and measurable) parameters. A microscopic interpretation of these concepts was later provided by the development of ''statistical mechanics''. | |||
#An ] occurs at constant volume. | |||
#An ] occurs at a constant temperature. | |||
#An ] occurs at a constant entropy. | |||
#An ] occurs without loss or gain of heat. | |||
===Statistical mechanics=== | |||
== The laws of thermodynamics == | |||
], also known as statistical thermodynamics, emerged with the development of atomic and molecular theories in the late 19th century and early 20th century, and supplemented classical thermodynamics with an interpretation of the microscopic interactions between individual particles or quantum-mechanical states. This field relates the microscopic properties of individual atoms and molecules to the macroscopic, bulk properties of materials that can be observed on the human scale, thereby explaining classical thermodynamics as a natural result of statistics, classical mechanics, and ] at the microscopic level. | |||
{{main|Laws of thermodynamics}} | |||
===Chemical thermodynamics=== | |||
In thermodynamics, there are four laws of very general validity, and as such they do not depend on the details of the interactions or the systems being studied. Hence, they can be applied to systems about which one knows nothing other than the balance of energy and matter transfer. Examples of this include ]'s prediction of ] around the turn of the ] and current research into the thermodynamics of ]s. | |||
] is the study of the interrelation of ] with ] or with a physical change of ] within the confines of the ]. The primary objective of chemical thermodynamics is determining the spontaneity of a given transformation.<ref>{{cite book |last1=Klotz |first1=Irving |title=Chemical Thermodynamics: Basic Theory and Methods |date=2008 |publisher=John Wiley & Sons, Inc. |location=Hoboken, New Jersey |page = 4 |isbn=978-0-471-78015-1}}</ref> | |||
===Equilibrium thermodynamics=== | |||
The four laws are: | |||
] is the study of transfers of matter and energy in systems or bodies that, by agencies in their surroundings, can be driven from one state of thermodynamic equilibrium to another. The term 'thermodynamic equilibrium' indicates a state of balance, in which all macroscopic flows are zero; in the case of the simplest systems or bodies, their intensive properties are homogeneous, and their pressures are perpendicular to their boundaries. In an equilibrium state there are no unbalanced potentials, or driving forces, between macroscopically distinct parts of the system. A central aim in equilibrium thermodynamics is: given a system in a well-defined initial equilibrium state, and given its surroundings, and given its constitutive walls, to calculate what will be the final equilibrium state of the system after a specified thermodynamic operation has changed its walls or surroundings. | |||
===Non-equilibrium thermodynamics=== | |||
* ], about the ] of ] | |||
] is a branch of thermodynamics that deals with systems that are not in ]. Most systems found in nature are not in thermodynamic equilibrium because they are not in stationary states, and are continuously and discontinuously subject to flux of matter and energy to and from other systems. The thermodynamic study of non-equilibrium systems requires more general concepts than are dealt with by equilibrium thermodynamics.<ref>{{Cite book|url=|title= Thermodynamics of Complex Systems: Principles and applications. |last= Pokrovskii |first=Vladimir|language=English | publisher= IOP Publishing, Bristol, UK.|year=2020|isbn=|pages=|bibcode= 2020tcsp.book.....P }}</ref> Many natural systems still today remain beyond the scope of currently known macroscopic thermodynamic methods. | |||
**If A and B are in thermal equilibrium, and B and C are in thermal equilibrium, then A and C are also in thermal equilibrium. | |||
**Two systems in thermal equilibrium with a third system, all must be in equilibrium with each other. | |||
* ], or a statement about the ] | |||
**The work exchanged in an adiabatic process depends only on the initial and the final state and not on the details of the process. | |||
**The heat energy flowing into a system is equal to the sum of the increase in the internal energy of the system and the work done by the system. | |||
* ], about ] | |||
**The ] of an isolated system never decreases (see ]) | |||
**A system operating in contact with a thermal reservoir cannot produce positive work in its surroundings (]) | |||
**A system operating in a cycle cannot produce a positive heat flow from a colder body to a hotter body (]) | |||
* ], about ] ] | |||
**All processes cease as temperature approaches zero. | |||
**As temperature goes to 0, the entropy of a system approaches a constant | |||
==Laws of thermodynamics== | |||
== Thermodynamic potentials == | |||
{{Main|Laws of thermodynamics}} | |||
{{main|Thermodynamic potentials}} | |||
] showing the hot body (boiler), working body (system, steam), and cold body (water), the letters labeled according to the stopping points in ]]] | |||
As derived from the energy balance equation on a thermodynamic system there exist energetic quantities called ], being the quantitative measure of the stored energy in the system. The four most well known potentials are: | |||
Thermodynamics is principally based on a set of four laws which are universally valid when applied to systems that fall within the constraints implied by each. In the various theoretical descriptions of thermodynamics these laws may be expressed in seemingly differing forms, but the most prominent formulations are the following. | |||
===Zeroth law=== | |||
{| border="0" cellpadding="4" style="margin: 0 0 1em 1em" | |||
The ] states: ''If two systems are each in thermal equilibrium with a third, they are also in thermal equilibrium with each other.'' | |||
|- | |||
|] | |||
|<math>U\,</math> | |||
|- | |||
|] | |||
|<math>A=U-TS\,</math> | |||
|- | |||
|] | |||
|<math>H=U+PV\,</math> | |||
|- | |||
|] | |||
|<math>G=U+PV-TS\,</math> | |||
|} | |||
This statement implies that thermal equilibrium is an ] on the set of ]s under consideration. Systems are said to be in equilibrium if the small, random exchanges between them (e.g. ]) do not lead to a net change in energy. This law is tacitly assumed in every measurement of temperature. Thus, if one seeks to decide whether two bodies are at the same ], it is not necessary to bring them into contact and measure any changes of their observable properties in time.<ref>Moran, Michael J. and Howard N. Shapiro, 2008. ''Fundamentals of Engineering Thermodynamics''. 6th ed. Wiley and Sons: 16.</ref> The law provides an empirical definition of temperature, and justification for the construction of practical thermometers. | |||
Potentials are used to measure energy changes in systems as they evolve from an initial state to a final state. The potential used depends on the constraints of the system, such as constant temperature or pressure. Internal energy is the internal energy of the system, enthalpy is the internal energy of the system plus the energy related to pressure-volume work, and Helmholtz and Gibbs free energy are the energies available in a system to do useful work when the temperature and volume or the pressure and temperature are fixed, respectively. | |||
The zeroth law was not initially recognized as a separate law of thermodynamics, as its basis in thermodynamical equilibrium was implied in the other laws. The first, second, and third laws had been explicitly stated already, and found common acceptance in the physics community before the importance of the zeroth law for the definition of temperature was realized. As it was impractical to renumber the other laws, it was named the ''zeroth law''. | |||
== Thermodynamic evolution == | |||
{{main|Thermodynamic evolution}} | |||
===First law=== | |||
In 1875 Austrian physicist ] declared: ''"the general struggle for existence of animate beings is a struggle for ]"''. Ever since, there has been a continuous search to elucidate the thermodynamic mechanism behind evolution. As it is generally agreed that life evolved from non-life, a process called ], by some form of ], and as it is understood that both life and non-life abide by the ], then, in theory, it is reasoned that there should exist a functionable model of thermodynamic evolution. This line of research defines the field of thermodynamic evolution. | |||
] (]). The sudden drop of pressure causes a huge drop of temperature. The moisture in the air freezes, creating a smoke of tiny ice crystals.<ref>{{cite web |url=https://www.chemistryviews.org/details/ezine/889289/Sparkling_Wine_Champagne__Co__Part_2/ |publisher=Chemistry Europe (chemistryviews.org) |work=Sparkling Wine, Champagne & Co |title=Sparkling Wine, Champagne & Co - Part 2 |date=17 December 2010 |access-date=17 April 2023}}</ref><ref>Klaus Roth: ''Sekt, Champagner & Co. So prickelnd kann Chemie sein'' in ''Chemie unserer Zeit'' 8. Dezember 2009: Vol. 43, Issue 6, S. 418-432 ]</ref><ref>Klaus Roth: ''Chemische Köstlichkeiten'', Wiley-VCH Verlag GmbH & Co. KGaA, 2010, ISBN 978-3527327522, S. 47</ref>]] | |||
The ] states: ''In a process without transfer of matter, the change in ],'' <math>\Delta U</math>'', of a ] is equal to the energy gained as heat,'' <math>Q</math>'', less the thermodynamic work,'' <math>W</math>'', done by the system on its surroundings.''<ref>Bailyn, M. (1994). ''A Survey of Thermodynamics'', American Institute of Physics, AIP Press, Woodbury NY, {{ISBN|0883187973}}, p. 79.</ref><ref group=nb>The sign convention (Q is heat supplied ''to'' the system as, W is work done ''by'' the system) is that of ]. The opposite sign convention is customary in chemical thermodynamics.</ref> | |||
:<math>\Delta U = Q - W</math>. | |||
== Quotes & humor == | |||
{{main|Quotes & humor (thermodynamics)}} | |||
where <math>\Delta U</math> denotes the change in the internal energy of a ] (for which heat or work through the system boundary are possible, but matter transfer is not possible), <math>Q</math> denotes the quantity of energy supplied ''to'' the system as heat, and <math>W</math> denotes the amount of thermodynamic work done ''by'' the system ''on'' its surroundings. An equivalent statement is that ] of the first kind are impossible; work <math>W</math> done by a system on its surrounding requires that the system's internal energy <math>U</math> decrease or be consumed, so that the amount of internal energy lost by that work must be resupplied as heat <math>Q</math> by an external energy source or as work by an external machine acting on the system (so that <math>U</math> is recovered) to make the system work continuously. | |||
* A common scientific joke expresses the three laws simply and surprisingly accurately as: | |||
For processes that include transfer of matter, a further statement is needed: ''With due account of the respective fiducial reference states of the systems, when two systems, which may be of different chemical compositions, initially separated only by an impermeable wall, and otherwise isolated, are combined into a new system by the thermodynamic operation of removal of the wall, then'' | |||
: '''Zeroth:''' ''"You must play the game."'' | |||
: '''First:''' ''"You can't win."'' | |||
: '''Second:''' ''"You can't break even."'' | |||
: '''Third:''' ''"You can't quit the game."'' | |||
:<math>U_0 = U_1 + U_2</math>, | |||
== See also == | |||
* ] | |||
''where'' {{math|''U''<sub>0</sub>}} ''denotes the internal energy of the combined system, and'' {{math|''U''<sub>1</sub>}} ''and'' {{math|''U''<sub>2</sub>}} ''denote the internal energies of the respective separated systems.'' | |||
* ] | |||
* ] - sometimes called the ''Fourth Law of Thermodynamics'' | |||
Adapted for thermodynamics, this law is an expression of the principle of ], which states that energy can be transformed (changed from one form to another), but cannot be created or destroyed.<ref>Callen, H.B. (1960/1985).''Thermodynamics and an Introduction to Thermostatistics'', second edition, John Wiley & Sons, Hoboken NY, {{ISBN|9780471862567}}, pp. 11–13.</ref> | |||
* ] | |||
* ] | |||
Internal energy is a principal property of the ], while heat and work are modes of energy transfer by which a process may change this state. A change of internal energy of a system may be achieved by any combination of heat added or removed and work performed on or by the system. As a ], the internal energy does not depend on the manner, or on the path through intermediate steps, by which the system arrived at its state. | |||
* ] | |||
* ] | |||
===Second law=== | |||
=== Related lists and timelines === | |||
A traditional version of the ] states: ''Heat does not spontaneously flow from a colder body to a hotter body.'' | |||
* ] | |||
* ] | |||
The second law refers to a system of matter and radiation, initially with inhomogeneities in temperature, pressure, chemical potential, and other ], that are due to internal 'constraints', or impermeable rigid walls, within it, or to externally imposed forces. The law observes that, when the system is isolated from the outside world and from those forces, there is a definite thermodynamic quantity, its ], that increases as the constraints are removed, eventually reaching a maximum value at thermodynamic equilibrium, when the inhomogeneities practically vanish. For systems that are initially far from thermodynamic equilibrium, though several have been proposed, there is known no general physical principle that determines the rates of approach to thermodynamic equilibrium, and thermodynamics does not deal with such rates. The many versions of the second law all express the general ] of the transitions involved in systems approaching thermodynamic equilibrium. | |||
* ] | |||
=== Related fields === | |||
In macroscopic thermodynamics, the second law is a basic observation applicable to any actual thermodynamic process; in statistical thermodynamics, the second law is postulated to be a consequence of molecular chaos. | |||
* ] | |||
* ] | |||
===Third law=== | |||
* ] | |||
The ] states: ''As the temperature of a system approaches absolute zero, all processes cease and the entropy of the system approaches a minimum value.'' | |||
* ] | |||
* ] (also known as chemical thermodynamics) | |||
This law of thermodynamics is a statistical law of nature regarding entropy and the impossibility of reaching ] of temperature. This law provides an absolute reference point for the determination of entropy. The entropy determined relative to this point is the absolute entropy. Alternate definitions include "the entropy of all systems and of all states of a system is smallest at absolute zero," or equivalently "it is impossible to reach the absolute zero of temperature by any finite number of processes". | |||
Absolute zero, at which all activity would stop if it were possible to achieve, is −273.15 °C (degrees Celsius), or −459.67 °F (degrees Fahrenheit), or 0 K (kelvin), or 0° R (degrees ]). | |||
==System models== | |||
] | |||
An important concept in thermodynamics is the ], which is a precisely defined region of the universe under study. Everything in the universe except the system is called the ]. A system is separated from the remainder of the universe by a ] which may be a physical or notional, but serve to confine the system to a finite volume. Segments of the ''boundary'' are often described as ''walls''; they have respective defined 'permeabilities'. Transfers of energy as ], or as ], or of ], between the system and the surroundings, take place through the walls, according to their respective permeabilities. | |||
Matter or energy that pass across the boundary so as to effect a change in the internal energy of the system need to be accounted for in the energy balance equation. The volume contained by the walls can be the region surrounding a single atom resonating energy, such as Max Planck defined in 1900; it can be a body of steam or air in a ], such as Sadi Carnot defined in 1824. The system could also be just one ] (i.e. a system of ]s) as hypothesized in ]. When a looser viewpoint is adopted, and the requirement of thermodynamic equilibrium is dropped, the system can be the body of a ], such as ] theorized in 1986 in the field of ], or the ] of a ]. | |||
Boundaries are of four types: fixed, movable, real, and imaginary. For example, in an engine, a fixed boundary means the piston is locked at its position, within which a constant volume process might occur. If the piston is allowed to move that boundary is movable while the cylinder and cylinder head boundaries are fixed. For closed systems, boundaries are real while for open systems boundaries are often imaginary. In the case of a jet engine, a fixed imaginary boundary might be assumed at the intake of the engine, fixed boundaries along the surface of the case and a second fixed imaginary boundary across the exhaust nozzle. | |||
Generally, thermodynamics distinguishes three classes of systems, defined in terms of what is allowed to cross their boundaries: | |||
{{table of thermodynamic systems}} | |||
As time passes in an isolated system, internal differences of pressures, densities, and temperatures tend to even out. A system in which all equalizing processes have gone to completion is said to be in a ] of ]. | |||
Once in thermodynamic equilibrium, a system's properties are, by definition, unchanging in time. Systems in equilibrium are much simpler and easier to understand than are systems which are not in equilibrium. Often, when analysing a dynamic thermodynamic process, the simplifying assumption is made that each intermediate state in the process is at equilibrium, producing thermodynamic processes which develop so slowly as to allow each intermediate step to be an equilibrium state and are said to be ]. | |||
==States and processes== | |||
When a system is at equilibrium under a given set of conditions, it is said to be in a definite ]. The state of the system can be described by a number of ] that do not depend on the process by which the system arrived at its state. They are called ]s or ]s according to how they change when the size of the system changes. The properties of the system can be described by an ] which specifies the relationship between these variables. State may be thought of as the instantaneous quantitative description of a system with a set number of variables held constant. | |||
A ] may be defined as the energetic evolution of a thermodynamic system proceeding from an initial state to a final state. It can be described by ]. Typically, each thermodynamic process is distinguished from other processes in energetic character according to what parameters, such as temperature, pressure, or volume, etc., are held fixed; Furthermore, it is useful to group these processes into pairs, in which each variable held constant is one member of a ] pair. | |||
Several commonly studied thermodynamic processes are: | |||
* ]: occurs without loss or gain of energy by ] | |||
* ]: occurs at a constant ] | |||
* ]: a reversible adiabatic process, occurs at a constant ] | |||
* ]: occurs at constant ] | |||
* ]: occurs at constant ] (also called isometric/isovolumetric) | |||
* ]: occurs at a constant ] | |||
* ]: occurs without a change in the ] | |||
== Instrumentation == | |||
There are two types of ], the meter and the reservoir. A thermodynamic meter is any device which measures any parameter of a ]. In some cases, the thermodynamic parameter is actually defined in terms of an idealized measuring instrument. For example, the ] states that if two bodies are in thermal equilibrium with a third body, they are also in thermal equilibrium with each other. This principle, as noted by ] in 1872, asserts that it is possible to measure temperature. An idealized ] is a sample of an ideal gas at constant pressure. From the ] ''pV=nRT'', the volume of such a sample can be used as an indicator of temperature; in this manner it defines temperature. Although pressure is defined mechanically, a pressure-measuring device, called a ] may also be constructed from a sample of an ideal gas held at a constant temperature. A ] is a device which is used to measure and define the internal energy of a system. | |||
A thermodynamic reservoir is a system which is so large that its state parameters are not appreciably altered when it is brought into contact with the system of interest. When the reservoir is brought into contact with the system, the system is brought into equilibrium with the reservoir. For example, a pressure reservoir is a system at a particular pressure, which imposes that pressure upon the system to which it is mechanically connected. The Earth's atmosphere is often used as a pressure reservoir. The ocean can act as temperature reservoir when used to cool power plants. | |||
== Conjugate variables == | |||
{{Main|Conjugate variables (thermodynamics)|l1=Conjugate variables}} | |||
The central concept of thermodynamics is that of ], the ability to do ]. By the ], the total energy of a system and its surroundings is conserved. Energy may be transferred into a system by heating, compression, or addition of matter, and extracted from a system by cooling, expansion, or extraction of matter. In ], for example, energy transfer equals the product of the force applied to a body and the resulting displacement. | |||
] are pairs of thermodynamic concepts, with the first being akin to a "force" applied to some ], the second being akin to the resulting "displacement", and the product of the two equaling the amount of energy transferred. The common conjugate variables are: | |||
* ]-] (the ] parameters); | |||
* ]-] (thermal parameters); | |||
* ]-] (material parameters). | |||
== Potentials == | |||
]s are different quantitative measures of the stored energy in a system. Potentials are used to measure the energy changes in systems as they evolve from an initial state to a final state. The potential used depends on the constraints of the system, such as constant temperature or pressure. For example, the Helmholtz and Gibbs energies are the energies available in a system to do useful work when the temperature and volume or the pressure and temperature are fixed, respectively. Thermodynamic potentials cannot be measured in laboratories, but can be computed using molecular thermodynamics.<ref>{{Cite journal |last1=Graben |first1=H.W. |last2=Ray |first2=John R. |date=1993-12-10 |title=Eight physical systems of thermodynamics, statistical mechanics, and computer simulations |url=http://dx.doi.org/10.1080/00268979300102971 |journal=Molecular Physics |volume=80 |issue=5 |pages=1183–1193 |doi=10.1080/00268979300102971 |bibcode=1993MolPh..80.1183G |issn=0026-8976}}</ref><ref>{{Cite journal |last1=Nitzke |first1=Isabel |last2=Stephan |first2=Simon |last3=Vrabec |first3=Jadran |date=2024-06-03 |title=Topology of thermodynamic potentials using physical models: Helmholtz, Gibbs, Grand, and Null |url=http://dx.doi.org/10.1063/5.0207592 |journal=The Journal of Chemical Physics |volume=160 |issue=21 |doi=10.1063/5.0207592 |pmid=38828811 |bibcode=2024JChPh.160u4104N |issn=0021-9606}}</ref> | |||
The five most well known potentials are: | |||
{{table of thermodynamic potentials}} | |||
where <math>T</math> is the ], <math>S</math> the ], <math>p</math> the ], <math>V</math> the ], <math>\mu</math> the ], <math>N</math> the number of particles in the system, and <math>i</math> is the count of particles types in the system. | |||
Thermodynamic potentials can be derived from the energy balance equation applied to a thermodynamic system. Other thermodynamic potentials can also be obtained through ]. | |||
== Axiomatic thermodynamics == | |||
Axiomatic thermodynamics is a ] that aims to describe thermodynamics in terms of rigorous ]s, for example by finding a mathematically rigorous way to express the familiar ]. | |||
The first attempt at an axiomatic theory of thermodynamics was ]'s 1909 work ''Investigations on the Foundations of Thermodynamics'', which made use of ] and the concept of ], a notion that was introduced by Carathéodory himself.<ref>{{Cite journal|last=Carathéodory|first=C.|date=1909|title=Untersuchungen über die Grundlagen der Thermodynamik|url=http://link.springer.com/10.1007/BF01450409|journal=]|language=de|volume=67|issue=3|pages=355–386|doi=10.1007/BF01450409|s2cid=118230148 |issn=0025-5831|via=}}</ref><ref name=frankel>{{cite book|last=Frankel |first=Theodore |title=The Geometry of Physics: An Introduction |edition=second |publisher=Cambridge University Press |year=2004 |isbn=9780521539272}}</ref> In this formulation, thermodynamic concepts such as ], ], and ] are derived from quantities that are more directly measurable.<ref>{{Cite journal|last=Rastall|first=Peter|date=1970-10-01|title=Classical Thermodynamics Simplified|url=https://aip.scitation.org/doi/10.1063/1.1665080|journal=]|volume=11|issue=10|pages=2955–2965|doi=10.1063/1.1665080|bibcode=1970JMP....11.2955R |issn=0022-2488}}</ref> Theories that came after, differed in the sense that they made assumptions regarding ]es with arbitrary initial and final states, as opposed to considering only neighboring states. | |||
== Applied fields == | |||
{{columns-list|colwidth=22em| | |||
* ] | |||
* ] | * ] | ||
* ] | * ] | ||
* ] | |||
* ] | |||
* ] | |||
* ] (re: ]) | |||
* ] | |||
* ] | |||
* ] | * ] | ||
* ] | * ] | ||
* ] | |||
=== Wikibooks === | |||
* ], i.e. Statistical mechanics | |||
* | |||
* ] | |||
== References == | |||
* ] | |||
* {{Book reference | Author=Perrot, Pierre | Title=A to Z of Thermodynamics | Publisher=Oxford University Press | Year=1998 | ID=ISBN 0198565526}} | |||
}} | |||
* {{Book reference | Author=Kroemer, Herbert; Kittel, Charles | Title=Thermal Physics | Publisher=W. H. Freeman Company | Year=1980 | ID=ISBN 0716710889}} | |||
* {{Book reference | Author=Cengel, Yunus A.; Boles, Michael A. | Title=Thermodynamics - An Engineering Approach | Publisher=McGraw-Hill | Year=2005 | ID=ISBN 0073107689}} | |||
== See also == | |||
{{Portal|Physics}} | |||
* ] | |||
===Lists and timelines=== | |||
* ]{{Broken anchor|date=2024-06-17|bot=User:Cewbot/log/20201008/configuration|target_link=List of important publications in physics#Thermodynamics|reason= The anchor (Thermodynamics) ].}} | |||
* ] | |||
* ] | |||
* ] | |||
* ] | |||
* ] | |||
* ] | |||
== Notes == | |||
{{Reflist|group=nb}} | |||
==References== | |||
{{Reflist|2}} | |||
==Further reading== | |||
* {{cite book|author1=Goldstein, Martin|author2=Inge F.|name-list-style=amp|title=The Refrigerator and the Universe|url=https://archive.org/details/refrigeratoruniv0000gold|url-access=registration|publisher=Harvard University Press|year=1993|isbn=978-0-674-75325-9|oclc=32826343}} A nontechnical introduction, good on historical and interpretive matters. | |||
* {{cite journal |last1=Kazakov |first1=Andrei |last2=Muzny |first2=Chris D. |last3=Chirico |first3=Robert D. |last4=Diky |first4=Vladimir V. |last5=Frenkel |first5=Michael |title=Web Thermo Tables – an On-Line Version of the TRC Thermodynamic Tables |journal=Journal of Research of the National Institute of Standards and Technology |volume=113 |issue=4 |year=2008 |pages=209–220 |issn=1044-677X |doi=10.6028/jres.113.016 |pmc=4651616 |pmid=27096122}} | |||
* {{cite book|author=Gibbs J.W.|title=The Collected Works of J. Willard Gibbs Thermodynamics.|publisher=Longmans, Green and Co.|year=1928|location=New York}} Vol. 1, pp. 55–349. | |||
* {{cite book|author=Guggenheim E.A.|title=Modern thermodynamics by the methods of Willard Gibbs|publisher=Methuen & co. ltd.|year=1933|location=London}} | |||
* {{cite book|author=Denbigh K.|title=The Principles of Chemical Equilibrium: With Applications in Chemistry and Chemical Engineering.|publisher=Cambridge University Press|year=1981|location=London}} | |||
* {{cite book|author=Stull, D.R., Westrum Jr., E.F. and Sinke, G.C.|title=The Chemical Thermodynamics of Organic Compounds.|publisher=John Wiley and Sons, Inc.|year=1969|location=London}} | |||
* {{cite book|author=Bazarov I.P.|title=Thermodynamics: Textbook.|publisher=Lan publishing house|year=2010|isbn=978-5-8114-1003-3|location=St. Petersburg|page=384}} 5th ed. (in Russian) | |||
* {{cite book|author=Bawendi Moungi G., Alberty Robert A. and Silbey Robert J.|title=Physical Chemistry|publisher=J. Wiley & Sons, Incorporated|year=2004}} | |||
* {{cite book|author=Alberty Robert A.|title=Thermodynamics of Biochemical Reactions|publisher=Wiley-Interscience|year=2003}} | |||
* {{cite book|author=Alberty Robert A.|title=Biochemical Thermodynamics: Applications of Mathematica|journal=Methods of Biochemical Analysis|publisher=John Wiley & Sons, Inc.|year=2006|volume=48|pages=1–458|pmid=16878778|isbn=978-0-471-75798-6}} | |||
* {{cite book|author=Dill Ken A., Bromberg Sarina|title=Molecular Driving Forces: Statistical Thermodynamics in Biology, Chemistry, Physics, and Nanoscience |publisher=Garland Science|year=2011|isbn=978-0-8153-4430-8}} | |||
* {{cite book|author=M. Scott Shell|title=Thermodynamics and Statistical Mechanics: An Integrated Approach|publisher=Cambridge University Press|year=2015|isbn=978-1107656789}} | |||
* {{cite book|author=Douglas E. Barrick|title=Biomolecular Thermodynamics: From Theory to Applications|publisher=CRC Press|year=2018|isbn=978-1-4398-0019-5}} | |||
The following titles are more technical: | |||
* {{Cite book|title=Advanced Engineering Thermodynamics|last=Bejan|first=Adrian|publisher=Wiley|year=2016|isbn=978-1-119-05209-8|edition=4}} | |||
* {{cite book|author=Cengel, Yunus A., & Boles, Michael A.|title=Thermodynamics – an Engineering Approach|publisher=McGraw Hill|year=2002|isbn=978-0-07-238332-4|oclc=45791449|url-access=registration|url=https://archive.org/details/thermodynamicsen00ceng_0}} | |||
* {{cite book|author=Dunning-Davies, Jeremy|title=Concise Thermodynamics: Principles and Applications|publisher=Horwood Publishing|year=1997|isbn=978-1-8985-6315-0|oclc=36025958}} | |||
* {{cite book|author1=Kroemer, Herbert|author2=Kittel, Charles|name-list-style=amp|title=Thermal Physics|publisher=W.H. Freeman Company|year=1980|isbn=978-0-7167-1088-2|oclc=32932988}} | |||
== External links == | == External links == | ||
*{{Commons category-inline}} | |||
* | |||
{{Wikibooks|Engineering Thermodynamics}} | |||
{{wikiquote|Thermodynamics}} | |||
* {{cite EB1911 |first=Hugh Longbourne |last=Callendar |wstitle=Thermodynamics |volume=26 |pages=808–814 |short=x}} | |||
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* | * | ||
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=== Laws === | |||
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* by Richard Fitzpatrick | |||
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Latest revision as of 02:19, 23 December 2024
Physics of heat, work, and temperature
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Material properties
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Thermodynamics is a branch of physics that deals with heat, work, and temperature, and their relation to energy, entropy, and the physical properties of matter and radiation. The behavior of these quantities is governed by the four laws of thermodynamics, which convey a quantitative description using measurable macroscopic physical quantities, but may be explained in terms of microscopic constituents by statistical mechanics. Thermodynamics applies to a wide variety of topics in science and engineering, especially physical chemistry, biochemistry, chemical engineering and mechanical engineering, but also in other complex fields such as meteorology.
Historically, thermodynamics developed out of a desire to increase the efficiency of early steam engines, particularly through the work of French physicist Sadi Carnot (1824) who believed that engine efficiency was the key that could help France win the Napoleonic Wars. Scots-Irish physicist Lord Kelvin was the first to formulate a concise definition of thermodynamics in 1854 which stated, "Thermo-dynamics is the subject of the relation of heat to forces acting between contiguous parts of bodies, and the relation of heat to electrical agency." German physicist and mathematician Rudolf Clausius restated Carnot's principle known as the Carnot cycle and gave to the theory of heat a truer and sounder basis. His most important paper, "On the Moving Force of Heat", published in 1850, first stated the second law of thermodynamics. In 1865 he introduced the concept of entropy. In 1870 he introduced the virial theorem, which applied to heat.
The initial application of thermodynamics to mechanical heat engines was quickly extended to the study of chemical compounds and chemical reactions. Chemical thermodynamics studies the nature of the role of entropy in the process of chemical reactions and has provided the bulk of expansion and knowledge of the field. Other formulations of thermodynamics emerged. Statistical thermodynamics, or statistical mechanics, concerns itself with statistical predictions of the collective motion of particles from their microscopic behavior. In 1909, Constantin Carathéodory presented a purely mathematical approach in an axiomatic formulation, a description often referred to as geometrical thermodynamics.
Introduction
A description of any thermodynamic system employs the four laws of thermodynamics that form an axiomatic basis. The first law specifies that energy can be transferred between physical systems as heat, as work, and with transfer of matter. The second law defines the existence of a quantity called entropy, that describes the direction, thermodynamically, that a system can evolve and quantifies the state of order of a system and that can be used to quantify the useful work that can be extracted from the system.
In thermodynamics, interactions between large ensembles of objects are studied and categorized. Central to this are the concepts of the thermodynamic system and its surroundings. A system is composed of particles, whose average motions define its properties, and those properties are in turn related to one another through equations of state. Properties can be combined to express internal energy and thermodynamic potentials, which are useful for determining conditions for equilibrium and spontaneous processes.
With these tools, thermodynamics can be used to describe how systems respond to changes in their environment. This can be applied to a wide variety of topics in science and engineering, such as engines, phase transitions, chemical reactions, transport phenomena, and even black holes. The results of thermodynamics are essential for other fields of physics and for chemistry, chemical engineering, corrosion engineering, aerospace engineering, mechanical engineering, cell biology, biomedical engineering, materials science, and economics, to name a few.
This article is focused mainly on classical thermodynamics which primarily studies systems in thermodynamic equilibrium. Non-equilibrium thermodynamics is often treated as an extension of the classical treatment, but statistical mechanics has brought many advances to that field.
History
The history of thermodynamics as a scientific discipline generally begins with Otto von Guericke who, in 1650, built and designed the world's first vacuum pump and demonstrated a vacuum using his Magdeburg hemispheres. Guericke was driven to make a vacuum in order to disprove Aristotle's long-held supposition that 'nature abhors a vacuum'. Shortly after Guericke, the Anglo-Irish physicist and chemist Robert Boyle had learned of Guericke's designs and, in 1656, in coordination with English scientist Robert Hooke, built an air pump. Using this pump, Boyle and Hooke noticed a correlation between pressure, temperature, and volume. In time, Boyle's Law was formulated, which states that pressure and volume are inversely proportional. Then, in 1679, based on these concepts, an associate of Boyle's named Denis Papin built a steam digester, which was a closed vessel with a tightly fitting lid that confined steam until a high pressure was generated.
Later designs implemented a steam release valve that kept the machine from exploding. By watching the valve rhythmically move up and down, Papin conceived of the idea of a piston and a cylinder engine. He did not, however, follow through with his design. Nevertheless, in 1697, based on Papin's designs, engineer Thomas Savery built the first engine, followed by Thomas Newcomen in 1712. Although these early engines were crude and inefficient, they attracted the attention of the leading scientists of the time.
The fundamental concepts of heat capacity and latent heat, which were necessary for the development of thermodynamics, were developed by Professor Joseph Black at the University of Glasgow, where James Watt was employed as an instrument maker. Black and Watt performed experiments together, but it was Watt who conceived the idea of the external condenser which resulted in a large increase in steam engine efficiency. Drawing on all the previous work led Sadi Carnot, the "father of thermodynamics", to publish Reflections on the Motive Power of Fire (1824), a discourse on heat, power, energy and engine efficiency. The book outlined the basic energetic relations between the Carnot engine, the Carnot cycle, and motive power. It marked the start of thermodynamics as a modern science.
The first thermodynamic textbook was written in 1859 by William Rankine, originally trained as a physicist and a civil and mechanical engineering professor at the University of Glasgow. The first and second laws of thermodynamics emerged simultaneously in the 1850s, primarily out of the works of William Rankine, Rudolf Clausius, and William Thomson (Lord Kelvin). The foundations of statistical thermodynamics were set out by physicists such as James Clerk Maxwell, Ludwig Boltzmann, Max Planck, Rudolf Clausius and J. Willard Gibbs.
Clausius, who first stated the basic ideas of the second law in his paper "On the Moving Force of Heat", published in 1850, and is called "one of the founding fathers of thermodynamics", introduced the concept of entropy in 1865.
During the years 1873–76 the American mathematical physicist Josiah Willard Gibbs published a series of three papers, the most famous being On the Equilibrium of Heterogeneous Substances, in which he showed how thermodynamic processes, including chemical reactions, could be graphically analyzed, by studying the energy, entropy, volume, temperature and pressure of the thermodynamic system in such a manner, one can determine if a process would occur spontaneously. Also Pierre Duhem in the 19th century wrote about chemical thermodynamics. During the early 20th century, chemists such as Gilbert N. Lewis, Merle Randall, and E. A. Guggenheim applied the mathematical methods of Gibbs to the analysis of chemical processes.
Etymology
Thermodynamics has an intricate etymology.
By a surface-level analysis, the word consists of two parts that can be traced back to Ancient Greek. Firstly, thermo- ("of heat"; used in words such as thermometer) can be traced back to the root θέρμη therme, meaning "heat". Secondly, the word dynamics ("science of force ") can be traced back to the root δύναμις dynamis, meaning "power".
In 1849, the adjective thermo-dynamic is used by William Thomson.
In 1854, the noun thermo-dynamics is used by Thomson and William Rankine to represent the science of generalized heat engines.
Pierre Perrot claims that the term thermodynamics was coined by James Joule in 1858 to designate the science of relations between heat and power, however, Joule never used that term, but used instead the term perfect thermo-dynamic engine in reference to Thomson's 1849 phraseology.
Branches of thermodynamics
The study of thermodynamical systems has developed into several related branches, each using a different fundamental model as a theoretical or experimental basis, or applying the principles to varying types of systems.
Classical thermodynamics
Classical thermodynamics is the description of the states of thermodynamic systems at near-equilibrium, that uses macroscopic, measurable properties. It is used to model exchanges of energy, work and heat based on the laws of thermodynamics. The qualifier classical reflects the fact that it represents the first level of understanding of the subject as it developed in the 19th century and describes the changes of a system in terms of macroscopic empirical (large scale, and measurable) parameters. A microscopic interpretation of these concepts was later provided by the development of statistical mechanics.
Statistical mechanics
Statistical mechanics, also known as statistical thermodynamics, emerged with the development of atomic and molecular theories in the late 19th century and early 20th century, and supplemented classical thermodynamics with an interpretation of the microscopic interactions between individual particles or quantum-mechanical states. This field relates the microscopic properties of individual atoms and molecules to the macroscopic, bulk properties of materials that can be observed on the human scale, thereby explaining classical thermodynamics as a natural result of statistics, classical mechanics, and quantum theory at the microscopic level.
Chemical thermodynamics
Chemical thermodynamics is the study of the interrelation of energy with chemical reactions or with a physical change of state within the confines of the laws of thermodynamics. The primary objective of chemical thermodynamics is determining the spontaneity of a given transformation.
Equilibrium thermodynamics
Equilibrium thermodynamics is the study of transfers of matter and energy in systems or bodies that, by agencies in their surroundings, can be driven from one state of thermodynamic equilibrium to another. The term 'thermodynamic equilibrium' indicates a state of balance, in which all macroscopic flows are zero; in the case of the simplest systems or bodies, their intensive properties are homogeneous, and their pressures are perpendicular to their boundaries. In an equilibrium state there are no unbalanced potentials, or driving forces, between macroscopically distinct parts of the system. A central aim in equilibrium thermodynamics is: given a system in a well-defined initial equilibrium state, and given its surroundings, and given its constitutive walls, to calculate what will be the final equilibrium state of the system after a specified thermodynamic operation has changed its walls or surroundings.
Non-equilibrium thermodynamics
Non-equilibrium thermodynamics is a branch of thermodynamics that deals with systems that are not in thermodynamic equilibrium. Most systems found in nature are not in thermodynamic equilibrium because they are not in stationary states, and are continuously and discontinuously subject to flux of matter and energy to and from other systems. The thermodynamic study of non-equilibrium systems requires more general concepts than are dealt with by equilibrium thermodynamics. Many natural systems still today remain beyond the scope of currently known macroscopic thermodynamic methods.
Laws of thermodynamics
Main article: Laws of thermodynamicsThermodynamics is principally based on a set of four laws which are universally valid when applied to systems that fall within the constraints implied by each. In the various theoretical descriptions of thermodynamics these laws may be expressed in seemingly differing forms, but the most prominent formulations are the following.
Zeroth law
The zeroth law of thermodynamics states: If two systems are each in thermal equilibrium with a third, they are also in thermal equilibrium with each other.
This statement implies that thermal equilibrium is an equivalence relation on the set of thermodynamic systems under consideration. Systems are said to be in equilibrium if the small, random exchanges between them (e.g. Brownian motion) do not lead to a net change in energy. This law is tacitly assumed in every measurement of temperature. Thus, if one seeks to decide whether two bodies are at the same temperature, it is not necessary to bring them into contact and measure any changes of their observable properties in time. The law provides an empirical definition of temperature, and justification for the construction of practical thermometers.
The zeroth law was not initially recognized as a separate law of thermodynamics, as its basis in thermodynamical equilibrium was implied in the other laws. The first, second, and third laws had been explicitly stated already, and found common acceptance in the physics community before the importance of the zeroth law for the definition of temperature was realized. As it was impractical to renumber the other laws, it was named the zeroth law.
First law
The first law of thermodynamics states: In a process without transfer of matter, the change in internal energy, , of a thermodynamic system is equal to the energy gained as heat, , less the thermodynamic work, , done by the system on its surroundings.
- .
where denotes the change in the internal energy of a closed system (for which heat or work through the system boundary are possible, but matter transfer is not possible), denotes the quantity of energy supplied to the system as heat, and denotes the amount of thermodynamic work done by the system on its surroundings. An equivalent statement is that perpetual motion machines of the first kind are impossible; work done by a system on its surrounding requires that the system's internal energy decrease or be consumed, so that the amount of internal energy lost by that work must be resupplied as heat by an external energy source or as work by an external machine acting on the system (so that is recovered) to make the system work continuously.
For processes that include transfer of matter, a further statement is needed: With due account of the respective fiducial reference states of the systems, when two systems, which may be of different chemical compositions, initially separated only by an impermeable wall, and otherwise isolated, are combined into a new system by the thermodynamic operation of removal of the wall, then
- ,
where U0 denotes the internal energy of the combined system, and U1 and U2 denote the internal energies of the respective separated systems.
Adapted for thermodynamics, this law is an expression of the principle of conservation of energy, which states that energy can be transformed (changed from one form to another), but cannot be created or destroyed.
Internal energy is a principal property of the thermodynamic state, while heat and work are modes of energy transfer by which a process may change this state. A change of internal energy of a system may be achieved by any combination of heat added or removed and work performed on or by the system. As a function of state, the internal energy does not depend on the manner, or on the path through intermediate steps, by which the system arrived at its state.
Second law
A traditional version of the second law of thermodynamics states: Heat does not spontaneously flow from a colder body to a hotter body.
The second law refers to a system of matter and radiation, initially with inhomogeneities in temperature, pressure, chemical potential, and other intensive properties, that are due to internal 'constraints', or impermeable rigid walls, within it, or to externally imposed forces. The law observes that, when the system is isolated from the outside world and from those forces, there is a definite thermodynamic quantity, its entropy, that increases as the constraints are removed, eventually reaching a maximum value at thermodynamic equilibrium, when the inhomogeneities practically vanish. For systems that are initially far from thermodynamic equilibrium, though several have been proposed, there is known no general physical principle that determines the rates of approach to thermodynamic equilibrium, and thermodynamics does not deal with such rates. The many versions of the second law all express the general irreversibility of the transitions involved in systems approaching thermodynamic equilibrium.
In macroscopic thermodynamics, the second law is a basic observation applicable to any actual thermodynamic process; in statistical thermodynamics, the second law is postulated to be a consequence of molecular chaos.
Third law
The third law of thermodynamics states: As the temperature of a system approaches absolute zero, all processes cease and the entropy of the system approaches a minimum value.
This law of thermodynamics is a statistical law of nature regarding entropy and the impossibility of reaching absolute zero of temperature. This law provides an absolute reference point for the determination of entropy. The entropy determined relative to this point is the absolute entropy. Alternate definitions include "the entropy of all systems and of all states of a system is smallest at absolute zero," or equivalently "it is impossible to reach the absolute zero of temperature by any finite number of processes".
Absolute zero, at which all activity would stop if it were possible to achieve, is −273.15 °C (degrees Celsius), or −459.67 °F (degrees Fahrenheit), or 0 K (kelvin), or 0° R (degrees Rankine).
System models
An important concept in thermodynamics is the thermodynamic system, which is a precisely defined region of the universe under study. Everything in the universe except the system is called the surroundings. A system is separated from the remainder of the universe by a boundary which may be a physical or notional, but serve to confine the system to a finite volume. Segments of the boundary are often described as walls; they have respective defined 'permeabilities'. Transfers of energy as work, or as heat, or of matter, between the system and the surroundings, take place through the walls, according to their respective permeabilities.
Matter or energy that pass across the boundary so as to effect a change in the internal energy of the system need to be accounted for in the energy balance equation. The volume contained by the walls can be the region surrounding a single atom resonating energy, such as Max Planck defined in 1900; it can be a body of steam or air in a steam engine, such as Sadi Carnot defined in 1824. The system could also be just one nuclide (i.e. a system of quarks) as hypothesized in quantum thermodynamics. When a looser viewpoint is adopted, and the requirement of thermodynamic equilibrium is dropped, the system can be the body of a tropical cyclone, such as Kerry Emanuel theorized in 1986 in the field of atmospheric thermodynamics, or the event horizon of a black hole.
Boundaries are of four types: fixed, movable, real, and imaginary. For example, in an engine, a fixed boundary means the piston is locked at its position, within which a constant volume process might occur. If the piston is allowed to move that boundary is movable while the cylinder and cylinder head boundaries are fixed. For closed systems, boundaries are real while for open systems boundaries are often imaginary. In the case of a jet engine, a fixed imaginary boundary might be assumed at the intake of the engine, fixed boundaries along the surface of the case and a second fixed imaginary boundary across the exhaust nozzle.
Generally, thermodynamics distinguishes three classes of systems, defined in terms of what is allowed to cross their boundaries:
Type of system | Mass flow | Work | Heat |
---|---|---|---|
Open | Y | Y | Y |
Closed | N | Y | Y |
Thermally isolated | N | Y | N |
Mechanically isolated | N | N | Y |
Isolated | N | N | N |
As time passes in an isolated system, internal differences of pressures, densities, and temperatures tend to even out. A system in which all equalizing processes have gone to completion is said to be in a state of thermodynamic equilibrium.
Once in thermodynamic equilibrium, a system's properties are, by definition, unchanging in time. Systems in equilibrium are much simpler and easier to understand than are systems which are not in equilibrium. Often, when analysing a dynamic thermodynamic process, the simplifying assumption is made that each intermediate state in the process is at equilibrium, producing thermodynamic processes which develop so slowly as to allow each intermediate step to be an equilibrium state and are said to be reversible processes.
States and processes
When a system is at equilibrium under a given set of conditions, it is said to be in a definite thermodynamic state. The state of the system can be described by a number of state quantities that do not depend on the process by which the system arrived at its state. They are called intensive variables or extensive variables according to how they change when the size of the system changes. The properties of the system can be described by an equation of state which specifies the relationship between these variables. State may be thought of as the instantaneous quantitative description of a system with a set number of variables held constant.
A thermodynamic process may be defined as the energetic evolution of a thermodynamic system proceeding from an initial state to a final state. It can be described by process quantities. Typically, each thermodynamic process is distinguished from other processes in energetic character according to what parameters, such as temperature, pressure, or volume, etc., are held fixed; Furthermore, it is useful to group these processes into pairs, in which each variable held constant is one member of a conjugate pair.
Several commonly studied thermodynamic processes are:
- Adiabatic process: occurs without loss or gain of energy by heat
- Isenthalpic process: occurs at a constant enthalpy
- Isentropic process: a reversible adiabatic process, occurs at a constant entropy
- Isobaric process: occurs at constant pressure
- Isochoric process: occurs at constant volume (also called isometric/isovolumetric)
- Isothermal process: occurs at a constant temperature
- Steady state process: occurs without a change in the internal energy
Instrumentation
There are two types of thermodynamic instruments, the meter and the reservoir. A thermodynamic meter is any device which measures any parameter of a thermodynamic system. In some cases, the thermodynamic parameter is actually defined in terms of an idealized measuring instrument. For example, the zeroth law states that if two bodies are in thermal equilibrium with a third body, they are also in thermal equilibrium with each other. This principle, as noted by James Maxwell in 1872, asserts that it is possible to measure temperature. An idealized thermometer is a sample of an ideal gas at constant pressure. From the ideal gas law pV=nRT, the volume of such a sample can be used as an indicator of temperature; in this manner it defines temperature. Although pressure is defined mechanically, a pressure-measuring device, called a barometer may also be constructed from a sample of an ideal gas held at a constant temperature. A calorimeter is a device which is used to measure and define the internal energy of a system.
A thermodynamic reservoir is a system which is so large that its state parameters are not appreciably altered when it is brought into contact with the system of interest. When the reservoir is brought into contact with the system, the system is brought into equilibrium with the reservoir. For example, a pressure reservoir is a system at a particular pressure, which imposes that pressure upon the system to which it is mechanically connected. The Earth's atmosphere is often used as a pressure reservoir. The ocean can act as temperature reservoir when used to cool power plants.
Conjugate variables
Main article: Conjugate variablesThe central concept of thermodynamics is that of energy, the ability to do work. By the First Law, the total energy of a system and its surroundings is conserved. Energy may be transferred into a system by heating, compression, or addition of matter, and extracted from a system by cooling, expansion, or extraction of matter. In mechanics, for example, energy transfer equals the product of the force applied to a body and the resulting displacement.
Conjugate variables are pairs of thermodynamic concepts, with the first being akin to a "force" applied to some thermodynamic system, the second being akin to the resulting "displacement", and the product of the two equaling the amount of energy transferred. The common conjugate variables are:
- Pressure-volume (the mechanical parameters);
- Temperature-entropy (thermal parameters);
- Chemical potential-particle number (material parameters).
Potentials
Thermodynamic potentials are different quantitative measures of the stored energy in a system. Potentials are used to measure the energy changes in systems as they evolve from an initial state to a final state. The potential used depends on the constraints of the system, such as constant temperature or pressure. For example, the Helmholtz and Gibbs energies are the energies available in a system to do useful work when the temperature and volume or the pressure and temperature are fixed, respectively. Thermodynamic potentials cannot be measured in laboratories, but can be computed using molecular thermodynamics.
The five most well known potentials are:
Name | Symbol | Formula | Natural variables |
---|---|---|---|
Internal energy | |||
Helmholtz free energy | |||
Enthalpy | |||
Gibbs free energy | |||
Landau potential, or grand potential |
, |
where is the temperature, the entropy, the pressure, the volume, the chemical potential, the number of particles in the system, and is the count of particles types in the system.
Thermodynamic potentials can be derived from the energy balance equation applied to a thermodynamic system. Other thermodynamic potentials can also be obtained through Legendre transformation.
Axiomatic thermodynamics
Axiomatic thermodynamics is a mathematical discipline that aims to describe thermodynamics in terms of rigorous axioms, for example by finding a mathematically rigorous way to express the familiar laws of thermodynamics.
The first attempt at an axiomatic theory of thermodynamics was Constantin Carathéodory's 1909 work Investigations on the Foundations of Thermodynamics, which made use of Pfaffian systems and the concept of adiabatic accessibility, a notion that was introduced by Carathéodory himself. In this formulation, thermodynamic concepts such as heat, entropy, and temperature are derived from quantities that are more directly measurable. Theories that came after, differed in the sense that they made assumptions regarding thermodynamic processes with arbitrary initial and final states, as opposed to considering only neighboring states.
Applied fields
- Atmospheric thermodynamics
- Biological thermodynamics
- Black hole thermodynamics
- Chemical thermodynamics
- Classical thermodynamics
- Equilibrium thermodynamics
- Industrial ecology (re: Exergy)
- Maximum entropy thermodynamics
- Non-equilibrium thermodynamics
- Philosophy of thermal and statistical physics
- Psychrometrics
- Quantum thermodynamics
- Statistical thermodynamics, i.e. Statistical mechanics
- Thermoeconomics
- Polymer chemistry
See also
Lists and timelines
- List of important publications in thermodynamics
- List of textbooks on thermodynamics and statistical mechanics
- List of thermal conductivities
- List of thermodynamic properties
- Table of thermodynamic equations
- Timeline of thermodynamics
- Thermodynamic equations
Notes
- The sign convention (Q is heat supplied to the system as, W is work done by the system) is that of Rudolf Clausius. The opposite sign convention is customary in chemical thermodynamics.
References
- Clausius, Rudolf (1850). On the Motive Power of Heat, and on the Laws which can be deduced from it for the Theory of Heat. Poggendorff's Annalen der Physik, LXXIX (Dover Reprint). ISBN 978-0-486-59065-3.
- William Thomson, LL.D. D.C.L., F.R.S. (1882). Mathematical and Physical Papers. Vol. 1. London, Cambridge: C.J. Clay, M.A. & Son, Cambridge University Press. p. 232. ISBN 978-0-598-96004-7. Archived from the original on 18 April 2021. Retrieved 2 November 2020.
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: CS1 maint: multiple names: authors list (link) - ^ Clausius, R. (1867). The Mechanical Theory of Heat – with its Applications to the Steam Engine and to Physical Properties of Bodies. London: John van Voorst. Retrieved 19 June 2012.
editions:PwR_Sbkwa8IC.
Contains English translations of many of his other works. - Clausius, RJE (1870). "On a Mechanical Theorem Applicable to Heat". Philosophical Magazine. 4th Series. 40: 122–127.
- Van Ness, H.C. (1983) . Understanding Thermodynamics. Dover Publications, Inc. ISBN 9780486632773. OCLC 8846081.
- Dugdale, J.S. (1998). Entropy and its Physical Meaning. Taylor and Francis. ISBN 978-0-7484-0569-5. OCLC 36457809.
- Smith, J.M.; Van Ness, H.C.; Abbott, M.M. (2005). Introduction to Chemical Engineering Thermodynamics (PDF). Vol. 27 (7th ed.). p. 584. Bibcode:1950JChEd..27..584S. doi:10.1021/ed027p584.3. ISBN 978-0-07-310445-4. OCLC 56491111.
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ignored (help) - Haynie, Donald T. (2001). Biological Thermodynamics. Cambridge University Press. ISBN 978-0-521-79549-4. OCLC 43993556.
- Schools of thermodynamics Archived 7 December 2017 at the Wayback Machine – EoHT.info.
- Partington, J.R. (1989). A Short History of Chemistry. Dover. OCLC 19353301.
- The Newcomen engine was improved from 1711 until Watt's work, making the efficiency comparison subject to qualification, but the increase from the 1865 version was on the order of 100%.
- ^ Perrot, Pierre (1998). A to Z of Thermodynamics. Oxford University Press. ISBN 978-0-19-856552-9. OCLC 123283342.
- Cengel, Yunus A.; Boles, Michael A. (2005). Thermodynamics – an Engineering Approach. McGraw-Hill. ISBN 978-0-07-310768-4.
- Cardwell, D.S.L. (1971), From Watt to Clausius: The Rise of Thermodynamics in the Early Industrial Age, London: Heinemann, ISBN 978-0-435-54150-7
- Gibbs, Willard, J. (1874–1878). Transactions of the Connecticut Academy of Arts and Sciences. Vol. III. New Haven. pp. 108–248, 343–524.
{{cite book}}
: CS1 maint: multiple names: authors list (link) - Gibbs, Willard (1993). The Scientific Papers of J. Willard Gibbs, Volume One: Thermodynamics. Ox Bow Press. ISBN 978-0-918024-77-0. OCLC 27974820.
- Duhem, P.M.M. (1886). Le Potential Thermodynamique et ses Applications, Hermann, Paris.
- Lewis, Gilbert N.; Randall, Merle (1923). Thermodynamics and the Free Energy of Chemical Substances. McGraw-Hill Book Co. Inc.
- Guggenheim, E.A. (1933). Modern Thermodynamics by the Methods of J.W. Gibbs, Methuen, London.
- Guggenheim, E.A. (1949/1967). Thermodynamics. An Advanced Treatment for Chemists and Physicists, 1st edition 1949, 5th edition 1967, North-Holland, Amsterdam.
- ^ "Thermodynamics (etymology)". EoHT.info. Archived from the original on 29 October 2023. Retrieved 29 October 2023.
- Thompson, Silvanus (1910). The Life of William Thomson, Baron Kelvin of Largs. Vol. 1. MacMillan and Co., Limited. p. 241.
the fundamental subject of Natural Philosophy is Dynamics, or the science of force .... Every phenomenon in nature is a manifestation of force.
- Donald T. Haynie (2008). Biological Thermodynamics (2 ed.). Cambridge University Press. p. 26.
- ^ Kelvin, William T. (1849) "An Account of Carnot's Theory of the Motive Power of Heat – with Numerical Results Deduced from Regnault's Experiments on Steam." Transactions of the Edinburg Royal Society, XVI. January 2.Scanned Copy Archived 24 July 2017 at the Wayback Machine
- ^ Smith, Crosbie W. (1977). "William Thomson and the Creation of Thermodynamics: 1840-1855". Archive for History of Exact Sciences. 16 (3): 231–288. doi:10.1007/BF00328156. ISSN 0003-9519. JSTOR 41133471. S2CID 36609995.
- Klotz, Irving (2008). Chemical Thermodynamics: Basic Theory and Methods. Hoboken, New Jersey: John Wiley & Sons, Inc. p. 4. ISBN 978-0-471-78015-1.
- Pokrovskii, Vladimir (2020). Thermodynamics of Complex Systems: Principles and applications. IOP Publishing, Bristol, UK. Bibcode:2020tcsp.book.....P.
- Moran, Michael J. and Howard N. Shapiro, 2008. Fundamentals of Engineering Thermodynamics. 6th ed. Wiley and Sons: 16.
- "Sparkling Wine, Champagne & Co - Part 2". Sparkling Wine, Champagne & Co. Chemistry Europe (chemistryviews.org). 17 December 2010. Retrieved 17 April 2023.
- Klaus Roth: Sekt, Champagner & Co. So prickelnd kann Chemie sein in Chemie unserer Zeit 8. Dezember 2009: Vol. 43, Issue 6, S. 418-432 doi:10.1002/ciuz.200900520
- Klaus Roth: Chemische Köstlichkeiten, Wiley-VCH Verlag GmbH & Co. KGaA, 2010, ISBN 978-3527327522, S. 47
- Bailyn, M. (1994). A Survey of Thermodynamics, American Institute of Physics, AIP Press, Woodbury NY, ISBN 0883187973, p. 79.
- Callen, H.B. (1960/1985).Thermodynamics and an Introduction to Thermostatistics, second edition, John Wiley & Sons, Hoboken NY, ISBN 9780471862567, pp. 11–13.
- Graben, H.W.; Ray, John R. (10 December 1993). "Eight physical systems of thermodynamics, statistical mechanics, and computer simulations". Molecular Physics. 80 (5): 1183–1193. Bibcode:1993MolPh..80.1183G. doi:10.1080/00268979300102971. ISSN 0026-8976.
- Nitzke, Isabel; Stephan, Simon; Vrabec, Jadran (3 June 2024). "Topology of thermodynamic potentials using physical models: Helmholtz, Gibbs, Grand, and Null". The Journal of Chemical Physics. 160 (21). Bibcode:2024JChPh.160u4104N. doi:10.1063/5.0207592. ISSN 0021-9606. PMID 38828811.
- Carathéodory, C. (1909). "Untersuchungen über die Grundlagen der Thermodynamik". Mathematische Annalen (in German). 67 (3): 355–386. doi:10.1007/BF01450409. ISSN 0025-5831. S2CID 118230148.
- Frankel, Theodore (2004). The Geometry of Physics: An Introduction (second ed.). Cambridge University Press. ISBN 9780521539272.
- Rastall, Peter (1 October 1970). "Classical Thermodynamics Simplified". Journal of Mathematical Physics. 11 (10): 2955–2965. Bibcode:1970JMP....11.2955R. doi:10.1063/1.1665080. ISSN 0022-2488.
Further reading
- Goldstein, Martin & Inge F. (1993). The Refrigerator and the Universe. Harvard University Press. ISBN 978-0-674-75325-9. OCLC 32826343. A nontechnical introduction, good on historical and interpretive matters.
- Kazakov, Andrei; Muzny, Chris D.; Chirico, Robert D.; Diky, Vladimir V.; Frenkel, Michael (2008). "Web Thermo Tables – an On-Line Version of the TRC Thermodynamic Tables". Journal of Research of the National Institute of Standards and Technology. 113 (4): 209–220. doi:10.6028/jres.113.016. ISSN 1044-677X. PMC 4651616. PMID 27096122.
- Gibbs J.W. (1928). The Collected Works of J. Willard Gibbs Thermodynamics. New York: Longmans, Green and Co. Vol. 1, pp. 55–349.
- Guggenheim E.A. (1933). Modern thermodynamics by the methods of Willard Gibbs. London: Methuen & co. ltd.
- Denbigh K. (1981). The Principles of Chemical Equilibrium: With Applications in Chemistry and Chemical Engineering. London: Cambridge University Press.
- Stull, D.R., Westrum Jr., E.F. and Sinke, G.C. (1969). The Chemical Thermodynamics of Organic Compounds. London: John Wiley and Sons, Inc.
{{cite book}}
: CS1 maint: multiple names: authors list (link) - Bazarov I.P. (2010). Thermodynamics: Textbook. St. Petersburg: Lan publishing house. p. 384. ISBN 978-5-8114-1003-3. 5th ed. (in Russian)
- Bawendi Moungi G., Alberty Robert A. and Silbey Robert J. (2004). Physical Chemistry. J. Wiley & Sons, Incorporated.
- Alberty Robert A. (2003). Thermodynamics of Biochemical Reactions. Wiley-Interscience.
- Alberty Robert A. (2006). Biochemical Thermodynamics: Applications of Mathematica. Vol. 48. John Wiley & Sons, Inc. pp. 1–458. ISBN 978-0-471-75798-6. PMID 16878778.
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ignored (help) - Dill Ken A., Bromberg Sarina (2011). Molecular Driving Forces: Statistical Thermodynamics in Biology, Chemistry, Physics, and Nanoscience. Garland Science. ISBN 978-0-8153-4430-8.
- M. Scott Shell (2015). Thermodynamics and Statistical Mechanics: An Integrated Approach. Cambridge University Press. ISBN 978-1107656789.
- Douglas E. Barrick (2018). Biomolecular Thermodynamics: From Theory to Applications. CRC Press. ISBN 978-1-4398-0019-5.
The following titles are more technical:
- Bejan, Adrian (2016). Advanced Engineering Thermodynamics (4 ed.). Wiley. ISBN 978-1-119-05209-8.
- Cengel, Yunus A., & Boles, Michael A. (2002). Thermodynamics – an Engineering Approach. McGraw Hill. ISBN 978-0-07-238332-4. OCLC 45791449.
{{cite book}}
: CS1 maint: multiple names: authors list (link) - Dunning-Davies, Jeremy (1997). Concise Thermodynamics: Principles and Applications. Horwood Publishing. ISBN 978-1-8985-6315-0. OCLC 36025958.
- Kroemer, Herbert & Kittel, Charles (1980). Thermal Physics. W.H. Freeman Company. ISBN 978-0-7167-1088-2. OCLC 32932988.
External links
- Media related to Thermodynamics at Wikimedia Commons
- Callendar, Hugh Longbourne (1911). "Thermodynamics" . Encyclopædia Britannica. Vol. 26 (11th ed.). pp. 808–814.
- Thermodynamics Data & Property Calculation Websites
- Thermodynamics Educational Websites
- Biochemistry Thermodynamics
- Thermodynamics and Statistical Mechanics
- Engineering Thermodynamics – A Graphical Approach
- Thermodynamics and Statistical Mechanics by Richard Fitzpatrick
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