A Wetpaint Site | TV Fandex 100

EasyEdit
Edit tags
(what's this?What are these tools?
People just like you can add or edit the content on this site. If you want to try editing, but aren't ready to add to this site, try our demo area.
Read more about editing pages at Wetpaint Central.
)
Report page
Share this

Equilibrium constant

In chemistry, the equilibrium constant K is a value defining the ratio of the concentrations of the products to the concentrations of the reactants in a reversible chemical reaction, at the point when the reactants and products reach steady-state values, a point otherwise known as equilibrium. [1] Given a reversible reaction of the form:

$x A + y B \rightleftharpoons z C + w D$

where x, y, z, and w are the stoichiometric coefficients, the equilibrium constant is defined by follow equation:

$K = \frac{[C]^z [D]^w} {[A]^x [B]^y} \,$

where [A], [B], [C], and [D] are the concentrations of the various reactants and products at the equilibrium.

Thermodynamics
The driving force of any reaction are the various chemical affinities of the reactants and products, in relation to each other. The affinity A for an isothermal-isobaric reaction, is defined by the variation of the Gibbs free energy per change in the extent or progress of the reaction:

$A=-\left(\frac{\partial G}{\partial \xi}\right)_{p,T}$

or, in terms of Gibbs free energy change:

$A= -\Delta G \,$

at equilibrium the affinities will be satisfied, as quantified by the condition ΔG=0. This condition can be expressed in terms of the equilibrium constant as:

$\ \Delta G^\circ = -RT \ln K$

where by solving for K the one arrives at an expression:

$K = e^{\left (-\Delta G^\circ /RT \right )}$

relating the equilibrium constant to Gibbs free energy and temperature: [2]

History
In 1868, in order to ascertain molecular weights via a vapor density method, German chemist August Horstmann began to investigate the effect of temperature on the equilibrium constant for a dissociation process, beginning with the Clausius-Clapeyron equation, but extending it to apply to a substance that is dissociating. In 1872-73, Horstmann applied the entropy principle to the problems of chemical dissociation. [3] In October 1973, Horstmann announced the condition for chemical equilibrium to be that of maximum entropy. [4]

In the 1880s, work on the relation between, affinity, the equilibrium constant, and thermodynamics was further established by Dutch physical chemisty Jacobus van't Hoff.

References
1. Daintith, John. (2004). Oxford Dictionary of Chemistry. Oxford University Press.
2. Perrot, Pierre. (1998). A to Z of Thermodynamics (Equilibrium constant, pgs. 100-03). Oxford: Oxford University Press.
3. Horstmann, August F. (1972). Ann. d. Chem. U. Pharm., 8. Suppl.-Bd., 112-13.
4. Horstmann, August F. (1973). “Theorie der Dissociation”, Liebig’s Annalen der Chemie und Pharmacie, Bd. 170 (CLXX), 192-210.

External links
● Equilibrium constant – Wikipedia.

Sadi-Carnot	Latest page update: made by Sadi-Carnot , Sep 11 2009, 9:43 PM EDT (about this update About This Update Edited by Sadi-Carnot 1 word added 1 word deleted 1 image added 1 image deleted view changes - complete history)
	Keyword tags: equilibrium constant (edit keyword tags) More Info: links to this page

Threads for this page

Post a new thread

There are no threads for this page. Be the first to start a new thread.

JavaScript must be enabled in order for you to contribute to this site.
To start contributing, enable JavaScript by changing your browser options, then try again.

	Subject:
	Message:
	Quote:
	Tags:
	Category:	General Discussion

Equilibrium constant

Threads for this page

Start a New Thread as Reply as Anonymous (Get credit for your thread)