*Saranya Chatterjee*Show bio

Saranya has a masters degree in Chemistry and in Secondary Education. She has taught high school, AP chemistry for 2 years and is teaching undergraduate college chemistry for 3 years.

Lesson Transcript

Instructor:
*Saranya Chatterjee*
Show bio

Saranya has a masters degree in Chemistry and in Secondary Education. She has taught high school, AP chemistry for 2 years and is teaching undergraduate college chemistry for 3 years.

This lesson will discuss law of mass action. It will derive the equations between equilibrium constants at constant partial pressure (Kp), concentrations (Kc) and discuss some real-life applications of chemical equilibrium.

Imagine the flow of water from a high level to a lower level. Will the water flow forever? No. The flow will stop when both levels become equal. This phenomenon may be considered a state of equilibrium. This idea applies in chemical reactions as well.

In chemistry, an **active mass** is the mass of a substance that is actually reacting. The **law of mass action** states that, at a constant temperature, the rate of a chemical reaction is proportional to the active masses of the reacting substances. Let us consider the following reaction:

A+B ā C+D

Let C' denote the concentrations of the components at a given instant during the reaction process. Let the concentrations of A, B, C and D be C'A, C'B, C'C and C'D. According to the law, the rate of reaction (RAB) between A and B at that moment will be:

RAB = k1 C'A C'B where k1, the constant of proportionality, depends upon reactants and temperature.

During the reaction, the concentrations of the reactants A and B would diminish, and therefore its rate would also diminish with time. Similarly, the rate of the opposite reaction (RCD) between C and D at that moment will be:

RCD = k2 C'C C'D

Since the concentrations of C and D would increase, the rate RCD would also increase. A time will come when the rates of the reaction in the two opposite directions will be equal; that is, RAB = RCD. The system will then attain equilibrium and there will be no further change in the masses of the components of the system. At equilibrium, let the concentrations be expressed by C (instead of C'). Then:

- RAB = RCD
- k1 CA CB = k2 CC CD
- CC CD / CA CB = k1 / k2 = Kc (constant)

**Kc** is the equilibrium constant of the reaction.

Okay, but what happens if multiple molecules of the reactants are involved? Say, 2A + 3B = C + 2D. The rates are given by:

- RAB = k1 C2A C3B
- RCD = k2 CC C2D

At equilibrium, k1 C2A C3B = k2 CC C2D

So, Kc = k1 / k2 = CC C2D / CC C2D

That is, the coefficients in the stoichiometric equation become powers of the concentrations in the expression of equilibrium constant. In general, for a reversible reaction of the type like that shown here -

aA + bB + cC + ..... ā dD + eE + fF + .......

- the equilibrium constant, Kc, would look like this:

Kc = Cd D Ce E Cf F...../ Ca A Cb B Cc C....

In a gaseous reaction, components are usually expressed in terms of their partial pressures instead of molarities. If the gases are supposed to behave ideally, partial pressures are expressed as PA, PB, ...PD, PE and so on.

Then the total pressure, P = PA + PB + .. + PD PE + ....

The equation for Kp looks like this, where ** Kp** is the equilibrium constant of a reaction found by adding the partial pressures:

Kp = PdD * PeE...../ PaA PbB ....

Again, assuming ideality, we can express pressures as:

PA = CA RT, and PB = CB RT

Therefore, the equation for the equilibrium constant looks like this:

Kp = (CD RT)d * (CE RT)e * ..../ (CA RT)a * (CB RT)b

= {(CD)d * (CE)e *.../ (CA)a * (CB)b} * (RT) d+e + ... -a-b...

So, **Kp = Kc (RT) Īn**

where Īn = number of product molecules minus number of reactant molecules. This is a relation between the equilibrium constants derived from partial pressure units and from molar concentrations unit of components.

The partial pressures can be expressed in terms of total pressure and the respective mole fractions, such as the partial pressure of A equals the molar concentration of A times the total pressure (PA =xA.P); the partial pressure of B equals the molar concentration of B times the total pressure (PB =xB.P); and so on.

So, the equation for the equilibrium constant looks like this:

Kp = PdD * PeE...../ PaA PbB ....

and can be written like this:

Kp = (xD.P)d * (xE.P)e * ...../ (xA.P)a * (xB.P)b * ....

= {(xD)d * (xE)e * .../ (xA)a * (xB)b * ....} * P (d+e + ...-a-b...)

Writing Kx for the terms within parentheses, we get:

**Kp = Kx P Īn**

Let's work out a problem. Take the famous water gas reaction, which is:

H2 + CO2 ā H2 O + CO

Starting with equimolecular mixture of the reactants, let us assume that x is the extent of H2 used up at equilibrium.

At equilibrium:

- moles of H2 = 1 - x
- moles of CO2 = 1 - x
- moles of H2 O = x
- moles of CO = x

So the total moles at equilibrium = (1 - x) + (1 - x) + x + x = 2

- Partial pressures of H2 = (1 - x)/ 2P
- Partial pressures of CO2 = (1 - x) / 2P
- Partial pressures of H2 O = x / 2P
- Partial pressures of CO = x / 2P

So, by adding, we know that the total partial pressure = P, so the equilibrium constant equals the partial pressure of water times the partial pressure of carbon monoxide divided by the partial pressure of hydrogen times the partial pressure of carbon dioxide, which looks like this:

Kp = P H2 O * P CO/ P H2 * P CO2

= ( x/2P)2 / {(1-x)/2P}2 = x2 / (1-x) 2

At 1260 K and 1 atm pressure, the equilibrium composition of this reaction is:

- CO2 = 21.4
- H2 = 22.9
- CO = 27.8

Therefore, the equilibrium constant (Kp) equals 1.58.

Real-life applications of equilibrium include refrigerators maintaining a chemical equilibrium in foods to prevent them from spoiling. Another example is the equilibrium between hemoglobin and the oxygen in the blood. Hemoglobin is responsible for transporting oxygen to the cells. Each hemoglobin molecule attaches to four oxygen molecules to form oxyhemoglobin, thus maintaining an equilibrium. At higher elevations, there is less oxygen, and equilibrium tends to shift away from the oxygenated hemoglobin, causing you to feel lightheaded.

The **law of mass action** states that, at a constant temperature, the rate of a chemical reaction is proportional to the active masses of the reacting substances. **Kc** is the equilibrium constant of the reaction, while **Kp** is the equilibrium constant found by adding partial pressures. We learned some mathematical derivations to reach at the relationships between these, which look like this:

Kp = Kc (RT) Īn

Kp = Kx P Īn

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