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| The principle of '''detailed balance''' is formulated for kinetic systems which are decomposed into elementary processes (collisions, or steps, or elementary reactions): ''At [[Thermodynamic equilibrium|equilibrium]], each elementary process should be equilibrated by its reverse process.''
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| ==History==
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| The principle of detailed balance was explicitly introduced for collisions by [[Ludwig Boltzmann]]. In 1872, he proved his [[H-theorem]] using this principle.<ref name = "Boltzmann1872">Boltzmann, L. (1964), Lectures on gas theory, Berkeley, CA, USA: U. of California Press.</ref> The arguments in favor of this property are founded upon [[microscopic reversibility]].<ref name = "Tolman1938">[[Richard C. Tolman|Tolman, R. C.]] (1938). ''The Principles of Statistical Mechanics''. Oxford University Press, London, UK.</ref> [[Albert Einstein]] in 1916 used this principle in a background for his quantum theory of emission and absorption of radiation.<ref>Einstein, A. (1916). Strahlungs-Emission und -Absorption nach der Quantentheorie [=Emission and absorption of radiation in quantum theory], Verhandlungen der Deutschen Physikalischen Gesellschaft 18 (13/14). Braunschweig: Vieweg, 318-323. See also: A. Einstein (1917). Zur Quantentheorie der Strahlung [=On the quantum theory of radiation], Physikalische Zeitschrift 18 (1917), 121-128. [http://hermes.ffn.ub.es/luisnavarro/nuevo_maletin/Einstein%20(1917)_Quantum%20theory%20of%20radiation.pdf English translation]: D. ter Haar (1967): The Old Quantum Theory. Pergamon Press, pp. 167-183.</ref>
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| In 1901, [[Rudolf Wegscheider]] introduced the principle of detailed balance for chemical kinetics.<ref>Wegscheider, R. (1901) [http://www.springerlink.com/content/q12x76713v015316/ Über simultane Gleichgewichte und die Beziehungen zwischen Thermodynamik und Reactionskinetik homogener Systeme], Monatshefte für Chemie / Chemical Monthly 32(8), 849--906.</ref> In particular, he demonstrated that the irreversible cycles <math>A_1 \to A_2 \to ... \to A_n \to A_1</math> are impossible and found explicitly the relations between kinetic constants that follow from the principle of detailed balance. In 1931, [[Lars Onsager]] used these relations in his works,<ref name = "Onsager1931">Onsager, L. (1931), [http://prola.aps.org/abstract/PR/v37/i4/p405_1 Reciprocal relations in irreversible processes.] I, Phys. Rev. 37, 405-426; II 38, 2265-2279</ref> for which he was awarded the 1968 [[Nobel Prize in Chemistry]].
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| The principle of detailed balance is used in the [[Markov chain Monte Carlo]] methods since their invention in 1953.<ref>{{cite journal
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| |first1=N. |last1=Metropolis |authorlink1=Nicholas Metropolis
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| |first2=A.W. |last2=Rosenbluth
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| |first3=M.N. |last3=Rosenbluth |authorlink3=Marshall N. Rosenbluth
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| |first4=A.H. |last4=Teller
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| |first5=E. |last5=Teller |authorlink5=Edward Teller
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| |title=[[Equations of State Calculations by Fast Computing Machines]]
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| |journal=Journal of Chemical Physics
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| |volume=21 |issue=6 |pages=1087–1092 |year=1953
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| |doi=10.1063/1.1699114 |bibcode=1953JChPh..21.1087M
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| }}</ref> In particular, in the [[Metropolis–Hastings algorithm]] and in its important particular case, [[Gibbs sampling]], it is used as a simple and reliable condition to provide the desirable equilibrium state.
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| Now, the principle of detailed balance is a standard part of the university courses in statistical mechanics, physical chemistry, chemical and physical kinetics.<ref name=vanKampen1992>van Kampen, N.G. "Stochastic Processes in Physics and Chemistry", Elsevier Science (1992).</ref><ref name=Yab1991>Yablonskii, G.S., Bykov, V.I., Gorban, A.N., Elokhin, V.I. (1991), Kinetic Models of Catalytic Reactions, Amsterdam, The Netherlands: Elsevier.</ref><ref>{{cite book | author=Lifshitz, E. M.; and Pitaevskii, L. P. | title=Physical kinetics | year = 1981 | location= London | publisher=Pergamon | isbn=978-0-08-026480-6}} Vol. 10 of the [[Course of Theoretical Physics]](3rd Ed).</ref>
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| ==Microscopical background==
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| The microscopic "reversing of time" turns at the kinetic level into the "reversing of arrows": the elementary processes transform into their reverse processes. For example, the reaction
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| :<math>\sum_i \alpha_i A_i \to \sum_j \beta_j B_j</math> transforms into <math>\sum_j \beta_j B_j \to \sum_i \alpha_i A_i</math>
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| and conversely. (Here, <math>A_i, B_j</math> are symbols of components or states, <math>\alpha_i, \beta_j \geq 0 </math> are coefficients). The equilibrium ensemble should be invariant with respect to this transformation because of microreversibility and the uniqueness of thermodynamic equilibrium. This leads us immediately to the concept of detailed balance: each process is equilibrated by its reverse process.
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| ==Reversible Markov chains==
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| The reversibility condition in Markov chains arises from [[Kolmogorov's criterion]] which demands that for the reversible chains the product of transition rates over any closed loop of states must be the same in both directions. A Markov process satisfies detailed balance equations if and only if it is a '''reversible Markov process''' or '''[[Markov chain#Reversible Markov chain|reversible Markov chain]]'''.<ref name=OHagan /> A [[Markov process]] is said to have detailed balance if the [[transition probability]], ''P'', between each pair of states ''i'' and ''j'' in the state space obey
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| :<math>\pi_{i} P_{ij} = \pi_{j} P_{ji}\,,</math>
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| where ''P'' is the Markov transition matrix (transition probability), ''i.e.'', ''P''<sub>''ij''</sub> = ''P''(''X''<sub>''t''</sub> = ''j'' | ''X''<sub>''t'' − 1</sub> = ''i''); and π<sub>''i''</sub> and π<sub>''j''</sub> are the equilibrium probabilities of being in states ''i'' and ''j'', respectively.<ref name=OHagan>{{Cite book|last1=O'Hagan |first1=Anthony |authorlink1= |last2=Forster |first2=Jonathan |authorlink2= |title=Kendall's Advanced Theory of Statistics, Volume 2B: Bayesian Inference |trans_title= |url= |archiveurl= |archivedate= |format= |accessdate= |edition= |series= |volume= |date= |year=2004 |month= |origyear= |publisher=Oxford University Press |location=New York |isbn=0-340-80752-0 |oclc= |doi= |id= |page=263 |pages= |at= |trans_chapter= |chapter=Section 10.3 |chapterurl= |quote= |ref= |bibcode= |laysummary= |laydate= |separator= |postscript= |lastauthoramp=}}</ref> When Pr(''X''<sub>''t''−1</sub> = ''i'') = π<sub>''i''</sub> for all ''i'', this is equivalent to the joint probability matrix, Pr(''X''<sub>''t''−1</sub> = ''i'', ''X''<sub>''t''</sub> = ''j'') being symmetric in ''i'' and ''j''; or symmetric in ''t'' − 1 and ''t''.
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| The definition carries over straightforwardly to continuous variables, where π becomes a probability density, and ''P''(''s''′, ''s'') a transition kernel probability density from state ''s''′ to state ''s'':
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| :<math>\pi(s') P(s',s) = \pi(s) P(s,s')\,.</math>
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| The detailed balance condition is stronger than that required merely for a [[stationary distribution]]; that is, there are Markov processes with stationary distributions that do not have detailed balance. Detailed balance implies that, around any closed cycle of states, there is no net flow of probability. For example, it implies that, for all ''a'', ''b'' and ''c'',
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| :<math>P(a,b) P(b,c) P(c,a) = P(a,c) P(c,b) P(b,a)\,.</math> | |
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| This can be proved by substitution from the definition. In the case of a positive transition matrix, the "no net flow" condition implies detailed balance.
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| Transition matrices that are symmetric (''P''<sub>''ij''</sub> = ''P''<sub>''ji''</sub> or ''P''(''s''′, ''s'') = ''P''(''s'', ''s''′)) always have detailed balance. In these cases, a uniform distribution over the states is an equilibrium distribution. For continuous systems with detailed balance, it may be possible to continuously transform the coordinates until the equilibrium distribution is uniform, with a transition kernel which then is symmetric. In the case of discrete states, it may be possible to achieve something similar by breaking the Markov states into a degeneracy of sub-states.
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| ==Detailed balance and the entropy growth==
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| For many systems of physical and chemical kinetics, detailed balance provides ''sufficient conditions'' for the entropy growth in isolated systems. For example, the famous Boltzmann [[H-theorem]]<ref name = "Boltzmann1872"/> states that, according to the Boltzmann equation, the principle of detailed balance implies positivity of the entropy production. The Boltzmann formula (1872) for the entropy production in the rarefied gas kinetics with detailed balance<ref name = "Boltzmann1872"/><ref name = "Tolman1938"/> served as a prototype of many similar formulas for dissipation in mass action kinetics<ref>[[Aizik Isaakovich Vol'pert|Volpert, A.I.]], Khudyaev, S.I. (1985), Analysis in classes of discontinuous functions and equations of mathematical physics. Dordrecht, The Netherlands: Nijoff. (Translation from the 1st Russian ed., Moscow, Nauka publ., 1975.)</ref> and generalized mass action kinetics<ref>Schuster, S., Schuster R. (1989). [http://www.springerlink.com/content/g3m2177v4344065q/ A generalization of Wegscheider's condition. Implications for properties of steady states and for quasi-steady-state approximation.] J. Math. Chem, 3 (1), 25-42.</ref> with detailed balance.
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| Nevertheless, the principle of detailed balance is not necessary for the entropy growth. For example, in the linear irreversible cycle <math>A_1 \to A_2 \to A_3 \to A_1</math>, the entropy production is positive but the principle of detailed balance does not hold.
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| Thus, the principle of detailed balance is a sufficient but not necessary condition for the entropy growth in the Boltzmann kinetics. These relations between the principle of detailed balance and the second law of thermodynamics were clarified in 1887 when [[Hendrik Lorentz]] objected the Boltzmann H-theorem for polyatomic gases.<ref>Lorentz H.-A. (1887) Über das Gleichgewicht der lebendigen Kraft unter Gasmolekülen. Sitzungsberichte der Kaiserlichen Akademie der Wissenschaften in Wien. 95 (2), 115–152.</ref> Lorentz stated that the principle of detailed balance is not applicable to collisions of polyatomic molecules. Boltzmann immediately invented a new, more general condition sufficient for the entropy growth.<ref name=Boltzmann1887>Boltzmann L. (1887) Neuer Beweis zweier Sätze über das Wärmegleichgewicht unter mehratomigen Gasmolekülen. Sitzungsberichte der Kaiserlichen Akademie der Wissenschaften in Wien. 95 (2), 153–164.</ref> In particular, this condition is valid for all Markov processes without any relation to time-reversibility. The entropy growth in all Markov processes was explicitly proved later.<ref>[[Claude Shannon|Shannon, C.E.]] (1948) A Mathematical Theory of Communication, ''Bell System Technical Journal'', Vol. 27, pp. 379–423, 623–656. [http://www.alcatel-lucent.com/bstj/vol27-1948/articles/bstj27-3-379.pdf] [http://www.alcatel-lucent.com/bstj/vol27-1948/articles/bstj27-4-623.pdf]</ref><ref name=everett56>[[Hugh Everett]] [http://www.pbs.org/wgbh/nova/manyworlds/pdf/dissertation.pdf Theory of the Universal Wavefunction], Thesis, Princeton University, (1956, 1973), Appendix I, pp 121 ff. In his thesis, Everett used the term "detailed balance" unconventionally, instead of [[balance equation]]</ref> These theorems may be considered as simplifications of the Boltzmann result. Later, this condition was discussed as the "cyclic balance" condition (because it holds for irreversible cycles) or the "semi-detailed balance" or the "complex balance". In 1981, [[Carlo Cercignani]] and Maria Lampis proved that the Lorenz arguments were wrong and the principle of detailed balance is valid for polyatomic molecules.<ref>Cercignani, C. and Lampis, M. (1981). On the H-theorem for polyatomic gases, Journal of Statistical Physics, V. 26 (4), 795–801.</ref> Nevertheless, the extended semi-detailed balance conditions invented by Boltzmann in this discussion remain the remarkable generalization of the detailed balance.
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| ==Wegscheider's conditions for the generalized mass action law==
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| In [[chemical kinetics]], the [[elementary reaction]]s are represented by the [[Chemical equation|stoichiometric equations]]
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| :<math>\sum_i \alpha_{ri} A_i \to \sum_j \beta_{rj} A_j \;\; (r=1, \ldots, m) \, , </math>
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| where <math>A_i</math> are the components and <math>\alpha_{ri}, \beta_{rj}\geq 0</math> are the stoichiometric coefficients. Here, the reverse reactions with positive constants are included in the list separately. We need this separation of direct and reverse reactions to apply later the general formalism to the systems with some irreversible reactions. The system of stoichiometric equations of elementary reactions is the ''reaction mechanism''.
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| The ''[[Stoichiometry|stoichiometric matrix]]'' is <math>\boldsymbol{\Gamma}=(\gamma_{ri})</math>, <math>\gamma_{ri}=\beta_{ri}-\alpha_{ri}</math> (gain minus loss). The ''stoichiometric vector'' <math>\gamma_r</math> is the ''r''th row of <math>\boldsymbol{\Gamma}</math> with coordinates <math>\gamma_{ri}=\beta_{ri}-\alpha_{ri}</math>.
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| According to the ''generalized [[Law of mass action|mass action law]]'', the [[reaction rate]] for an elementary reaction is
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| :<math>w_r=k_r \prod_{i=1}^n a_i^{\alpha_{ri}} \, ,</math>
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| where <math>a_i\geq 0</math> is the [[Activity (chemistry)|activity]] of <math>A_i</math>.
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| The reaction mechanism includes reactions with the [[reaction rate constant]]s <math>k_r>0</math>. For each ''r'' the following notations are used: <math>k_r^+=k_r</math>; <math>w_r^+=w_r</math>; <math>k_r^-</math> is the reaction rate constant for the reverse reaction if it is in the reaction mechanism and 0 if it is not; <math>w_r^-</math> is the reaction rate for the reverse reaction if it is in the reaction mechanism and 0 if it is not. For a reversible reaction, <math>K_r=k_r^+/k_r^-</math> is the [[equilibrium constant]].
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| The principle of detailed balance for the generalized mass action law is: For given values <math>k_r</math> there exists a positive equilibrium <math>a_i^{\rm eq}>0</math> with detailed balance, <math>w_r^+=w_r^-</math>. This means that the system of ''linear'' detailed balance equations | |
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| <math>\sum_i \gamma_{ri} x_i = \ln k_r^+-\ln k_r^-=\ln K_r </math>
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| is solvable (<math>x_i=\ln a_i^{\rm eq}</math>). The following classical result gives the necessary and sufficient conditions for the existence of the positive equilibrium <math>a_i^{\rm eq}>0</math> with detailed balance (see, for example, the textbook<ref name=Yab1991/>).
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| Two conditions are sufficient and necessary for solvability of the system of detailed balance equations:
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| # If <math>k_r^+>0</math> then <math>k_r^->0</math> (reversibility);
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| # For any solution <math>\boldsymbol{\lambda}=(\lambda_r)</math> of the system
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| :<math>\boldsymbol{\lambda \Gamma} =0 \;\; \left(\mbox{i.e.}\;\; \sum_r \lambda_r \gamma_{ri}=0\;\; \mbox{for all} \;\; i\right)</math>
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| the Wegscheider's identity<ref name=GorbanYablonsky2011>Gorban, A.N., Yablonsky, G.S. (2011) [http://arxiv.org/PS_cache/arxiv/pdf/1101/1101.5280v3.pdf Extended detailed balance for systems with irreversible reactions], [http://dx.doi.org/10.1016/j.ces.2011.07.054 Chemical Engineering Science 66, 5388–5399].</ref> holds:
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| :<math>\prod_{r=1}^m (k_r^+)^{\lambda_r}=\prod_{r=1}^m (k_r^-)^{\lambda_r} \, .</math>
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| ''Remark.'' It is sufficient to use in the Wegscheider conditions a basis of solutions of the system <math>\boldsymbol{\lambda \Gamma} =0 </math>.
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| In particular, for any cycle in the monomolecular (linear) reactions the product of the reaction rate constants in the clockwise direction is equal to the product of the reaction rate constants in the counterclockwise direction. The same condition is valid for the reversible Markov processes (it is equivalent to the "no net flow" condition).
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| A simple nonlinear example gives us a linear cycle supplemented by one nonlinear step:<ref name=GorbanYablonsky2011/>
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| # <math>A_1 \rightleftharpoons A_2</math>
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| # <math>A_2 \rightleftharpoons A_3 </math>
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| # <math>A_3 \rightleftharpoons A_1</math>
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| # <math>A_1+A_2 \rightleftharpoons 2A_3</math>
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| There are two nontrivial independent Wegscheider's identities for this system:
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| :<math>k_1^+k_2^+k_3^+=k_1^-k_2^-k_3^-</math> and <math>k_3^+k_4^+/k_2^+=k_3^-k_4^-/k_2^-</math>
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| They correspond to the following linear relations between the stoichiometric vectors: | |
| :<math>\gamma_1+\gamma_2+\gamma_3=0</math> and <math>\gamma_3+\gamma_4-\gamma_2=0</math>.
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| The computational aspect of the Wegscheider conditions was studied by D. Colquhoun with co-authors.<ref>Colquhoun, D., Dowsland, K.A., Beato, M., and Plested, A.J.R. (2004) [http://www.ucl.ac.uk/Pharmacology/dc-bits/colquhoun-biophysj-04.pdf How to Impose Microscopic Reversibility in Complex Reaction Mechanisms], Biophysical Journal 86, June 2004, 3510–3518</ref>
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| The Wegscheider conditions demonstrate that whereas the principle of detailed balance states a local property of equilibrium, it implies the relations between the kinetic constants that are valid for all states far from equilibrium. This is possible because a kinetic law is known and relations between the rates of the elementary processes at equilibrium can be transformed into relations between kinetic constants which are used globally. For the Wegscheider conditions this kinetic law is the law of mass action (or the generalized law of mass action).
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| ==Dissipation in systems with detailed balance==
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| To describe dynamics of the systems that obey the generalized mass action law, one has to represent the activities as functions of the [[concentration]]s ''c<sub>j</sub>'' and [[temperature]]. For this purpose, use the representation of the activity through the chemical potential:
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| :<math>a_i = \exp\left (\frac{\mu_i - \mu^{\ominus}_i}{RT}\right )</math>
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| where ''μ<sub>i</sub>'' is the [[chemical potential]] of the species under the conditions of interest, ''μ''<sup><s>o</s></sup><sub>''i''</sub> is the chemical potential of that species in the chosen [[standard state]], ''R'' is the [[gas constant]] and ''T'' is the [[thermodynamic temperature]].
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| The chemical potential can be represented as a function of ''c'' and ''T'', where ''c'' is the vector of concentrations with components ''c<sub>j</sub>''. For the ideal systems, <math>\mu_i=RT\ln c_i+\mu^{\ominus}_i</math> and <math>a_j=c_j</math>: the activity is the concentration and the generalized mass action law is the usual [[law of mass action]].
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| Let us consider a system in [[Isothermal process|isothermal]] (''T''=const) [[Isochoric process|isochoric]] (the volume ''V''=const) condition. For these conditions, the [[Helmholtz free energy]] ''F(T,V,N)'' measures the “useful” work obtainable from a system. It is a functions of the temperature ''T'', the volume ''V'' and the amounts of chemical components ''N<sub>j</sub>'' (usually measured in [[Mole (unit)|mole]]s), ''N'' is the vector with components ''N<sub>j</sub>''. For the ideal systems, <math>F=RT \sum_i N_i \left(\ln\left(\frac{N_i}{V}\right)-1+\frac{\mu^{\ominus}_i(T)}{RT}\right) </math>
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| The chemical potential is a partial derivative: <math> \mu_i=\partial F(T,V,N)/\partial N_j</math>.
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| The chemical kinetic equations are
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| :<math>\frac{d N_i}{d t}=V \sum_r \gamma_{ri}(w^+_r-w^-_r) .</math>
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| If the principle of detailed balance is valid then for any value of ''T'' there exists a positive point of detailed balance ''c''<sup>eq</sup>:
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| :<math>w^+_r(c^{\rm eq},T)=w^-_r(c^{\rm eq},T)=w^{\rm eq}_r</math>
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| Elementary algebra gives
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| :<math>w^+_r=w^{\rm eq}_r \exp \left(\sum_i \frac{\alpha_{ri}(\mu_i-\mu^{\rm eq}_i)}{RT}\right); \;\; w^-_r=w^{\rm eq}_r \exp \left(\sum_i \frac{\beta_{ri}(\mu_i-\mu^{\rm eq}_i)}{RT}\right);</math>
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| where <math>\mu^{\rm eq}_i=\mu_i(c^{\rm eq},T)</math>
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| For the dissipation we obtain from these formulas:
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| :<math>\frac{d F}{d t}=\sum_i \frac{\partial F(T,V,N)}{\partial N_i} \frac{d N_i}{d t}=\sum_i \mu_i \frac{d N_i}{d t} = -VRT \sum_r (\ln w_r^+-\ln w_r^-) (w_r^+-w_r^-) \leq 0</math>
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| The inequality holds because ln is a monotone function and, hence, the expressions <math>\ln w_r^+-\ln w_r^-</math> and <math>w_r^+-w_r^-</math> have always the same sign.
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| Similar inequalities<ref name=Yab1991/> are valid for other classical conditions for the closed systems and the corresponding characteristic functions: for isothermal isobaric conditions the [[Gibbs free energy]] decreases, for the isochoric systems with the constant [[internal energy]] ([[isolated system]]s) the [[entropy]] increases as well as for isobaric systems with the constant [[enthalpy]].
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| == Onsager reciprocal relations and detailed balance ==
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| Let the principle of detailed balance be valid. Then, in the linear approximation near equilibrium the reaction rates for the generalized mass action law are
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| :<math>w^+_r=w^{\rm eq}_r \left(1+\sum_i \frac{\alpha_{ri}(\mu_i-\mu^{\rm eq}_i)}{RT}\right); \;\; w^-_r=w^{\rm eq}_r \left(1+ \sum_i \frac{\beta_{ri}(\mu_i-\mu^{\rm eq}_i)}{RT}\right);</math>
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| Therefore, in the linear approximation near equilibrium, the kinetic equations are (<math>\gamma_{ri}=\beta_{ri}-\alpha_{ri}</math>):
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| :<math>\frac{d N_i}{d t}=-V \sum_j \left[\sum_r w^{\rm eq}_r \gamma_{ri}\gamma_{rj}\right] \frac{\mu_j-\mu^{\rm eq}_j}{RT}.</math>
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| This is exactly the Onsager form: following the original work of Onsager,<ref name = "Onsager1931"/> we should introduce the thermodynamic forces <math>X_j</math> and the matrix of coefficients <math>L_{ij}</math> in the form
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| :<math>X_j = \frac{\mu_j-\mu^{\rm eq}_j}{T}; \;\; \frac{d N_i}{d t}=\sum_j L_{ij}X_j </math>
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| The coefficient matrix <math>L_{ij}</math> is symmetric:
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| :<math>L_{ij}=-\frac{V}{R}\sum_r w^{\rm eq}_r \gamma_{ri}\gamma_{rj}</math>
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| These symmetry relations, <math>L_{ij}=L_{ji}</math>, are exactly the Onsager reciprocal relations. The coefficient matrix <math>L</math> is non-positive. It is negative on the [[linear span]] of the stoichiometric vectors <math>\gamma_{r}</math>.
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| So, the Onsager relations follow from the principle of detailed balance in the linear approximation near equilibrium.
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| ==Semi-detailed balance==
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| To formulate the principle of semi-detailed balance, it is convenient to count the direct and inverse elementary reactions separately. In this case, the kinetic equations have the form:
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| :<math>\frac{d N_i}{d t}=V\sum_r \gamma_{ri} w_r=V\sum_r (\beta_{ri}-\alpha_{ri})w_r </math>
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| Let us use the notations <math>\alpha_r=\alpha_{ri}</math>, <math>\beta_r=\beta_{ri}</math> for the input and the output vectors of the stoichiometric coefficients of the ''r''th elementary reaction. Let <math>Y</math> be the set of all these vectors <math>\alpha_r, \beta_r</math>.
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| For each <math>\nu \in Y</math>, let us define two sets of numbers:
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| :<math>R_{\nu}^+=\{r|\alpha_r=\nu \}; \;\;\; R_{\nu}^-=\{r|\beta_r=\nu \}</math>
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| <math>r \in R_{\nu}^+</math> if and only if <math>\nu</math> is the vector of the input stoichiometric coefficients <math>\alpha_r</math> for the ''r''th elementary reaction;<math>r \in R_{\nu}^-</math> if and only if <math>\nu</math> is the vector of the output stoichiometric coefficients <math>\beta_r</math> for the ''r''th elementary reaction.
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| The principle of '''semi-detailed balance''' means that in equilibrium the semi-detailed balance condition holds: for every <math>\nu \in Y</math>
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| :<math>\sum_{r\in R_{\nu}^-}w_r=\sum_{r\in R_{\nu}^+}w_r</math>
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| The semi-detailed balance condition is sufficient for the stationarity: it implies that
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| :<math>\frac{d N}{dt}=V \sum_r \gamma_r w_r=0</math>.
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| For the Markov kinetics the semi-detailed balance condition is just the elementary [[balance equation]] and holds for any steady state. For the nonlinear mass action law it is, in general, sufficient but not necessary condition for stationarity.
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| The semi-detailed balance condition is weaker than the detailed balance one: if the principle of detailed balance holds then the condition of semi-detailed balance also holds.
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| For systems that obey the generalized mass action law the semi-detailed balance condition is sufficient for the dissipation inequality <math>d F/ dt \geq 0</math> (for the Helmholtz free energy under isothermal isochoric conditions and for the dissipation inequalities under other classical conditions for the corresponding thermodynamic potentials).
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| Boltzmann introduced the semi-detailed balance condition for collisions in 1887<ref name=Boltzmann1887 /> and proved that it guaranties the positivity of the entropy production. For chemical kinetics, this condition (as the ''complex balance'' condition) was introduced by Horn and Jackson in 1972.<ref name="HornJackson1972">''Horn, F., Jackson, R.'' (1972) General mass action kinetics. Arch. Ration. Mech. Anal. 47, 87-116.</ref>
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| The microscopic backgrounds for the semi-detailed balance were found in the Markov microkinetics of the intermediate compounds that are present in small amounts and whose concentrations are in quasiequilibrium with the main components.<ref>''[[Ernst Stueckelberg|Stueckelberg]], E.C.G.'' (1952) Theoreme ''H'' et unitarite de ''S''. Helv. Phys. Acta 25, 577-580</ref> Under these microscopic assumptions, the semi-detailed balance condition is just the [[balance equation]] for the Markov microkinetics according to the '''[[Leonor Michaelis|Michaelis]]-[[Maud Menten|Menten]]-[[Ernst Stueckelberg|Stueckelberg]] theorem.<ref name="GorbanShahzad2011">''Gorban, A.N., Shahzad, M.'' (2011) [http://arxiv.org/pdf/1008.3296 The Michaelis-Menten-Stueckelberg Theorem.] Entropy 13, no. 5, 966-1019.</ref>
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| == Dissipation in systems with semi-detailed balance ==
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| Let us represent the generalized mass action law in the equivalent form: the rate of the elementary process
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| :<math>\sum_i \alpha_{ri} A_i \to \sum_i \beta_{ri} A_i</math>
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| is
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| :<math>w_r=\varphi_r \exp\left(\sum_i\frac{\alpha_{ri} \mu_i}{RT}\right)</math>
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| where <math>\mu_i=\partial F(T,V,N)/ \partial N_i</math> is the chemical potential and <math>F(T,V,N)</math> is the [[Helmholtz free energy]]. The exponential term is called the ''Boltzmann factor'' and the multiplier <math>\varphi_r \geq 0</math> is the kinetic factor.<ref name="GorbanShahzad2011" />
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| Let us count the direct and reverse reaction in the kinetic equation separately:
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| :<math>\frac{d N_i}{d t}=V\sum_r \gamma_{ri} w_r</math>
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| An auxiliary function <math>\theta(\lambda)</math> of one variable <math>\lambda\in [0,1]</math> is convenient for the representation of dissipation for the mass action law
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| :<math>\theta(\lambda)=\sum_{r}\varphi_{r}\exp\left(\sum_i\frac{(\lambda \alpha_{ri}+(1-\lambda)\beta_{ri}))\mu_i}{RT}\right)</math>
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| This function <math>\theta(\lambda)</math> may be considered as the sum of the reaction rates for ''deformed'' input stoichiometric coefficients <math>\tilde{\alpha}_{\rho}(\lambda)=\lambda \alpha_{\rho}+(1-\lambda)\beta_{\rho}</math>. For <math>\lambda=1</math> it is just the sum of the reaction rates. The function <math>\theta(\lambda)</math> is convex because <math>\theta''(\lambda) \geq 0</math>.
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| Direct calculation gives that according to the kinetic equations
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| :<math> \frac{d F}{d t}=-VRT \left.\frac{d \theta(\lambda)}{d \lambda}\right|_{\lambda=1}</math>
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| This is ''the general dissipation formula for the generalized mass action law''.<ref name="GorbanShahzad2011" />
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| Convexity of <math>\theta(\lambda)</math> gives the sufficient and necessary conditions for the proper dissipation inequality:
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| :<math>\frac{d F}{d t}<0 \mbox{ if and only if } \theta(\lambda)< \theta(1) \mbox{ for some }\lambda <1; \;\;\; \frac{d F}{d t}\leq0 \mbox{ if and only if } \theta(\lambda)\leq \theta(1) \mbox{ for some }\lambda <1 </math> | |
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| The semi-detailed balance condition can be transformed into identity <math>\theta(0)\equiv \theta(1)</math>. Therefore, for the systems with semi-detailed balance <math>{d F}/{d t}\leq 0</math>.<ref name="HornJackson1972" />
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| == Detailed balance for systems with irreversible reactions ==
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| Detailed balance states that in equilibrium each elementary process is equilibrated by its reverse process and required reversibility of all elementary processes. For many real physico-chemical complex systems (e.g. homogeneous combustion, heterogeneous catalytic oxidation, most enzyme reactions etc.), detailed mechanisms include both reversible and irreversible reactions. If one represents irreversible reactions as limits of reversible steps, then it become obvious that not all reaction mechanisms with irreversible reactions can be obtained as limits of systems or reversible reactions with detailed balance. For example, the irreversible cycle <math>A_1 \to A_2 \to A_3 \to A_1</math> cannot be obtained as such a limit but the reaction mechanism <math>A_1 \to A_2 \to A_3 \leftarrow A_1</math> can.<ref>Chu, Ch. (1971), Gas absorption accompanied by a system of first-order reactions, Chem. Eng. Sci. 26(3), 305-312.</ref>
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| '''Gorban-[[Grigoriy Yablonsky|Yablonsky]] theorem'''. ''A system of reactions with some irreversible reactions is a limit of systems with detailed balance when some constants tend to zero if and only if (i) the reversible part of this system satisfies the principle of detailed balance and (ii) the [[convex hull]] of the stoichiometric vectors of the irreversible reactions has empty intersection with the [[linear span]] of the stoichiometric vectors of the reversible reactions.''<ref name=GorbanYablonsky2011/> Physically, the last condition means that the irreversible reactions cannot be included in oriented cyclic pathways.
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| ==See also==
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| * [[T-symmetry]]
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| * [[Microscopic reversibility]]
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| * [[Master equation]]
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| * [[Balance equation]]
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| * [[Gibbs sampling]]
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| * [[Metropolis–Hastings algorithm]]
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| * [[Atomic spectral line]] (deduction of the Einstein coefficients)
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| * [[Random walk#Random walk on graphs|Random walks on graphs]]
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| ==References==
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| {{Reflist}}
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| {{DEFAULTSORT:Detailed Balance}}
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| [[Category:Probability theory]]
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| [[Category:Non-equilibrium thermodynamics]]
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| [[Category:Statistical mechanics]]
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| [[Category:Markov models]]
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| [[Category:Chemical kinetics| ]]
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