At a certain temperature, 4.0 mol #NH_3# is introduced into a 2.0 L container, and the #NH_3# partially dissociates to #2NH_3(g)\rightleftharpoonsN_2(g)+3H_2(g)#. At equilibrium, 2.0 mol #NH_3# remains. What is the value of #K_c#?
A clearer version:
At a certain temperature, 4.0 mol #NH_3# is introduced into a 2.0 L container, and the #NH_3# partially dissociates to #2NH_3(g)\rightleftharpoonsN_2(g)+3H_2(g)# .
At equilibrium, 2.0 mol #NH_3# remains. What is the value of #K_c# ?
Note: I started an ICE table but I don't know what to put in the #N_2# and #3H_2# columns.
A clearer version:
At a certain temperature, 4.0 mol
At equilibrium, 2.0 mol
Note: I started an ICE table but I don't know what to put in the
1 Answer
Remember to include the coefficients in the change in concentratio, as well as the exponents. I get
If
#color(white)("From the reaction, "Deltan_"gas" = (1+3) - (2) = 2,)#
#color(white)("since there are 3 mols H"_2, "1 mol N"_2, "and 2 mols NH"_3.)#
#color(white)("So,")#
#color(white)(K_p = 1.69 cdot ("0.08206 L"cdot"atm/mol"cdot"K" cdot "298 K")^((1+3)-(2)))#
#color(white)(~~ 1010" in implied units of atm")#
Let's first find the concentrations, because
#"4.0 mols NH"_3/("2.0 L") = "2.0 M"#
#"2.0 mols NH"_3/("2.0 L") = "1.0 M"#
The ICE table uses
#color(red)(2)"NH"_3(g) rightleftharpoons "N"_2(g) + color(red)(3)"H"_2(g)#
#"I"" "2.0" "" "" "" "0" "" "" "0#
#"C"" "-color(red)(2)x" "" "+x" "" "+color(red)(3)x#
#"E"" "2.0-color(red)(2)x" "" "x" "" "color(red)(3)x#
Remember that the coefficients go into the change in concentration and exponents.
Now, the
#K_c = (x(color(red)(3)x)^color(red)(3))/(2.0 - color(red)(2)x)^color(red)(2)#
#= (27x^4)/(2.0 - 2x)^2#
But like mentioned, we know
#2.0 - 2x = "1.0 M"# .
Therefore:
#x = "0.5 M"# .
As a result,
#color(blue)(K_c) = (27(0.5)^4)/(2.0 - 2(0.5))^2#
#= color(blue)(1.69)#
