Henry's Law Calculations - Online Tutor, Practice Problems & Exam Prep

The concentration, also referred to as the solubility of a dissolved gas, can be determined from its Henry's law constant and partial pressure. Now when I say Henry's law constant, that's the variable KH, and it represents the solubility of a gas at a fixed temperature in a particular solvent in molarity, which remember uses the variable capital M. Also remember we discussed this before where concentration and molarity are synonymous with one another. Usually, professors will interchange them. We can say concentration or molarity, and they mean the same thing.

With this idea of Henry's law constant comes Henry's law formula, where Cgas, which equals the solubility of a gas in molarity, equals Henry's constant which is KH, and here it's in units of molarity over pressure. So our normal type of pressure is atmospheres. But remember there's a possibility of tours or millimeters of mercury as well. So always be on the lookout for the units that you'll see for Henry's law constant. Usually, you'll see it in molarities over atmospheres, but there can be times where you might see it in molarities over tours or molarities over millimeters of mercury.

If it makes you feel more comfortable, just convert those pressure units all to atmospheres and use this version of Henry's law constant. Now, and that's times Pgas. Pgas is the partial pressure of the gas in atmospheres, and again, units are always important. The units here for partial pressure are atmospheres because we're using these units for Henry's law constant, molarity over atmospheres.

Calculate the solubility of carbon dioxide gas, which is CO₂ when its Henry loss constant is 8.20 * 10 to the two molarities per atmosphere at a pressure of 3.29 atmospheres. All right, so we need to find the solubility of our gas. So that's S gas, which is CO₂ equals Henry's constant times the pressure of that gas.

So we're going to plug in 8.20 * 10 to the two molarities over atmospheres times 3.29 atmospheres. Again, you see that units will cancel out. And what do we have at the end? Molarity. So this would come out to be 27 * 10 to the three molar.

So this would be the concentration of carbon dioxide for this particular example question.

So now we take a look at Henry's law, at least in terms of the 2.4. We're going to say the 2.4 Met. Henry's law formula illustrates how changes in pressure can affect gas solubility.

Now we're going to say this formula. This version is used when dealing with two pressures and with two solubilities for a given gas. Here we're going to say with this formula the units from solubility can be in molarity or they can be in other units that are in mass per volume.

So Henry's law formula. The two point form is S1P1 = S2P2. So again, we use this version when we're dealing with two solubilities or two pressures for any given gas.

At a pressure of 2.88 atmospheres, the solubility of dichloromethane, which is Chapter 2 CL₂, is 0.384 milligrams per liter. If the solubility decreases to, oh, 0.225 milligrams per liter, what is the new pressure? All right, so here they're giving US1 pressure, but they're asking for a new pressure. So since this is the first pressure that's given, this is P₁. And since this is the second pressure that's talked about, this is P₂ connected to P₁.

Is this solubility which we're going to say is S₁ and connected to the new pressure we need to find? Is this solubility, which we call S₂? So now we're just going to solve, so we're going to say here that

S 1 P 1 = S 2 P 2

So then we're going to plug in the numbers that we know. So this is

0.384 2.88 = 0.225 P 2

which we don't know you're going to cross.

Multiply these two and cross multiply these two. So when we do that, what we're going to see is we're going to have

0.384 × P 2 = 0.648

milligrams over liters times atmospheres, divide both sides now by

0.384

milligrams per liter so these units cancel out and we'll have

P 2 = 2

atmospheres.

O here 2 = 16 atmospheres as my final answer.