What volume flask should be used to get 0.37 moles $I$ $I$ present for every mole $I_{2}$ $I_2$ at equilibrium?

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What volume flask should be used to get 0.37 moles $I$ $I$ present for every mole $I_{2}$ $I_2$ at equilibrium?

For the dissociation of $I_{2} (g)$ $I_2"(g)"$ at 1200°C, $K_{c} = 0.011$ $K_c=0.011$ . What volume flask should we use if we want 0.37 moles of $I$ $I$ to be present for every mole of $I_{2}$ $I_2$ present at equilibrium?

$I_{2} (g) ⇌ 2 I (g)$ $I_2"(g)"\rightleftharpoons2I"(g)"$

My work:

(can't see? it sets equilibrium pressures as stated below:)
$P_{I} = \frac{0.37 \cdot 0.0821 (1200 + 273)}{V} = \frac{0.37 \cdot 121}{V} atm$ $P_I=\frac{0.370.0821(1200+273)}{V}=\frac{0.37121}{V}" atm"$
$P_{I_{2}} = \frac{1.00 \cdot 0.0821 (1200 + 273)}{V} = \frac{1.00 \cdot 121}{V} = \frac{121}{V} atm$ $P_(I_2)=\frac{1.000.0821(1200+273)}{V}=\frac{1.00121}{V}=121/V" atm"$

after using those pressures for $K_{p}$ $K_p$ in the formula $\color(red)(K_c=K_p(RT)^(\Deltan))$ , I got $V=0.0307/0.011\approx0.279" L"$

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Answer 1 · 2018-07-19T18:31:42

Are we missing information? We need to be able to figure out the exact number of mols of $"I"$ or $"I"_2$ ... no ratios, an actual number.

We begin with the ICE table:

$"I"_2(g) " "rightleftharpoons" " 2"I"(g)$

$"I"" "["I"_2]_i" "" "" "" "0$
$"C"" "-x" "" "" "+2x$
$"E"" "["I"_2]_i-x" "" "2x$

So we write the mass action expression to get:

$K_c = 0.011 = (["I"]^2)/(["I"_2])$

$= (2x)^2/(["I"_2]_i - x)$

What we apparently want is

$(2x)/(["I"_2]_i - x) = 0.37 = (["I"])/(["I"_2]) = ("mols I"//cancel"L")/("mols I"_2//cancel"L")$

We now have a system of equations:

$(2x)^2/(["I"_2]_i - x) = 0.011$ $" "" "bb((1))$
(Note that $0.011$ is in implied units of $"M"$ .)

$(2x)/(["I"_2]_i - x) = 0.37$ $" "" "bb((2))$
(Note that $0.37$ is unitless.)

By inspection, we have:

$(2x)^2/(["I"_2]_i - x) = 0.011 = 0.37(2x) = 0.74x$

So,

$x = ("0.011 M")/0.74 = ul"0.0149 M"$

As a result, take $(2)$ to get

$(2 cdot "0.0149 M")/(["I"_2]_i - "0.0149 M") = 0.37$

$2 cdot "0.0149 M" = 0.37(["I"_2]_i - "0.0149 M")$

$"0.0297 M" = 0.37["I"_2]_i - "0.0055 M"$

Therefore, the initial concentration of $"I"_2$ is:

$color(blue)(["I"_2]_i) = ("0.0352 M")/(0.37) = color(blue)("0.0952 M")$

and the fraction of dissociation is

$alpha = x/(["I"_2]_i) = 0.1565$

Now we just need to know the ACTUAL mols of either $"I"$ or $"I"_2$ ... the ratio desired can be ANY NUMBER of combinations of quantities...

The fraction of dissociation $alpha$ and the concentration lost $x$ also vary with concentration $["I"_2]_i$ , so we cannot use those to determine the volume.

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What volume flask should be used to get 0.37 moles $I$ $I$ present for every mole $I_{2}$ $I_2$ at equilibrium?

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What volume flask should be used to get 0.37 moles $I$ $I$ present for every mole $I_{2}$ $I_2$ at equilibrium?