Question #32207
1 Answer
Explanation:
The idea here is that the pressure of a gas is directly proportional to the amount of gas present when volume and temperature are kept constant.
#color(blue)(ul(color(black)(P prop n))) -># when volume and temperature are kept constant
This can be expressed as
#color(blue)(ul(color(black)(P_1/n_1 = P_2/n_2)))#
Here
#P_1# ,#n_1# are the pressure and number of moles of gas at an initial state#P_2# ,#n_2# are the pressure and number of moles of gas at a final state
Now, you don't have to convert the sample from grams to moles because the number of moles of a substance is proportional to its mass as given by
#color(blue)(ul(color(black)(n = m/M_M)))#
Here
#m# is the mass of the gas#M_M# is the molar mass of the gas
So, you know that you start with
#n_1 = 35/M_M#
After you remove
#n_2 = 35/M_M - 5/M_M = 30/M_M#
moles of ethylene in the container. This means that you will have
#P_1/(35/color(red)(cancel(color(black)(M_M)))) = P_2/(30/color(red)(cancel(color(black)(M_M))))#
which is equivalent to
#P_2 = 30/35 * P_1#
Plug in your value to find
#P_2 = 30/35 * "793 torr" = color(darkgreen)(ul(color(black)("680 torr")))#
I'll leave the answer rounded to two sig figs, but keep in mind that you only have one significant figure for the mass of gas removed from the container.
So, does the result make sense?
Since pressure is proportional to the amount of gas present in the container, decreasing the amount of gas will cause the pressure to decrease as well.