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Answer 1 · 2015-05-25T10:23:51

In the case of $[C r {(N H_{3})}_{6}] [C r {(C N)}_{6}]$ $[Cr(NH_3)_6][Cr(CN)_6]$ , the first thing you need to notice is that neither the cation, nor the anion, have a sbubscript.

This means that the charges on the two complex ions will be equal. You can thus break up the coordination complex into a cation and an anion

${[C r {(N H_{3})}_{6}]}_{6}^{x +}$ $[Cr(NH_3)_6]^(color(red)(x+))$ $\to$ $->$ cation

${[C r {(C N)}_{6}]}_{6}^{x -}$ $[Cr(CN)_6]^(color(blue)(x-))$ $\to$ $->$ anion.

Notice that the anion contains the cyanide anion, $C N^{-}$ $CN^(-)$ , which has an overall charge of -1. This means that the oxidation state of the metal plus the total negative charge of the six cyanide ions must be equal to -x, the overall charge of the anion.

Let $c$ $c$ be the charge of the metal. This means that

$c + 6 \cdot (- 1) = - x$ $c + 6 * (-1) = -x$ $(1)$ $" "color(green)((1))$

Now look at the cation. Since ammonia is a neutral compound, the overall charge of the cation must be equal to the charge of the metal. This means that you have

$c = x$ $c = x$ $(2)$ $" "color(green)((2))$

Use equations $(1)$ $color(green)((1))$ and $(2)$ $color(green)((2))$ to get the identity of $c$ $c$

${ (c -6 = -x), (c=x) :}$ $=>$ $x-6 = -x => x =3$

Therefore, the charge of the metal will be +3 and the two complex ions will be

$[Cr(NH_3)_6]^(3+)$ and $[Cr(CN)_6]^(3-)$

You can use the same approach for the second coordination complex. This time, however, the two complex ions do have subscripts. This means that you have

$[Co(en)_3]_color(red)(4)[Mn(CN)_5I]_color(blue)(3)$

$[Co(en)_3]^(color(blue)(3+))$ $->$ cation

$[Mn(CN)_5I]^(color(red)(4-))$ $->$ anion

So, ethylenediamine is a neutral compound, so the oxidation state of cobalt will match the overall charge of the complex ion. Thus, you're dealing with the $Co^(3+)$ cation.

Once again, use a simple equation to find the charge of the manganese ion. This time, in addition to the negative charge that's coming from the cyanide anion, you get an extra -1 charge from the iodide anion, $I^(-)$ . This means that you have ( $c$ is the charge on the manganese ion)

$c + 5 * (-1) + (-1) = -4$

$c -6 = -4 => c = +2$

Therefore, you're dealing with the $Mn^(2+)$ cation.

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