Find link

language: af: Afrikaans als: Alemannisch [Alemannic] am: አማርኛ [Amharic] an: aragonés [Aragonese] ar: العربية [Arabic] arz: مصرى [Egyptian Arabic] as: অসমীয়া [Assamese] ast: asturianu [Asturian] az: azərbaycanca [Azerbaijani] azb: تۆرکجه [Southern Azerbaijani] ba: башҡортса [Bashkir] bar: Boarisch [Bavarian] bat-smg: žemaitėška [Samogitian] be: беларуская [Belarusian] be-tarask: беларуская (тарашкевіца) [Belarusian (Taraškievica)] bg: български [Bulgarian] bn: বাংলা [Bengali] bpy: বিষ্ণুপ্রিয়া মণিপুরী [Bishnupriya Manipuri] br: brezhoneg [Breton] bs: bosanski [Bosnian] bug: ᨅᨔ ᨕᨘᨁᨗ [Buginese] ca: català [Catalan] ce: нохчийн [Chechen] ceb: Cebuano ckb: کوردیی ناوەندی [Kurdish (Sorani)] cs: čeština [Czech] cv: Чӑвашла [Chuvash] cy: Cymraeg [Welsh] da: dansk [Danish] de: Deutsch [German] el: Ελληνικά [Greek] en: English eo: Esperanto es: español [Spanish] et: eesti [Estonian] eu: euskara [Basque] fa: فارسی [Persian] fi: suomi [Finnish] fo: føroyskt [Faroese] fr: français [French] fy: Frysk [West Frisian] ga: Gaeilge [Irish] gd: Gàidhlig [Scottish Gaelic] gl: galego [Galician] gu: ગુજરાતી [Gujarati] he: עברית [Hebrew] hi: हिन्दी [Hindi] hr: hrvatski [Croatian] hsb: hornjoserbsce [Upper Sorbian] ht: Kreyòl ayisyen [Haitian] hu: magyar [Hungarian] hy: Հայերեն [Armenian] ia: interlingua [Interlingua] id: Bahasa Indonesia [Indonesian] io: Ido is: íslenska [Icelandic] it: italiano [Italian] ja: 日本語 [Japanese] jv: Basa Jawa [Javanese] ka: ქართული [Georgian] kk: қазақша [Kazakh] kn: ಕನ್ನಡ [Kannada] ko: 한국어 [Korean] ku: Kurdî [Kurdish (Kurmanji)] ky: Кыргызча [Kirghiz] la: Latina [Latin] lb: Lëtzebuergesch [Luxembourgish] li: Limburgs [Limburgish] lmo: lumbaart [Lombard] lt: lietuvių [Lithuanian] lv: latviešu [Latvian] map-bms: Basa Banyumasan [Banyumasan] mg: Malagasy min: Baso Minangkabau [Minangkabau] mk: македонски [Macedonian] ml: മലയാളം [Malayalam] mn: монгол [Mongolian] mr: मराठी [Marathi] mrj: кырык мары [Hill Mari] ms: Bahasa Melayu [Malay] my: မြန်မာဘာသာ [Burmese] mzn: مازِرونی [Mazandarani] nah: Nāhuatl [Nahuatl] nap: Napulitano [Neapolitan] nds: Plattdüütsch [Low Saxon] ne: नेपाली [Nepali] new: नेपाल भाषा [Newar] nl: Nederlands [Dutch] nn: norsk nynorsk [Norwegian (Nynorsk)] no: norsk bokmål [Norwegian (Bokmål)] oc: occitan [Occitan] or: ଓଡ଼ିଆ [Oriya] os: Ирон [Ossetian] pa: ਪੰਜਾਬੀ [Eastern Punjabi] pl: polski [Polish] pms: Piemontèis [Piedmontese] pnb: پنجابی [Western Punjabi] pt: português [Portuguese] qu: Runa Simi [Quechua] ro: română [Romanian] ru: русский [Russian] sa: संस्कृतम् [Sanskrit] sah: саха тыла [Sakha] scn: sicilianu [Sicilian] sco: Scots sh: srpskohrvatski / српскохрватски [Serbo-Croatian] si: සිංහල [Sinhalese] simple: Simple English sk: slovenčina [Slovak] sl: slovenščina [Slovenian] sq: shqip [Albanian] sr: српски / srpski [Serbian] su: Basa Sunda [Sundanese] sv: svenska [Swedish] sw: Kiswahili [Swahili] ta: தமிழ் [Tamil] te: తెలుగు [Telugu] tg: тоҷикӣ [Tajik] th: ไทย [Thai] tl: Tagalog tr: Türkçe [Turkish] tt: татарча/tatarça [Tatar] uk: українська [Ukrainian] ur: اردو [Urdu] uz: oʻzbekcha/ўзбекча [Uzbek] vec: vèneto [Venetian] vi: Tiếng Việt [Vietnamese] vo: Volapük wa: walon [Walloon] war: Winaray [Waray] yi: ייִדיש [Yiddish] yo: Yorùbá [Yoruba] zh: 中文 [Chinese] zh-min-nan: Bân-lâm-gú [Min Nan] zh-yue: 粵語 [Cantonese]

jump to random article

searching for Entropy (classical thermodynamics) 66 found (81 total)

alternate case: entropy (classical thermodynamics)

Thermodynamics (5,705 words) [view diff] no match in snippet view article find links to article

Chemical thermodynamics Classical thermodynamics Equilibrium thermodynamics Industrial ecology (re: Exergy) Maximum entropy thermodynamics Non-equilibrium

Likewise, 'the entropy of the Solar System' is not defined in classical thermodynamics. It has not been possible to define non-equilibrium entropy, as a simple

Fundamentals of Classical Thermodynamics, Section 2.1 (3rd edition). G. J. Van Wylen and R. E. Sonntag, Fundamentals of Classical Thermodynamics, Section 5

in nature. Though very useful, they are strictly hypothetical. Classical thermodynamics is usually presented as postulating the existence of isolated systems

thought experiment involving ideal gases, is a useful exercise in classical thermodynamics. It provides a convenient example for calculating changes in thermodynamic

Classical thermodynamics considers three main kinds of thermodynamic processes: (1) changes in a system, (2) cycles in a system, and (3) flow processes

define a group of physical quantities, such as temperature, energy, and entropy, that characterize thermodynamic systems in thermodynamic equilibrium.

is accompanied by an increase in the sum of the entropies of the portions. Classical thermodynamics deals with states of dynamic equilibrium. The state

The Concepts of Classical Thermodynamics, Cambridge University Press, Cambridge. Jaynes, E.T. (1965). Gibbs vs Boltzmann entropies, American Journal

the definitions of entropy in statistical mechanics is the only entropy that is equivalent to the classical thermodynamics entropy under the following

textbook written by Herbert Callen that explains the basics of classical thermodynamics and discusses advanced topics in both classical and quantum frameworks

would show that the initial and final entropies are the same, thus, the reason it is called isentropic (entropy does not change). Thermodynamic processes

energy, and will therefore be unable to sustain processes that increase entropy. Heat death does not imply any particular absolute temperature; it only

quantities (such as heat capacity) to microscopic behavior, whereas, in classical thermodynamics, the only available option would be to measure and tabulate such

(Prentice-Hall 1966) p.45-46. Buchdahl, H.A. (1966). The Concepts of Classical Thermodynamics, Cambridge University Press, London, p. 40. Bailyn, M. (1994).

surroundings; then the entropy of Boltzmann's microscopically specified system can be identified with the system entropy in classical thermodynamics. The microstates

provides an independent definition of temperature without reference to entropy, which is defined in the second law. The law was established by Ralph H

temperature. The existence of such states is a basic postulate of classical thermodynamics. This postulate is sometimes, but not often, called the minus first

the history of classical thermodynamics, and with the development of statistical thermodynamics and quantum theory, entropy changes have been described

amounts of entropy that are extremely large compared to anything in data compression or signal processing. In classical thermodynamics, entropy is defined

; Tsallis, C. (2008). "Nonadditive entropy reconciles the area law in quantum systems with classical thermodynamics". Physical Review E. 78 (2): 021102

ISBN 0-471-38149-7 G.J. Van Wylen and R.E. Sonntag (1985), Fundamentals of Classical Thermodynamics, Section 2.1 (3rd edition), John Wiley & Sons, Inc., New York ISBN 0-471-82933-1

weather or climate. Atmospheric thermodynamics use the laws of classical thermodynamics, to describe and explain such phenomena as the properties of moist

Wiedemanns Ann. 69, 685 (1899) Pippard, Alfred B. (1981). Elements of classical thermodynamics: for advanced students of physics (Repr ed.). Cambridge: Univ.

dealing with processes in which systems exchange matter or energy, classical thermodynamics is not concerned with the rate at which such processes take place

editing an Entropy special Issue, Nature of heat and entropy, as well as a Topical collection, Foundations and Ubiquity of Classical Thermodynamics. Kostic

p 275. van Wylen, G.J.; Sonntag, R.E. (1985). Fundamentals of Classical Thermodynamics (3rd ed.). New York, NY: John Wiley & Sons. section 5.5. ISBN 978-0-471-82933-1

equilibrium system (i.e. it is not at rest yet). Many results in classical thermodynamics are not easily applied to non-equilibrium systems. However, there

Joule expansion is an example of classical thermodynamics, as it is easy to work out the resulting increase in entropy. It occurs where a volume of gas

(2003). Greven, A.; Keller, G.; Warnecke, G. (eds.). The Entropy of Classical Thermodynamics (Princeton Series in Applied Mathematics). Princeton University

constant. Note that in classical thermodynamics, S is defined in terms of temperature. This is reversed here, S is the statistical entropy, a function of the

Thermodynamic equations Pippard, A. B. (1957-01-01). Elements of Classical Thermodynamics:For Advanced Students of Physics (1st ed.). Cambridge: Cambridge

edition 1967, North-Holland, Amsterdam, p. 14. Münster, A. (1970). Classical Thermodynamics, translated by E.S. Halberstadt, Wiley–Interscience, London, pp

is possible to describe the kinetic theory of gases, upon which classical thermodynamics is based. Thermodynamics studies the effects of changes in temperature

transferring entropy between spins, or outside of the system. The concept of heat reservoir is discussed extensively in classical thermodynamics (for instance

Butterworth Heinemann. ISBN 978-0-7506-2633-0. Münster, A. (1970), Classical Thermodynamics, translated by E. S. Halberstadt, Wiley–Interscience, London, ISBN 0-471-62430-6

cause. Much of the book is devoted to expanding upon the ideas of classical thermodynamics, with an extended discussion about how consistently far from equilibrium

β{\displaystyle \beta } can be understood in a variety of different ways. In classical thermodynamics, it is an inverse temperature. More generally, one would say that

mechanics than classical mechanics, and statistical mechanics over classical thermodynamics) focuses on the position of atoms, especially in disordered materials

thermodynamics and their time of inception: Thermochemistry – 1780s Classical thermodynamics – 1824 Chemical thermodynamics – 1876 Statistical mechanics – c

\cdot ({\mathbf {\sigma } \cdot v})-\nabla \cdot {\mathbf {q} }}. Classical thermodynamics is initially focused on closed homogeneous systems (e.g. Planck

Wikimedia Commons has media related to Heat engines. Fundamentals of Classical Thermodynamics, 3rd ed. p. 159, (1985) by G. J. Van Wylen and R. E. Sonntag: "A

be a special case of a more general relation. Siefert writes: Classical thermodynamics, at its heart, deals with general laws governing the transformations

of nonzero temperature phase transitions is fully described by classical thermodynamics; quantum mechanics does not play any role even if the actual phases

integrability of demand functions. In classical thermodynamics, Frobenius' theorem can be used to construct entropy and temperature in Carathéodory's formalism

pandemic in Michigan. Van Wylen, Gordon J. (1994). Fundamentals of classical thermodynamics. Richard Edwin Sonntag, C. Borgnakke (4th ed.). New York: Wiley

In thermodynamics, the entropy of mixing is the increase in the total entropy when several initially separate systems of different composition, each in

Hamiltonian formalisms Classical electrodynamics (Maxwell's Equations) Classical thermodynamics Classical chaos theory and nonlinear dynamics In contrast to classical

contraries. For radiation, some further comments may be useful. In classical thermodynamics, one-way radiation, from one system to another, is not considered

modern physics. When combined with classical thermodynamics, classical mechanics leads to the Gibbs paradox in which entropy is not a well-defined quantity

time as relating to the nature of thermodynamics. The answer from classical thermodynamics states that while our basic physical theory is, in fact, time-reversal

1017/S0080456800022481. Pippard, Alfred B. (1981). Elements of classical thermodynamics: for advanced students of physics (Repr ed.). Cambridge: Univ.

physical theory tend to use thermodynamic cycles, a concept from classical thermodynamics. The two common thermodynamic cycles used involve either the calculation

scaling dimension Classical theories of gravitation Classical theory Classical thermodynamics Classical treatment of tensors Classical unified field theories

non-equilibrium thermodynamics can describe irreversible changes. However, classical thermodynamics is mostly concerned with systems in equilibrium and reversible

ISBN 0-19-855148-7 Pippard, Alfred B. (1981). "5: Useful ideas". Elements of classical thermodynamics: for advanced students of physics (Repr ed.). Cambridge: Univ.

1007/s10909-016-1733-3. Pippard, Alfred B. (1981). Elements of classical thermodynamics: for advanced students of physics (Repr ed.). Cambridge: Univ.

Publishing, NY, p.250, (1979) Truesdale, C. and Bharatha, S., Classical Thermodynamics as a Theory of Heat Engines, Springer-Verlag, NY, pp 13-15, (1977)

1/β=kT{\displaystyle 1/\beta =kT}. This reproduces the equipartition theorem of classical thermodynamics: every harmonic oscillator at temperature T has energy kT on average

including its fundamental laws, providing a harmonization of classical thermodynamics with classical mechanics. The work is a "technical masterpiece"[citation

1985, Wiley, New York, ISBN 0-471-86256-8. Münster, A. (1970), Classical Thermodynamics, translated by E.S. Halberstadt, Wiley–Interscience, London, ISBN 0-471-62430-6

for systems that lie outside the bounds of the assumptions of classical thermodynamics. In the case of high velocity objects approaching the speed of

unjustifiable assumption that for some reason the radiation is finite, classical thermodynamics provides an account of some aspects of the Planck distribution

ISSN 1742-5468. S2CID 119122520. Pippard, Alfred B. (1981). Elements of classical thermodynamics: for advanced students of physics (Repr ed.). Cambridge: Univ.

Wylen, Gordon J.; Sonntag, Richard E. (1965). Fundamentals of Classical Thermodynamics. New York: John Wiley and Sons. Feynman, R.P.; Leighton, R.B.;

357-359, (1875) Van Wylen, G.J., and Sonntag, R.E., Fundamentals of Classical Thermodynamics Second Edition, John Wiley and Sons, N.Y., p. 211, (1973) Moran