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The Law of Mass Action, first expressed by Waage and Guldberg in 1864 , states that the rate of
a Chemical Reaction is proportional to the Probability that the reacting molecules will be found together
in a small volume. By assumption, the probability of finding ''one'' reactant molecule in a small volume is Independent of finding ''another'' reactant molecule in the same volume; therefore, the probability of finding them ''both'' in the same volume is the product of their individual probabilities.

For a reacting solute in Solution , the probability is proportional to its concentration or, more correctly,
its Chemical Activity . For a reacting molecule in the gas phase, the corresponding
probability is proportional to its concentration (number per volume) or, equivalently, its partial pressure.


EXAMPLE OF A SINGLE REACTION


Consider the following reaction occurring in the gas phase:

A + A + B ightarrow A_2B

There are three reacting molecules so, according to the Law of Mass Action, the rate of
forming A_2B should be proprotional to the probability of finding all three
in the same space, which is the product of the probabilities of finding each one in that space.
Those probabilities are proportional to their concentrations, so we may write

r= k imes [A]^2 imes [B]

where k is the overall proportionality constant. For a closed system (see Mass Balance ), i.e.,
if no other reactions are creating or destroying A_{2}B, we may write

rac{d = k imes [A ^2 imes [B].


EXAMPLE OF FORWARD AND BACKWARD REACTIONS (CHEMICAL EQUILIBRIUM)


Similarly, a reversible reaction such as

:A + A + B \leftrightarrow C + D

in a closed system results in the kinetic rate equation

: rac{d = k_{AB} imes [A ^2 imes - k_{CD} imes [C imes [D]

The first term on the right-hand side equals the rate of forming C, i.e., the rate of the forward
reaction A + A + B ightarrow C + D. By contrast, the second term is the rate of losing
C, i.e., the rate of the backward reaction A + A + B \leftarrow C + D.

If the system is at chemical equilibrium, the forward rate must equal the backward rate

:
k_{AB} imes [A]^2 imes [B] = k_{CD} imes [C] imes [D]


Cross-dividing gives us the equilibrium constant K_{eq}

:
K_{eq} = rac{ {Link without Title} {Link without Title} }{ {Link without Title} ^2 {Link without Title} } = rac{k_{AB}}{k_{CD}}


Given the equilibrium constant K_{eq} and the overall amounts of the reacting
substances, it is usually possible to determine the final equilibrium concentrations of
the individual reacting molecules.

K_{eq} is a constant insofar as the individual rate constants k_{AB} and
k_{CD} are; if they change (e.g., with temperature or pH), the equilibrium constant
will generally change as well.

The equation for K_{eq} is sometimes referred to as the Mass Action Law. This is
incorrect, however; it is merely a ''consequence'' of the kinetic rate equations that result from
the Law of Mass Action.


A DIFFERENT DEFINITION OF MASS ACTION


Mass action in science is the idea that a large number of small units (especially atoms or molecules) acting randomly by themselves can in fact have a larger pattern. For example, consider a cloud of gas is moving in a given direction. Individual molecules will move in a semi- Random Walk , but if taken as a whole, they have direction.

However, this use of the term "mass action" is extremely rare and would not be understood among working scientists.
The proper term for such phenomena is "collective behavior".



SEE ALSO





REFERENCES