How do you calculate the partial pressure of O2 in the air if the atmospheric pressure is 370 mmHg, PH2O is 23 mmHg, and concentration of Oxygen is 20.93%?
1 Answer
#P_(O_2) = "72.6 torr"#
The atmosphere contains water vapor, from which we must subtract the water. We assume water vapor is an ideal gas, and thus Dalton's law of partial pressures applies:
#P_"wet air" = P_(H_2O ) + overbrace(P_(O_2) + . . . )^(P_"dry air")= "370 mm Hg"#
We lumped it as
#P_"dry air" = P_(O_2) + . . . # except for#P_(H_2O)# ,since obviously,
#P_("wet air") = P_"dry air" + P_(H_2O)# .
So, at approx.
#P_"dry air" = overbrace("370 mm Hg")^(P_"wet air") - overbrace("23 mm Hg")^(P_(H_2O)) = "347 mm Hg"#
From the same principles,
#P_(O_2) = chi_(O_2(v))P_"dry air"# where
#chi_(O_2(v))# is the mol fraction of#O_2# gas in the vapor phase above the surface of the water.
Therefore, the partial pressure of
#color(blue)(P_(O_2)) = overbrace(0.2093)^(chi_(O_2(v))) cdot overbrace("347 mm Hg")^(P_"dry air")#
#=# #color(blue)("72.6 mm Hg")#
What is this in torr?
