Respuesta :
Answer:
The new equilibrium concentration of HI: [HI] = 3.589 M
Explanation:
Given: Initial concentrations at original equilibrium- [H₂] = 0.106 M; [I₂] = 0.022 M; [HI] = 1.29 M
Final concentrations at new equilibrium- [H₂] = 0.95 M; [I₂] = 0.019 M; [HI] = ? M
Given chemical reaction: H₂(g) + I₂(g) → 2 HI(g)
The equilibrium constant ([tex]K_{c}[/tex]) for the given chemical reaction, is given by the equation:
[tex]K_{c} = \frac {[HI]^{2}}{[H_{2}]\: [I_{2}]}[/tex]
At the original equilibrium state:
[tex]K_{c} = \frac {(1.29\: M)^{2}}{(0.106\: M) \times (0.022\: M)}[/tex]
[tex]K_{c} = \frac {1.6641}{0.002332} = 713.59[/tex]
Therefore, at the new equilibrium state:
[tex]K_{c} = \frac {[HI]^{2}}{(0.95\: M) \times (0.019\: M)}[/tex]
[tex]\Rightarrow K_{c} = 713.59 = \frac {[HI]^{2}}{0.01805}[/tex]
[tex]\Rightarrow [HI]^{2} = 713.59 \times 0.01805 = 12.88[/tex]
[tex]\Rightarrow [HI] = \sqrt {12.88} = 3.589 M[/tex]
Therefore, the new equilibrium concentration of HI: [HI] = 3.589 M
