Answer:
11.58 g
Step-by-step explanation:
The equilibrium constant based on pressure (Kp) only relates the gases, so, for the reaction given, only the pressure of CO₂ will be considered. The equation is already balanced, so
Kp = pCO₂
Kp = 0.220
So, if 0.270 atm is added, the equilibrium will shift to form the reactant, and Kp will remain the same (0.220), so the gas added will form CaCO₃. The number of moles of CO₂ can be calculated by the equation of ideal gas:
PV = nRT, where P is the pressure, V is the volume, n is the number of moles, R is the constant of the gases (R = 0.082 atm.L/mol.K), and is the temperature.
First, let's calculated how much moles of CO₂ were formed in the equilibrium:
0.220x10 = nx0.082x385
31.57n = 2.20
n = 0.0697 mol
The stoichiometry is 1 mol of CaCO₃ for 1 mol of CO₂, so it was consumed 0.0697 mol of CaCO₃, and in the equilibrium, the number of moles of it is 0.100 - 0.0697 = 0.0303 mol
For the quantity added, the number of moles is:
0.270x10 = nx0.082x385
31.57n = 2.70
n = 0.0855 mol
This will form more 0.0855 mol of CaCO₃, so the final number of moles is:
n = 0.0303 + 0.0855 = 0.1158 mol
The molar masses are: Ca = 40 g/mol, C = 12 g/mol, O = 16 g/mol
CaCO₃ = 40 + 12 + 3x16 = 100 g/mol
The mass is the number of moles multiplied by the molar mass:
m = 0.1158x100
m = 11.58 g