Answer:
0 M.
Explanation:
Hello,
In this case, the undergoing reaction is:
[tex]M(NO_3)_2+NaCN\leftrightarrow [M(CN)_4]^{-2}+NaNO_3[/tex]
Nonetheless, it only matters the reaction forming the given complex:
[tex]M^{+2}+4CN^-\leftrightarrow [M(CN)_4]^{-2}[/tex]
In such a way, the formation constant turns out:
[tex]K_F=\frac{[[M(CN)_4]^{-2}]_{eq}}{[M^{+2}]_{eq}[CN^{-}]_{eq}^4}[/tex]
Now, one could assume that the initial concentrations of the ions equals the original compounds concentrations:
[tex][M^{+2}]_0=0.150M;[CN^-]_0=0.820M[/tex]
In such a way, we modify the formation constant in terms of the change [tex]x[/tex] due to the reaction progress:
[tex]K_F=\frac{x}{(0.150-x)(0.820-x)^4}=7.70x10^{16}[/tex]
Now, solving for [tex]x[/tex]:
[tex]x_1=0.15M\\x_2=0.82M[/tex]
The feasible solution is 0.15M which will lead to an equilibrium concentration of M⁺² of 0M
[tex][M^{+2}]_{eq}=0.15M-0.15M=0M[/tex]
This fact has sense since the formation constant is very large.
Best regards.
