Solveeit Logo
Login

Question

Question: Give \({K_c}\) for is 0.04 at \(25^\circ C\) .The number of moles of \(PC{l_5}\) required to a 3.0 l...

Give Kc{K_c} for is 0.04 at 25C25^\circ C .The number of moles of PCl5PC{l_5} required to a 3.0 litre flask to obtain Cl2C{l_2} of concentration 0.15 MM is
A. 1.5 mole
B. 2.1 mole
C. 6.0 mole
D. 0.45 mole

Explanation

Solution

PCl5PC{l_5} decomposes to PCl3PC{l_{{3_{}}}} and chlorine gas and all these remain in a state of equilibrium. Initially, PCl5PC{l_5} decomposes to form the products and once the equilibrium is achieved the reaction takes place in both the forward and backward direction simultaneously. Here Kc{K_c} is called the equilibrium constant and is used to quantify the equilibrium. Here the concentration of one of the products is given so we can get to know about the concentration of the rest of the components with its help.

Complete step by step answer:
PCl5PC{l_5} decomposes to PCl3PC{l_3} and chlorine gas and all these remain in a state of equilibrium.
The equilibrium constant of the reaction is given as, Kc{K_c}
for PCl5(g)PCl3(g)+Cl2(g)PC{l_5}(g) \rightleftharpoons PC{l_3}(g) + C{l_2}(g) is 0.04 at 25C{25^\circ }C
Let the initial concentration of being aa and the amount reacted at equilibrium be xx.
So the reaction and the initial concentration can be represented as
PCl5PCl3+Cl2PC{l_5} \rightleftharpoons PC{l_3} + C{l_2}
a(R),0(P),0(P)a(R),0(P),0(P)
Let at equilibrium the amount reacted be xx . So,
PCl5PCl3+Cl2PC{l_5} \rightleftharpoons PC{l_3} + C{l_2}
ax(R),x(P),x(P)a - x(R),x(P),x(P)
The concentration of chlorine gas is given in the question as 0.15 MM So using the molarity relation we can find the number of moles of chlorine gas at equilibrium
molarity(M)=moles  of  soluteVolume  Of  Solution(L)molarity(M) = \dfrac{{moles\; of \;solute}}{{Volume\; Of \;Solution(L)}}
0.15=moles  of  Cl23\Rightarrow 0.15 = \dfrac{{moles\;of\;C{l_2}}}{3}
  Moles  of  Cl2=0.45\Rightarrow \;Moles\;of\;C{l_2} = 0.45
Therefore from the previous point, we can infer that the value of xx is 0.45
So, the equilibrium concentration becomes
PCl5PCl3+Cl2PC{l_5} \rightleftharpoons PC{l_3} + C{l_2}
a0.45(PCl5),0.45(PCl3),0.45(Cl2)a - 0.45(PC{l_5}),0.45(PC{l_3}),0.45(C{l_2})
Since The equilibrium constant of the reaction is given as 0.04
We can write the equilibrium expression as
Kc=[PCl3][Cl2][PCl5]{K_c} = \dfrac{{[PC{l_3}][C{l_2}]}}{{[PC{l_5}]}}
0.04=0.15×0.15(a0.453)\Rightarrow 0.04 = \dfrac{{0.15 \times 0.15}}{{\left( {\dfrac{{a - 0.45}}{3}} \right)}}
(Dividing the number of equilibrium moles with the volume of the solution at equilibrium to get the molar concentration.)
Cross multiplying and simplifying we get,
a=2.1a = 2.1

So, the correct answer is Option B.

Note: There are other representations of the concentration of solution than molarity.
While molality is represented by mm, Molarity is represented by MM.
Molarity of the solution can be represented in terms of the volume of the solution rather than the mass of the solvent as In case of molality. It can be represented as
Molality(m)=Moles  of  soluteMass  of  solvent  in  kgMolality(m) = \dfrac{{{{Moles\; of \;solute}}}}{{{{Mass\; of \;solvent \;in\; kg}}}}