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| '''Equilibrium chemistry''' is a concerned with systems in [[chemical equilibrium]]. The unifying principle is that the [[thermodynamic free energy|free energy]] of a system at equilibrium is the minimum possible, so that the slope of the free energy with respect to the [[reaction coordinate]] is zero.<ref>{{cite book|last=Denbeigh|first=K|title=The principles of chemical equilibrium|publisher=Cambridge University Press |location=Cambridge, U.K.|year=1981|edition=4th.|isbn=0-521-28150-4}}</ref><ref>{{cite book|last=de Nevers|first=N.|title=Physical and Chemical Equilibrium for Chemical Engineers|year=2002|isbn=978-0-471-07170-9}}</ref> This principle, applied to mixtures at equilibrium provides a definition of an [[equilibrium constant]]. Applications include [[acid dissociation constant|acid-base]], [[Host-guest chemistry|host-guest]], [[stability constants of complexes|metal-complex]], [[solubility]], [[partition coefficient|partition]], [[chromatography]] and [[redox]] equilibria.
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| == Thermodynamic equilibrium ==
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| {{main|dynamic equilibrium|thermodynamic equilibrium}}
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| A chemical system is said to be in equilibrium when the quantities of the chemical entities involved do not and ''cannot'' change in time without the application of an external influence. In this sense a system in chemical equilibrium is in a [[stable]] state. The system at chemical equilibrium will be at a constant temperature, pressure (or volume) and composition. It will be insulated from exchange of heat with the surroundings, that is, it is a [[closed system]]. A change of temperature, pressure (or volume) constitutes an external influence and the equilibrium quantities will change as a result of such a change. If there is a possibility that the composition might change, but the rate of change is negligibly slow, the system is said to be in a [[metastable]] state. The equation of chemical equilibrium can be expressed symbolically as
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| :reactant(s) {{eqm}} product(s)
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| The sign {{eqm}} means "are in equilibrium with". This definition refers to [[macroscopic]] properties. Changes do occur at the microscopic level of atoms and molecules, but to such a minute extent that they are not measurable and in a balanced way so that the macroscopic quantities do not change. Chemical equilibrium is a dynamic state in which forward and backward reactions proceed at such rates that the macroscopic composition of the mixture is constant. Thus, equilibrium sign {{eqm}} symbolizes the fact that reactions occur in both forward <math>\rightharpoonup </math> and backward <math>\leftharpoondown</math> directions.
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| [[File:Diag eq.svg|250px|right]]
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| A [[Steady state (chemistry)|steady state]], on the other hand, is not necessarily an equilibrium state in the chemical sense. For example, in a radioactive [[decay chain]] the concentrations of intermediate isotopes are constant because the rate of production is equal to the rate of decay. It is not a chemical equilibrium because the decay process occurs in one direction only.
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| Thermodynamic equilibrium is characterized by the free energy for the whole (closed) system being a minimum. For systems at constant volume the [[Helmholtz free energy]] is minimum and for systems at constant pressure the [[Gibbs free energy]] is minimum.<ref>Denbigh, Chapter 4</ref> Thus a metastable state is one for which the free energy change between reactants and products is not minimal even though the composition does not change in time.<ref>Denbigh, Chapter 5</ref>
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| The existence of this minimum is due to the free energy of mixing of reactants and products being always negative.<ref>Atkins, p 203</ref> For [[ideal solution]]s the [[enthalpy]] of mixing is zero, so the minimum exists because the [[entropy]] of mixing is always positive.<ref>Atkins, p 149</ref><ref>{{cite journal|last= Schultz|first=M.J.|year=1999|title=Why Equilibrium? Understanding the Role of Entropy of Mixing|journal=J. Chem. Educ.|volume=76|issue=10|page=1391|doi=10.1021/ed076p1391|bibcode = 1999JChEd..76.1391S }}</ref> The slope of the reaction free energy, δG<sub>r</sub> with respect to the [[reaction coordinate]], ξ, is zero when the free energy is at its minimum value. | |
| :<math>\delta G_r=\left(\frac{\partial G}{\partial \xi }\right)_{T,P}; \delta G_r(Eq)=0</math>
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| == Equilibrium constant ==
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| {{main|Equilibrium constant|Acid dissociation constant|Stability constants of complexes}}
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| [[Chemical potential]] is the partial molar free energy. The potential, μ<sub>i</sub>, of the ''i''th species in a chemical reaction is the partial derivative of the free energy with respect to the number of moles of that species, ''N''<sub>i</sub>
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| :<math>\mu_i=\left(\frac{\partial G}{\partial N_i}\right)_{T,P}</math>
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| A general chemical equilibrium can be written as<ref group=note>The general expression is not used much in chemistry. To help understand the notation consider the equilibrium
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| :H<sub>2</sub>SO<sub>4</sub> + 2 OH<sup>-</sup> {{eqm}} SO<sub>4</sub><sup>2-</sup> + 2 H<sub>2</sub>O
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| for this reaction ''n''<sub>1</sub>=1, ''n''<sub>2</sub>=2,''m''<sub>1</sub>=1 and ''m''<sub>2</sub>=2, Reactant<sub>1</sub>=H<sub>2</sub>SO<sub>4</sub>, Reactant<sub>2</sub>=OH<sup>-</sup>, Product<sub>1</sub>=SO<sub>4</sub><sup>2-</sup> and Product<sub>2</sub>=H<sub>2</sub>O.</ref>
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| :<math>\sum_j n_j Reactant_j\rightleftharpoons \sum_k m_k Product_k</math>
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| ''n''<sub>j</sub> are the [[stoichiometric coefficient]]s of the reactants in the equilibrium equation, and ''m''<sub>j</sub> are the coefficients of the products. The value of δ''G''<sub>r</sub> for these reactions is a function of the chemical potentials of all the species.
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| :<math>\delta G_r = \sum_k m_k \mu_k \, - \sum_j n_j \mu_j </math>
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| The chemical potential, μ<sub>i</sub>, of the ''i''th species can be calculated in terms of its [[activity (chemistry)|activity]], ''a''<sub>i</sub>. | |
| :<math>\mu_i = \mu_i^\ominus + RT \ln a_i</math>
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| μ<sub>i</sub><sup>[[File:StrikeO.png]]</sup> is the standard chemical potential of the species, ''R'' is the [[gas constant]] and ''T'' is the temperature. Setting the sum for the reactants ''j'' to be equal to the sum for the products, ''k'', so that δG<sub>r</sub> (Eq) = 0
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| :<math>\sum_j n_j(\mu_j^\ominus +RT\ln a_j)=\sum_k m_k(\mu_k^\ominus +RT\ln a_k) </math>
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| Rearranging the terms,
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| :<math>\sum_k m_k\mu_k^\ominus-\sum_j n_j\mu_j^\ominus =-RT \left(\sum_k \ln {a_k}^{m_k}-\sum_j \ln {a_j}^{n_j}\right)</math>
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| :<math>\Delta G^\ominus = -RT ln K.</math>
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| This relates the [[standard state|standard]] Gibbs free energy change, Δ''G''<sup>[[File:StrikeO.png]]</sup> to an [[equilibrium constant]], ''K'', the [[reaction quotient]] of activity values at equilibrium.
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| :<math>\Delta G^\ominus = \sum_k m_k\mu_k^\ominus-\sum_j n_j\mu_j^\ominus</math>
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| :<math>\ln K= \sum_k \ln {a_k}^{m_k}-\sum_j \ln {a_j}^{n_j};
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| K=\frac{\prod_k {a_k}^{m_k}}{\prod_j {a_j}^{n_j}}
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| </math>
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| It follows that any equilibrium of this kind can be characterized either by the standard free energy change or by the equilibrium constant. In practice concentrations are more useful than activities. Activities can be calculated from concentrations if the [[activity coefficient]] are known, but this is rarely the case. Sometimes activity coefficients can be calculated using, for example, [[Pitzer equations]] or [[Specific ion interaction theory]]. Otherwise conditions must be adjusted so that activity coefficients do not vary much. For ionic solutions this is achieved by using a background ionic medium at a high concentration relative to the concentrations of the species in equilibrium.
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| If activity coefficients are unknown they may be subsumed into the equilibrium constant, which becomes a concentration quotient.<ref name=FJCR>{{cite book|last=Rossotti|first=F.J.C|coauthors=Rossotti, H.|title=The Determination of Stability Constants|publisher=McGraw-Hill|year=1961}} Chapter 2, Activity and concentration quotients</ref> Each activity ''a''<sub>i</sub> is assumed to be the product of a concentration, [A<sub>i</sub>], and an activity coefficient, γ<sub>i</sub>
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| :<math>a_i=[A_i]\gamma_i</math>
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| This expression for activity is placed in the expression defining the equilibrium constant.<ref>Atkins, p 208</ref>
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| :<math>K=\frac{\prod_k {a_k}^{m_k}}{\prod_j {a_j}^{n_j}}
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| =\frac{\prod_k \left([A_k]\gamma_k\right)^{m_k}}{\prod_j \left([A_j]\gamma_j\right)^{n_j}}
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| =\frac{\prod_k [A_k]^{m_k}}{\prod_j [A_j]^{n_j}}\times
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| \frac{\prod_k {\gamma_k}^{m_k}}{\prod_j {\gamma_j}^{n_j}}
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| =\frac{\prod_k [A_k]^{m_k}}{\prod_j [A_j]^{n_j}}\times \Gamma
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| </math>
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| By setting the quotient of activity coefficients, Γ, equal to one <ref group=note>This is equivalent to defining a new equilibrium constant as ''K'' / Γ</ref> the equilibrium constant is defined as a quotient of concentrations.
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| :<math>K=\frac{\prod_k [A_k]^{m_k}}{\prod_j [A_j]^{n_j}}</math>
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| In more familiar notation, for a general equilibrium
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| :<math>\alpha A +\beta B ... \rightleftharpoons \sigma S+\tau T ...</math>
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| :<math>K=\frac{[S]^\sigma [T]^\tau ... } {[A]^\alpha [B]^\beta ...} </math>
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| This definition is much more practical, but an equilibrium constant defined in terms of concentrations is dependent on conditions. In particular, equilibrium constants for species in aqueous solution are dependent on [[ionic strength]], as the quotient of activity coefficients varies with the ionic strength of the solution. | |
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| The values of the standard free energy change and of the equilibrium constant are temperature dependent. To a first approximation, the [[van 't Hoff equation]] may be used. | |
| :<math> \frac{d \ln K}{dT}\ = \frac{\Delta H^\ominus}{RT^2} \mbox{ or } \frac{d \ln K}{d(1/T)}\ = -\frac{\Delta H^\ominus}{R}</math>
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| This shows that when the reaction is exothermic (Δ''H''<sup>[[File:StrikeO.png]]</sup>, the standard [[enthalpy]] change, is negative), then ''K'' decreases with increasing temperature, in accordance with [[Le Chatelier's principle]]. The approximation involved is that the standard enthalpy change, Δ''H''<sup>[[File:StrikeO.png]]</sup>, is independent of temperature, which is a good approximation only over a small temperature range. Thermodynamic arguments can be used to show that
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| :<math>\left(\frac{\partial H}{\partial T} \right)_p=C_p</math>
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| where C<sub>p</sub> is the [[Specific heat capacity|heat capacity]] at constant pressure.<ref>{{cite book|last=Blandamer|first=M.J.|title=Chemical equilibria in solution : dependence of rate and equilibrium constants on temperature and pressure|publisher=Ellis Horwood/PTR Prentice Hall|location=New York|year=1992|isbn=0-13-131731-8}}</ref>
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| | |
| === Equilibria involving gases ===
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| When dealing with gases, [[fugacity]], ''f'', is used rather than activity. However, whereas activity is [[dimension]]less, fugacity has the dimension of [[pressure]]. A consequence is that chemical potential has to be defined in terms of a standard pressure, ''p''<sup>[[File:StrikeO.png]]</sup><ref>Atkins, p 111</ref>
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| :<math>\mu=\mu^\ominus +RT \ln \frac{f}{p^\ominus}</math>
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| By convention ''p''<sup>[[File:StrikeO.png]]</sup> is usually taken to be 1 [[bar (unit)|bar]]
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| Fugacity can be expressed as the product of [[partial pressure]], ''p'', and a fugacity coefficient, Φ
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| :<math>f=p\Phi</math> | |
| Fugacity coefficients are dimensionless and can be obtained experimentally at specific temperature and pressure, from measurements of deviations from [[ideal gas]] behaviour. Equilibrium constants are defined in terms of fugacity. If the gases are at sufficiently low pressure that they behave as ideal gases, the equilibrium constant can be defined as a quotient of partial pressures.
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| An example of gas-phase equilibrium is provided by the [[Haber-Bosch]] process of [[ammonia]] synthesis.
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| :<math>N_2 + 3H_2\leftrightharpoons 2NH_3; K=\frac{{f_{NH_3}}^2}{f_{N_2}{f_{H_2}}^3}</math>
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| This reaction is strongly [[exothermic]], so the equilibrium constant decreases with temperature. However, a temperature of around 400°C is required in order to achieve a reasonable rate of reaction with currently available [[catalyst]]s. Formation of ammonia is also favoured by high pressure, as the volume decreases when the reaction takes place. It is interesting to note that the same reaction, [[nitrogen fixation]], occurs at ambient temperatures in nature, when the catalyst is an [[enzyme]] such as [[nitrogenase]]. Much energy is needed initially to break the N-N triple bond even though the overall reaction is exothermic.
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| Gas-phase equilibria occur during [[combustion]] and were studied as early as 1943 in connection with the development of the [[V-2 rocket|V2]] [[rocket engine]].<ref>{{cite journal| last=Damköhler| first=G| coauthors=Edse, R.|year=1943|title=Composition of dissociating combustion gases and the calculation of simultaneous equilibria|journal=Z. Elektrochem.|volume=49|pages=178–802}}</ref>
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| The calculation of composition for a gaseous equilibrium at constant pressure is often carried out using ΔG values, rather than equilibrium constants.<ref>{{cite book|last=Van Zeggeren|first=F.|coauthors=Storey, S. H. |title=The computation of chemical equilibria|publisher=Cambridge University Press|location=London|year=1970|isbn=0-521-07630-7}}</ref><ref>{{cite book|last=Smith|first=W.R.|coauthors=Missen, R.W.|title=Chemical reaction equilibrium analysis : theory and algorithms |publisher= Krieger|location=Malabar, Fla.|year=1991|isbn=0-89464-584-6}}</ref> | |
| | |
| === Multiple equilibria ===
| |
| Two or more equilibria can exist at the same time. When this is so, equilibrium constants can be ascribed to individual equilibria, but they are not always unique. For example, three equilibrium constants can be defined for a [[dibasic]] [[acid]], H<sub>2</sub>A.<ref>*{{cite book|last=Hartley|first=F.R.|coauthors= Burgess, C.; Alcock., R. M.|title=Solution equilibria |publisher=Ellis Horwood|location= New York : Halsted Press|year=1980|isbn=0-470-26880-8 }}</ref><ref group=note>The definitions given are [[equilibrium constant#Association and dissociation constants|association constants]]. A dissociation constant is the reciprocal of an association constant</ref>
| |
| :<math>A^{2-} + H^+ \rightleftharpoons HA^-; K_1=\frac{[HA^-]}{[H^+][A^{2-}]}</math>
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| :<math>HA^- + H^+ \rightleftharpoons H_2A; K_2=\frac{[H_2A]}{[H^+][HA^-]}</math>
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| :<math>A^{2-} + 2H^+ \rightleftharpoons H_2A; \beta_2=\frac{[H_2A]}{[H^+]^2[A^{2-}]}</math>
| |
| The three constants are not independent of each other and it is easy to see that ''β''<sub>2</sub>= ''K''<sub>1</sub>''K''<sub>2</sub>. The constants ''K''<sub>1</sub> and ''K''<sub>2</sub> are stepwise constants and ''β'' is an example of an overall constant.
| |
| | |
| === Speciation ===
| |
| [[File:Citric acid speciation.png|thumb|200 px|alt=This image plots the relative percentages of the protonation species of citric acid as a function of p H. Citric acid has three ionisable hydrogen atoms and thus three p K A values. Below the lowest p K A, the triply protonated species prevails; between the lowest and middle p K A, the doubly protonated form prevails; between the middle and highest p K A, the singly protonated form prevails; and above the highest p K A, the unprotonated form of citric acid is predominant.|Speciation diagram for a solution of citric acid as a function of pH.]]
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| | |
| The concentrations of species in equilibrium are usually calculated under the assumption that activity coefficients are either known or can be ignored. In this case, each equilibrium constant for the formation of a complex in a set of multiple equilibria can be defined as follows
| |
| | |
| :<math>\alpha A +\beta B \ldots \rightleftharpoons A_\alpha B_\beta\ldots; K_{\alpha \beta \ldots}=\frac{[A_\alpha B_\beta \ldots]} {[A]^\alpha [B]^\beta \ldots}</math>
| |
| | |
| The concentrations of species containing reagent A are constrained by a condition of [[conservation of mass|mass-balance]], that is, the total (or analytical) concentration, which is the sum of all species' concentrations, must be constant. There is one mass-balance equation for each reagent of the type
| |
| :<math>T_A = [A] +\sum [A_\alpha B_\beta \ldots]= [A] +\sum \left(\alpha K_{\alpha \beta}\ldots[A]^\alpha [B]^\beta \ldots\right)</math>
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| | |
| There are as many mass-balance equations as there are reagents, A, B .., so if the equilibrium constant values are known, there are ''n'' mass-balance equations in ''n'' unknowns, [A], [B].., the so-called free reagent concentrations. Solution of these equations gives all the information needed to calculate the concentrations of all the species.<ref name=DJL/>
| |
| | |
| Thus, the importance of an equilibrium constants lies in the fact that, once their values have been determined by experiment, they can be used to calculate the concentrations, known as the [[speciation of ions|speciation]], of mixtures that contain the relevant species.
| |
| | |
| === Determination ===
| |
| {{main|Determination of equilibrium constants}}
| |
| There are five main types of experimental data that are used for the determination of solution equilibrium constants. Potentiometric data obtained with a [[glass electrode]] are the most widely used with aqueous solutions. The others are [[Spectrophotometry|Spectrophotometric]], [[Fluorescence]] (luminescence) measurements and [[NMR]] [[chemical shift]] measurements;<ref name=FJCR/><ref>{{cite book|last=Martell|first=A.E.|coauthors=Motekaitis.|others=R.J.|title=Determination and use of stability constants|publisher=VCH Publishers|location=New York|year=1992|edition=2nd|isbn=1-56081-516-7 }}</ref> simultaneous measurement of K and <math>\Delta</math>H for 1:1 adducts in biological systems is routinely carried out using [[Isothermal Titration Calorimetry]].
| |
| | |
| The experimental data will comprise a set of data points. At the i'th data point, the analytical concentrations of the reactants, <math>T_A(i)</math>, <math>T_B(i)</math> etc. will be experimentally known quantities and there will be one or more measured quantities, '''y'''<sub>i</sub>, that depend in some way on the analytical concentrations and equilibrium constants. A general computational procedure has three main components.
| |
| # Definition of a chemical model of the equilibria. The model consists of a list of reagents, A, B, etc. and the complexes formed from them, with stoichiometries A<sub>p</sub>B<sub>q</sub>... Known or estimated values of the equilibrium constants for the formation of all complexes must be supplied.
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| # Calculation of the concentrations of all the chemical species in each solution. The free concentrations are calculated by solving the equations of mass-balance, and the concentrations of the complexes are calculated using the equilibrium constant definitions. A quantity corresponding to the observed quantity can then be calculated using physical principles such as the [[Nernst equation#Nernst potential|Nernst potential]] or [[Beer-Lambert law]] which relate the calculated quantity to the concentrations of the species.
| |
| # Refinement of the equilibrium constants. Usually a [[Non-linear least squares]] procedure is used. A weighted sum of squares, U, is minimized.
| |
| ::<math>U=\sum^{i=1}_{i=np} w_i\left(y_i^{observed} - y_i^{calculated}\right)^2</math>
| |
| :The weights, ''w''<sub>i</sub> and quantities ''y'' may be vectors. Values of the equilibrium constants are refined in an iterative procedure.<ref name=DJL>{{cite book|last=Leggett|first=D.J. (Editor)|title=Computational methods for the determination of formation constants |publisher=Plenum Press|location=New York|year=1985|isbn=0-306-41957-2}}</ref>
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| | |
| == Acid-base equilibria ==
| |
| {{main|Acid dissociation constant}}
| |
| [[Brønsted–Lowry acid-base theory|Brønsted and Lowry]] characterized an acid-base equilibrium as involving a proton exchange reaction:<ref>
| |
| {{cite book |last=Bell |first=R.P. |title=The Proton in Chemistry |publisher=Chapman & Hall |location=London |year=1973 |edition=2nd |isbn=0-8014-0803-2}} Includes discussion of many organic Brønsted acids.</ref><ref name=SA>
| |
| {{cite book |last=Shriver |first=D.F |coauthors=Atkins, P.W. |title=Inorganic Chemistry |edition=3rd |year=1999 |publisher=Oxford University Press |location=Oxford |isbn=0-19-850331-8}} Chapter 5: Acids and Bases</ref><ref>{{cite book |title=Inorganic Chemistry |last=Housecroft |first=C.E. |coauthors=Sharpe, A.G. |year=2008 |publisher=Prentice Hall |edition=3rd |isbn=0-13-175553-6 }} Chapter 6: Acids, Bases and Ions in Aqueous Solution</ref>
| |
| :acid + base {{Eqm}} conjugate base + conjugate acid.
| |
| An acid is a proton donor; the proton is transferred to the base, a proton acceptor, creating a conjugate acid. For aqueous solutions of an acid HA, the base is water; the conjugate base is A<sup>−</sup> and the conjugate acid is the solvated hydrogen ion. In solution chemistry, it is usual to use H<sup>+</sup> as an abbreviation for the solvated hydrogen ion, regardless of the solvent. In aqueous solution H<sup>+</sup> denotes a [[hydronium#Solvation|solvated hydronium ion]].<ref name=Headrick>{{cite journal |last=Headrick |first=J.M. |coauthors=Diken, E.G.; Walters, R. S.; Hammer, N. I.; Christie, .A. ; Cui, J.; Myshakin, E.M.; Duncan, M.A.; Johnson, M.A.; Jordan, K.D. |year=2005 |title=Spectral Signatures of Hydrated Proton Vibrations in Water Clusters |journal=Science |volume=308 |issue=5729 |pages=1765–69 |doi=10.1126/science.1113094 |pmid=15961665 |bibcode=2005Sci...308.1765H}}</ref><ref name=Smiechowski>{{cite journal |last=Smiechowski |first=M. |coauthors=Stangret, J. |year=2006 |title=Proton hydration in aqueous solution: Fourier transform infrared studies of HDO spectra |journal=J. Chem. Phys. |volume=125 |issue=20 |pages=204508–204522 |doi=10.1063/1.2374891 |pmid=17144716|bibcode = 2006JChPh.125t4508S }}</ref><ref group=note name=proton>The bare proton does not exist in aqueous solution. It is a very strong acid and combines the base, water, to form the hydronium ion
| |
| :H<sup>+</sup> + H<sub>2</sub>O → H<sub>3</sub>O<sup>+</sup>
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| The hydronium ion forms various weak complexes by hydrogen bonding with more water molecules</ref>
| |
| | |
| The Brønsted–Lowry definition applies to other solvents, such as [[dimethyl sulfoxide]]: the solvent S acts as a base, accepting a proton and forming the conjugate acid SH<sup>+</sup>.
| |
| A broader definition of acid dissociation includes [[hydrolysis]], in which protons are produced by the splitting of water molecules. For example, [[boric acid]], B(OH)<sub>3</sub>, acts as a weak acid, even though it is not a proton donor, because of the hydrolysis equilibrium
| |
| :B(OH)<sub>3</sub> + H<sub>2</sub>O {{eqm}} B(OH)<sub>4</sub><sup>−</sup> + H<sup>+</sup>.
| |
| Similarly, [[hydrolysis#Hydrolysis of metal aqua ions|metal ion hydrolysis]] causes ions such as <span style="white-space:nowrap;">[Al(H<sub>2</sub>O)<sub>6</sub>]<sup>3+</sup></span> to behave as weak acids:<ref name=Burgess>{{cite book |title=Metal Ions in Solution |last=Burgess |first=J. |year=1978 |publisher=Ellis Horwood |isbn=0-85312-027-7}} Section 9.1 "Acidity of Solvated Cations" lists many p''K''<sub>a</sub> values.</ref>
| |
| :[Al(H<sub>2</sub>O)<sub>6</sub>]<sup>3+</sup> {{eqm}} [Al(H<sub>2</sub>O)<sub>5</sub>(OH)]<sup>2+</sup> + H<sup>+</sup>.
| |
| | |
| Acid-base equilibria are important in a very wide [[acid dissociation constant#Applications and significance|range of applications]], such as [[acid-base homeostasis]], [[ocean acidification]], [[pharmacology]] and [[analytical chemistry]].
| |
| | |
| ==Host-guest equilibria==
| |
| {{main|host-guest chemistry}}
| |
| A host-guest complex, also known as a donor-acceptor complex, may be formed from a [[Lewis base]], B, and a [[Lewis acid]], A. The host may be either a donor or an acceptor. In [[biochemistry]] host-guest complexes are known as [[receptor (biochemistry)|receptor]]-ligand complexes; they are formed primarily by [[non-covalent bond]]ing. Many host-guest complexes has 1:1 stoichiometry, but many others have more complex structures. The general equilibrium can be written as
| |
| :''p''A +''q''B {{eqm}} A<sub>p</sub>B<sub>q</sub>
| |
| The study of these complexes is important for [[supramolecular chemistry]]<ref>{{cite book|last=Lehn|first=J.-M.|title=Supramolecular Chemistry|publisher=Wiley-VCH |year=1995|isbn=978-3-527-29311-7}}</ref><ref>{{cite book|last=Steed|first=J.W.|coauthors=Atwood, L.J.|title=Supramolecular chemistry |publisher=Wiley|year=2000|isbn=0-471-98831-6 }}</ref> and [[molecular recognition]]. The objective of these studies is often to find systems with a high [[binding selectivity]] of a host (receptor) for a particular target molecule or ion, the guest or ligand. An application is the development of [[chemical sensor]]s.<ref>{{cite book|last=Cattrall|first=R.W.|title=Chemical sensors|publisher=Oxford University Press|year=1997|isbn=0-19-850090-4 }}</ref> Finding a drug which either blocks a receptor, an [[antagonist]] which forms a strong complex the receptor, or activate it, an [[agonist]], is an important pathway to [[drug discovery]].<ref>{{cite web|url=http://www.elsevier.com/wps/find/journaldescription.cws_home/30921/description#description|title=Drug discovery today|accessdate=23 March 2010}}</ref>
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| | |
| == Complexes of metals ==
| |
| {{main|Stability constants of complexes}}
| |
| [[File:Al hydrolysis speciation diagram.png|thumb|Speciation diagram for aluminium in aqueous solution as a function of pH. A variety of hydroxo complexes are formed, including aluminium hydroxide, (Al(OH)<sub>3</sub>(s), which is insoluble at pH ~6.5]]
| |
| The formation of a complex between a metal ion, M, and a ligand, L, is in fact usually a substitution reaction. For example, In [[aqueous solution]]s, metal ions will be present as [[Metal ions in aqueous solution|aqua-ions]], so the reaction for the formation of the first complex could be written as<ref group=note name=charge>Electrical charges are omitted from such expressions because the ligand, L, may or may not carry an electrical charge.</ref>
| |
| :[M(H<sub>2</sub>O)<sub>n</sub>] + L {{eqm}} [M(H<sub>2</sub>O)<sub>n-1</sub>L] +H<sub>2</sub>O
| |
| However, since water is in vast excess, the concentration of water is usually assumed to be constant and is omitted from equilibrium constant expressions. Often, the metal and the ligand are in competition for protons.<ref group=note name=proton/> For the equilibrium
| |
| :pM + qL +rH {{eqm}} M<sub>p</sub>L<sub>q</sub>H<sub>r</sub>
| |
| a stability constant can be defined as follows.<ref>{{cite book |title=Chemistry of Complex Equilibria |last=Beck |first=M.T. |coauthors=Nagypál, I. |year=1990 |publisher=Horwood |isbn=0-85312-143-5}} Section 2.2, Types of complex equilibrium constants</ref><ref>{{cite book|last=Hartley|first=F.R.|coauthors= Burgess, C.; Alcock., R. M.|title=Solution equilibria |publisher=Ellis Horwood|location= New York : Halsted Press|year=1980|isbn=0-470-26880-8 }}
| |
| </ref>
| |
| :<math>\beta_{pqr}=\mathrm{\frac{[M_pL_qH_r] } {[M]^p [L]^q [H]^r}}</math>
| |
| The definition can easily be extended to include any number of reagents. It includes [[hydroxide]] complexes because the concentration of the hydroxide ions is related to the concentration of hydrogen ions by the [[self-ionization of water]]
| |
| :[OH<sup>-</sup>] = K<sub>W</sub> [H<sup>+</sup>]<sup>-1</sup>
| |
| Stability constants defined in this way, are ''association'' constants. This can lead to some confusion as [[acid dissociation constant|p''K''<sub>a</sub> values]] are ''dissociation'' constants. In general purpose computer programs it is customary to define all constants as association constants. The relationship between the two types of constant is given in [[equilibrium constant#Association and dissociation constants|association and dissociation constants]].
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| | |
| In [[biochemistry]], an oxygen molecule can bind to an iron (II) atom in a [[heme]] [[prosthetic group]] in [[hemoglobin]]. The equilibrium is usually written, denoting hemoglobin by Hb, as
| |
| : Hb + O<sub>2</sub> {{eqm}} HbO<sub>2</sub>
| |
| but this representation is incomplete as the [[Bohr effect]] shows that the equilibrium concentrations are pH-dependent. A better representation would be
| |
| : [HbH]<sup>+</sup> + O<sub>2</sub> {{eqm}} HbO<sub>2</sub> + H<sup>+</sup>
| |
| as this shows that when hydrogen ion concentration increases the equilibrium is shifted to the left in accordance with [[Le Chatelier's principle]]. Hydrogen ion concentration can be increased by the presence of carbon dioxide, which behaves as a weak acid.
| |
| :H<sub>2</sub>O + CO<sub>2 </sub> {{eqm}} HCO<sub>3</sub><sup>-</sup> + H<sup>+</sup>
| |
| The iron atom can also bind to other molecules such as [[carbon monoxide]]. Cigarette smoke contains some carbon monoxide so the equilibrium
| |
| :HbO<sub>2</sub> + CO {{eqm}} Hb(CO) + O<sub>2</sub>
| |
| is established in the blood of cigarette smokers.
| |
| | |
| [[Chelation therapy]] is based on the principle of using [[chelate effect|chelating ligands]] with a high [[binding selectivity]] for a particular metal to remove that metal from the human body.
| |
| | |
| Complexes with [[polyamino carboxylic acid]]s find a wide range of applications. [[EDTA#Uses|EDTA]] in particular is used extensively.
| |
| | |
| == Redox equilibria ==
| |
| A reduction-oxidation ([[redox]]) equilibrium can be handled in exactly the same way as any other chemical equilibrium. For example
| |
| :<math>Fe^{2+} + Ce^{4+} \rightleftharpoons Fe^{3+} + Ce^{3+}; K=\frac{[Fe^{3+}][Ce^{3+}]}{[Fe^{2+}][Ce^{4+}]}</math>
| |
| However, in the case of redox reactions it is convenient to split the overall reaction into two half-reactions. In this example
| |
| :<math>Fe^{3+} + e^- \rightleftharpoons Fe^{2+} </math>
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| :<math>Ce^{4+} + e^- \rightleftharpoons Ce^{3+}</math>
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| The standard free energy change, which is related to the equilibrium constant by
| |
| :<math>\Delta G^\ominus=-RT \ln K\,</math>
| |
| can be split into two components,
| |
| :<math>\Delta G^\ominus=\Delta G^\ominus_{Fe}+\Delta G^\ominus_{Ce}</math>
| |
| The concentration of free electrons is effectively zero as the electrons are transferred directly from the reductant to the oxidant. The [[standard electrode potential]], ''E''<sup>0</sup> for the each half-reaction is related to the standard free energy change by<ref>Atkins, Chapter 7, section "Equilibrium electrochemistry"</ref>
| |
| :<math>\Delta G^\ominus_{Fe} = -nFE^0_{Fe};\Delta G^\ominus_{Ce} = -nFE^0_{Ce} </math>
| |
| where ''n'' is the number of electrons transferred and ''F'' is the [[Faraday constant]]. Now, the free energy for an actual reaction is given by
| |
| :<math>\Delta G=\Delta G^\ominus +RT \ln Q </math>
| |
| where R is the [[gas constant]] and ''Q'' a [[reaction quotient]]. Strictly speaking ''Q'' is a quotient of activities, but it is common practice to use concentrations instead of activities. Therefore
| |
| :<math>E_{Fe}=E_{Fe}^0 + \frac{RT}{nF} \ln \frac{[Fe^{3+}]}{[Fe^{2+}]}</math>
| |
| For any half-reaction, the redox potential of an actual mixture is given by the generalized expression<ref group=note>The alternative expression
| |
| :<math>E=E^0 - \frac{RT}{nF} \ln \frac{[\text{reduced species}]}{[\text{oxidized species}]}</math>
| |
| is sometimes used, as in [[Nernst equation]]</ref>
| |
| :<math>E=E^0 + \frac{RT}{nF} \ln \frac{[\text{oxidized species}]}{[\text{reduced species}]}</math>
| |
| This is an example of the [[Nernst equation]]. The potential is known as a reduction potential. Standard electrode potentials are available in a [[Standard electrode potential (data page)|table of values]]. Using these values, the actual electrode potential for a redox couple can be calculated as a function of the ratio of concentrations.
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| | |
| The equilibrium potential for a general redox half-reaction (See [[#Equilibrium constant]] above for an explanation of the symbols)
| |
| :<math>\alpha A +\beta B ... +ne^- \rightleftharpoons \sigma S+\tau T ...</math>
| |
| is given by<ref>Mendham, pp 59-64</ref>
| |
| :<math>E=E^\ominus + \frac{RT}{nF}\ln\frac{{\{S\}} ^\sigma {\{T\}}^\tau ... } {{\{A\}}^\alpha {\{B\}}^\beta ...}</math>
| |
| Use of this expression allows the effect of a species not involved in the redox reaction, such as the hydrogen ion in a half-reaction such as
| |
| :MnO<sub>4</sub><sup>-</sup> + 8H<sup>+</sup> +5e<sup>-</sup> {{eqm}} Mn<sup>2+</sup> + 4H<sub>2</sub>O
| |
| to be taken into account.
| |
| | |
| The equilibrium constant for a full redox reaction can be obtained from the standard redox potentials of the constituent half-reactions. At equilibrium the potential for the two half-reactions must be equal to each other and, of course, the number of electrons exchanged must be the same in the two half reactions.<ref>Mendham, section 2.33, p63 for details</ref>
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| | |
| Redox equilibria play an important role in the [[electron transport chain]]. The various [[cytochrome]]s in the chain have different standard redox potentials, each one adapted for a specific redox reaction. This allows, for example, atmospheric [[oxygen]] to be reduced in [[photosynthesis]]. A distinct family of cytochromes, the [[cytochrome P450 oxidase]]s, are involved in [[steroidogenesis]] and [[detoxification]].
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| | |
| == Solubility ==
| |
| {{main|solubility equilibrium}}
| |
| When a [[solution|solute]] forms a [[saturated solution]] in a [[solvent]], the concentration of the solute, at a given temperature, is determined by the equilibrium constant at that temperature.<ref>{{cite book|last=Hefter|first=G.T.|coauthors=Tomkins, R.P.T. (editors),|title=The Experimental Determination of Solubilities|publisher=Wiley|year=2003|isbn=0-471-49708-8}}</ref>
| |
| :<math>ln K=-RT \ln \left(\frac{\sum_k {a_k}^{m_k} (solution)}{a (solid)}\right)</math>
| |
| | |
| The activity of a pure substance in the solid state is one, by definition, so the expression simplifies to
| |
| :<math>ln K=-RT \ln \left(\sum_k {a_k}^{m_k} (solution)\right)</math>
| |
| | |
| If the solute does not dissociate the summation is replaced by a single term, but if dissociation occurs, as with ionic substances
| |
| :<math>K_{SP}=\prod_k{{a_k}^{m_k}}</math>
| |
| | |
| For example, with Na<sub>2</sub>SO<sub>4</sub> ''m''<sub>1</sub>=2 and ''m''<sub>2</sub>=1 so the solubility product is written as
| |
| :<math>K_{SP}=[Na^+]^2[SO_4^{2-}]</math>
| |
| Concentrations, indicated by [..], are usually used in place of activities, but activity must be taken into account of the presence of another salt with no ions in common, the so-called salt effect. When another salt is present that has an ion in common, the [[common-ion effect]] comes into play, reducing the solubility of the primary solute.<ref>Mendham, pp 37-45</ref>
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| | |
| ==Partition==
| |
| {{main|partition coefficient|liquid-liquid extraction}}
| |
| When a solution of a substance in one solvent is brought into equilibrium with a second solvent that is immiscible with the first solvent, the dissolved substance may be partitioned between the two solvents. The ratio of concentrations in the two solvents is known as a [[partition coefficient]] or [[distribution coefficient]].<ref group=note>The distinction between a partition coefficient and a [[distribution coefficient]] is of historical significance only.</ref> The partition coefficient is defined as the ratio of the [[analytical concentration]]s of the solute in the two phases. By convention the value is reported in logarithmic form.
| |
| : <math>\log p = \log \frac{[solute]_\mbox{organic phase}}{[solute]_\mbox{aqueous phase}}</math>
| |
| | |
| The partition coefficient is defined at a specified temperature and, if applicable, pH of the aqueous phase. Partition coefficients are very important in [[pharmacology]] because they determine the extent to which a substance can pass from the blood (an aqueous solution) through a cell wall which is like an organic solvent. They are usually measured using water and [[1-Octanol|octanol]] as the two solvents. Many pharmaceutical compounds are [[weak acid]]s or [[weak base]]s. Such a compound may exist with a different extent of protonation depending on [[pH]] and the [[acid dissociation constant]]. Because the organic phase has a low [[dielectric constant]] the species with no electrical charge will be the most likely one to pass from the aqueous phase to the organic phase. Even at pH 7-7.2, the range of biological pH values, the aqueous phase may support an equilibrium between more than one protonated form. Log ''p'' is determined from the analytical concentration of the substance in the aqueous phase, that is, the sum of the concentration of the different species in equilibrium.
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| | |
| [[File:Separation02.ogg|frame|right|300px|An organic [[MTBE]] solution is extracted with [[aqueous]] sodium bicarbonate solution. This base removes [[benzoic acid]] as [[benzoate]] but leaves non-acidic [[benzil]] (yellow) behind in the upper organic phase.]]
| |
| Solvent extraction is used extensively in separation and purification processes. In its simplest form a reaction is performed in an organic solvent and unwanted by-products are removed by extraction into water at a particular pH.
| |
| | |
| A metal ion may be extracted from an aqueous phase into an organic phase in which the salt is not soluble, by adding a [[ligand]]. The ligand, L<sup>a-</sup>, forms a complex with the metal ion, M<sup>b+</sup>, [ML<sub>x</sub>]<sup>(b-ax)+</sup> which has a strongly [[hydrophobic]] outer surface. If the complex has no electrical charge it will be extracted relatively easily into the organic phase. If the complex is charged, it is extracted as an [[ion pair]]. The additional ligand is not always required. For example, [[uranyl nitrate]], UO<sub>2</sub>(NO<sub>3</sub>)<sub>2</sub>, is soluble in [[diethyl ether]] because the solvent itself acts as a ligand. This property was used in the past for separating uranium from other metals whose salts are not soluble in ether. Currently extraction into [[kerosene]] is preferred, using a ligand such as [[tri-n-butyl phosphate]], TBP. In the [[PUREX]] process, which is commonly used in [[nuclear reprocessing]], uranium(VI) is extracted from strong nitric acid as the electrically neutral complex [UO<sub>2</sub>(TBP)<sub>2</sub>(NO<sub>3</sub>)<sub>2</sub>]. The strong nitric acid provides a high concentration of nitrate ions which pushes the equilibrium in favour of the weak nitrato complex. Uranium is recovered by back-extraction (stripping) into weak nitric acid. Plutonium(IV) forms a similar complex, [PuO<sub>2</sub>(TBP)<sub>2</sub>(NO<sub>3</sub>)<sub>2</sub>] and the plutonium in this complex can be reduced to separate it from uranium.
| |
| | |
| Another important application of solvent extraction is in the separation of the [[lanthanoid]]s. This process also uses TBP and the complexes are extracted into kerosene. Separation is achieved because the [[stability constants of complexes|stability constant]] for the formation of the TBP complex increases as the size of the lanthanoid ion decreases.
| |
| | |
| An instance of ion-pair extraction is in the use of a ligand to enable oxidation by [[potassium permanganate]], KMnO<sub>4</sub>, in an organic solvent. KMnO<sub>4</sub> is not soluble in organic solvents. When a ligand, such as a [[crown ether]] is added to an aqueous solution of KMnO<sub>4</sub>, it forms a hydrophobic complex with the potassium cation which allows the uncharged ion-pair, {[KL]<sup>+</sup>[MnO<sub>4</sub>]<sup>-</sup>} to be extracted into the organic solvent. See also: [[phase-transfer catalysis]].
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| | |
| More complex partitioning problems (i.e. 3 or more phases present) can sometimes be handled with a [[fugacity capacity]] approach.
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| == Chromatography ==
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| {{main|Chromatography}}
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| In chromatography substances are separated by partition between a stationary phase and a mobile phase. The analyte is dissolved in the mobile phase, and passes over the stationary phase. Separation occurs because of differing affinities of the [[analyte]]s for the stationary phase. A distribution constant, ''K''<sub>d</sub> can be defined as
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| :<math>K_d=\frac{a_s}{a_m}</math>
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| where ''a''<sub>s</sub> and ''a''<sub>m</sub> are the equilibrium activities in the stationary and mobile phases respectively. It can be shown that the rate of migration, <math>\bar{\nu}</math>, is related to the distribution constant by
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| :<math>\bar{\nu} \propto \frac{1}{1+fK_d}.</math>
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| ''f'' is a factor which depends on the volumes of the two phases.<ref>{{cite book |last=Skoog |first=D.A |coauthors=West, D.M.; Holler, J.F.; Crouch, S.R. |title=Fundamentals of Analytical Chemistry |publisher=Thomson Brooks/Cole |year=2004 |edition=8th |isbn=0-03-035523-0}} Section 30E, Chromatographic separations</ref> Thus, the higher the affinity of the solute for the stationary phase, the slower the migration rate.
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| There is a wide variety of chromatographic techniques, depending on the nature of the stationary and mobile phases. When the stationary phase is solid, the analyte may form a complex with it. A [[water softener]] functions by selective complexation with a [[sulfonate]] [[ion exchange resin]]. Sodium ions form relatively weak complexes with the resin. When [[hard water]] is passed through the resin, the divalent ions of magnesium and calcium displace the sodium ions and are retained on the resin, R.
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| : RNa + M<sup>2+</sup> {{eqm}} RM<sup>+</sup> + Na<sup>+</sup>
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| The water coming out of the column is relatively rich in sodium ions<ref group=note>Feeding babies formula made up with sodium rich water can lead to [[hypernatremia]].</ref> and poor in calcium and magnesium which are retained on the column. The column is regenerated by passing a strong solution of sodium chloride through it, so that the resin- sodium complex is again formed on the column. [[Ion-exchange chromatography]] utilizes a resin such as [[chelex 100]] in which [[iminodiacetic acid|iminodiacetate]] residues, attached to a polymer backbone, form [[chelate]] complexes of differing strengths with different metal ions, allowing the ions such as Cu<sup>2+</sup> and Ni<sup>2+</sup> to be separated chromatographically.
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| Another example of complex formation is in [[Chromatography#Chiral chromatography|chiral chromatography]] in which is used to separate [[enantiomer]]s from each other. The stationary phase is itself chiral and forms complexes selectively with the enantiomers. In other types of chromatography with a solid stationary phase, such as [[thin layer chromatography]] the analyte is selectively [[adsorbed]] onto the solid.
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| In [[gas-liquid chromatography]] (GLC) the stationary phase is a liquid such as [[polydimethylsiloxane]], coated on a glass tube. Separation is achieved because the various components in the gas have different solubility in the stationary phase. GLC can be used to separate literally hundreds of components in a gas mixture such as [[cigarette smoke]] or [[essential oil]]s, such as [[lavender oil#Composition|lavender oil]].
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| == See also ==
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| *[[Thermodynamic databases for pure substances]]
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| == External links ==
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| *Chemical Equilibrium [http://download-book.net/Chemical-Equilibrium-ppt-pdf.html Downloadable book]
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| == Notes ==
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| {{reflist|group=note}}
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| == References ==
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| *{{cite book |title=Physical Chemistry |last=Atkins |first=P.W. |coauthors=de Paula, J. |year=2006 | publisher=Oxford University Press |edition=8th.|isbn=0-19-870072-5}}
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| *{{cite book|last=Denbeigh|first=K|title=The principles of chemical equilibrium|publisher=Cambridge University Press |location=Cambridge, U.K.|year=1981|edition=4th.|isbn=0-521-28150-4}} A classic book, last reprinted in 1997.
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| * {{VogelQuantitative}}
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| {{reflist|2}}
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| {{Chemical equilibria}}
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| [[Category:Equilibrium chemistry]]
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