A $5 L$ $5 L$ container holds $12$ $12$ mol and $6$ $6$ mol of gasses A and B, respectively. Every four of molecules of gas B bind to three molecule of gas A and the reaction changes the temperature from $360^{o} K$ $360^oK$ to $420^{o} K$ $420 ^oK$ . By how much does the pressure change?

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A $5 L$ $5 L$ container holds $12$ $12$ mol and $6$ $6$ mol of gasses A and B, respectively. Every four of molecules of gas B bind to three molecule of gas A and the reaction changes the temperature from $360^{o} K$ $360^oK$ to $420^{o} K$ $420 ^oK$ . By how much does the pressure change?

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Answer 1 · 2016-08-01T20:30:03

The pressure changed by: $2.39 \times 10^{6} P a$ $2.39 × 10^6 Pa$ (to 3 sig figs)

Explanation:

To get started we’ll work out how many moles of gas are present at the end of the reaction, we start with 12 moles of gas A and 6 moles of gas B (a total of 18 moles). In the reaction gas A bonds with gas B at a ratio of 3:4 molecules, so that ratio will apply to the number of moles also.

There are only 6 moles of gas B which is not a multiple of 4, so only 4 moles of gas B will react and only 3 moles of gas A will react (due to 3:4 ratio). That gives only 1 mole of the new gas from the reaction. In the end we have 9 moles of gas A left, 2 moles of gas B and 1 mole of the new gas, a total of 12 moles.

Ideal Gas Equation
Use the ideal gas equation to find the pressure change: $p V = n R T$ $pV = nRT$
p is pressure (Pa)
V is volume (m³)
n is number of moles (mol)
R is the molar gas constant (8.31 m² kg s⁻² K⁻¹ mol⁻¹)
T is temperature (K)

Here is the equation with pressure as the subject:
$p = \frac{n R T}{V}$ $p = (nRT)/V$
$\Rightarrow p_{1} - p_{2} = \frac{n_{1} R T_{1}}{V_{1}} - \frac{n_{2} R T_{2}}{V_{2}}$ $⇒ p_1 - p_2 = (n_1RT_1)/V_1 - (n_2RT_2)/V_2$

The question implies that the volume does not change so $V_{1} = V_{2}$ $V_1 = V_2$
$\Rightarrow p_{1} - p_{2} = \frac{(n_{1} R T_{1}) - (n_{2} R T_{2})}{V}$ $⇒ p_1 - p_2 = ((n_1RT_1) - (n_2RT_2))/V$

Before calculation the volume needs to be converted into cubic metres: $V = 5L = 5×10^(-3) m³$

Substitute in the values
$⇒ p_1 - p_2 = ((18 × 8.31 × 360) - (12 × 8.31 × 420))/(5×10^(-3)) = 2.393 × 10^6 Pa$

The pressure changed by:
$2.39 × 10^6 Pa$ (to 3 sig figs)

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A $5 L$ $5 L$ container holds $12$ $12$ mol and $6$ $6$ mol of gasses A and B, respectively. Every four of molecules of gas B bind to three molecule of gas A and the reaction changes the temperature from $360^{o} K$ $360^oK$ to $420^{o} K$ $420 ^oK$ . By how much does the pressure change?

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Explanation:

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A 5 L5L5 L container holds 12 1212 mol and 6 66 mol of gasses A and B, respectively. Every four of molecules of gas B bind to three molecule of gas A and the reaction changes the temperature from 360^oK360oK360^oK to 420 ^oK420oK420 ^oK. By how much does the pressure change?

1 Answer

Explanation:

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A $5 L$ $5 L$ container holds $12$ $12$ mol and $6$ $6$ mol of gasses A and B, respectively. Every four of molecules of gas B bind to three molecule of gas A and the reaction changes the temperature from $360^{o} K$ $360^oK$ to $420^{o} K$ $420 ^oK$ . By how much does the pressure change?