Ideal gas law/Tutorials: Difference between revisions
imported>Paul Wormer (2 extra problems) |
imported>Milton Beychok m (Revised heading rank of "Answer" to Problem 5 (i.e., from === to ====)) |
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*<i>All pressures are [[Pressure#Absolute_pressure_versus_gauge_pressure|absolute]].</i> | *<i>All pressures are [[Pressure#Absolute_pressure_versus_gauge_pressure|absolute]].</i> | ||
* <i> The molar gas constant</i> ''R'' = 0.082057 | * <i> The molar gas constant</i> ''R'' = 0.082057 atm·L/(K·mol). | ||
* 1 bar = 0.98692 atm | <!--* 1 bar = 0.98692 atm --> | ||
== Example problems == | == Example problems == | ||
''See also the tutorials on the [[Ideal gas law/Video|Video subpage]].'' | |||
===Problem 1=== | ===Problem 1=== | ||
Determine the volume of 1 mol of ideal gas at pressure 1 atm and temperature 20 °C. | Determine the volume of 1 mol of ideal gas at pressure 1 atm and temperature 20 °C. | ||
:<math> | :<math> | ||
V = \frac{n\,R\,T}{p} = \frac{1\cdot 0.082057\cdot (20+273.15)}{1} \quad | V = \frac{n\,R\,T}{p} = \frac{1\cdot 0.082057\cdot (20+273.15)}{1} \quad\left[ | ||
\frac{ \mathrm{mol}\cdot\frac {\mathrm{atm}\cdot\mathrm{L}} {\mathrm{K}\cdot\mathrm{mol}} | \frac{ \mathrm{mol}\cdot\frac {\mathrm{atm}\cdot\mathrm{L}} {\mathrm{K}\cdot\mathrm{mol}} | ||
\cdot\mathrm{K} } | \cdot\mathrm{K} } | ||
{\mathrm{atm}} | {\mathrm{atm}} \right] | ||
= 24.0550 \quad \mathrm{L} | = 24.0550 \quad [\mathrm{L}] | ||
</math> | |||
===Problem 2=== | ===Problem 2=== | ||
Compute from Charles' and Gay-Lussac's law (V/T is constant) the volume of an ideal gas at 1 atm and 0 °C (Use the final result of the previous problem). Write ''V''<sub>''T''</sub> for the volume at ''T'' °C, then | Compute from Charles' and Gay-Lussac's law (''V''/''T'' is constant) the volume of an ideal gas at 1 atm and 0 °C (Use the final result of the previous problem). Write ''V''<sub>''T''</sub> for the volume at ''T'' °C, then | ||
:<math> | :<math> | ||
\frac{V_{20}}{273.15+20} = \frac{V_0}{273.15+0} \quad\Longrightarrow | \frac{V_{20}}{273.15+20} = \frac{V_0}{273.15+0} \quad\Longrightarrow | ||
V_0 = 273.15 \times \frac{24.0550}{ | V_0 = 273.15 \times \frac{24.0550}{293.15} = 22.4139\; \;[\mathrm{L}] | ||
</math> | </math> | ||
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A certain amount of gas that has an initial pressure of 1 atm and an initial volume of 2 L, is compressed to a final pressure of 5 atm at constant temperature. What is the final volume of the gas? | A certain amount of gas that has an initial pressure of 1 atm and an initial volume of 2 L, is compressed to a final pressure of 5 atm at constant temperature. What is the final volume of the gas? | ||
====Boyle's law (''pV'' is constant)==== | |||
:<math> | :<math> | ||
(1.1)\qquad\qquad p_\mathrm{i}\,V_\mathrm{i} = p_\mathrm{f}\,V_\mathrm{f} | (1.1)\qquad\qquad p_\mathrm{i}\,V_\mathrm{i} = p_\mathrm{f}\,V_\mathrm{f} | ||
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Inserting the given numbers | Inserting the given numbers | ||
:<math> | :<math> | ||
(1.3)\qquad\qquad V_\mathrm{f} = \left(\frac{1\cdot 2}{5}\right)\; \frac{\mathrm{atm}\sdot\mathrm{L}}{\mathrm{atm}} = 0.4\; \mathrm{L} | (1.3)\qquad\qquad V_\mathrm{f} = \left(\frac{1\cdot 2}{5}\right)\;\left[ \frac{\mathrm{atm}\sdot\mathrm{L}}{\mathrm{atm}} \right] = 0.4\; [\mathrm{L}] | ||
</math> | </math> | ||
====Ideal gas law==== | |||
The number ''n'' of moles is constant | The number ''n'' of moles is constant | ||
:<math> | :<math> | ||
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It is given that the initial and final temperature are equal, <math>T_\mathrm{i} = T_\mathrm{f}\, </math>, therefore the products ''RT'' on both sides of the equation cancel, and Eq. (1.4) reduces to Eq. (1.1). | It is given that the initial and final temperature are equal, <math>T_\mathrm{i} = T_\mathrm{f}\, </math>, therefore the products ''RT'' on both sides of the equation cancel, and Eq. (1.4) reduces to Eq. (1.1). | ||
===Problem 4=== | ===Problem 4=== | ||
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:<math> | :<math> | ||
n=\frac{p\,V}{R\,T} = \frac{10.0\cdot 50.0} {0.0821 \cdot (273+25.0)} | n=\frac{p\,V}{R\,T} = \frac{10.0\cdot 50.0} {0.0821 \cdot (273+25.0)} | ||
\quad | \quad \left[ | ||
\frac{\mathrm{atm}\cdot \mathrm{L}}{\frac{\mathrm{atm} \cdot \mathrm{L}}{\mathrm{K}\cdot \mathrm{mol}}\cdot\mathrm{K}} | \frac{\mathrm{atm}\cdot \mathrm{L}}{\frac{\mathrm{atm} \cdot \mathrm{L}}{\mathrm{K}\cdot \mathrm{mol}}\cdot\mathrm{K}} \right] | ||
=\frac{500}{0.0821 \cdot 298}\quad \frac{\mathrm{mol} \cdot \mathrm{atm}\cdot \mathrm{L}}{\mathrm{atm}\cdot \mathrm{L}} = 20.4 \quad \mathrm{mol} | =\frac{500}{0.0821 \cdot 298}\quad\left[ \frac{\mathrm{mol} \cdot \mathrm{atm}\cdot \mathrm{L}}{\mathrm{atm}\cdot \mathrm{L}} \right] = 20.4 \quad [\mathrm{mol}] | ||
</math> | |||
===Problem 5=== | |||
Given is that dry air consists of 78.1% N<sub>2</sub>, 20.1% O<sub>2</sub>, and 0.8% Ar (volume percentages). The [[Atomic_mass#Standard_Atomic_Weights_of_the_Elements|atomic weights]] of N, O, and Ar are 14.0, 16.0 and 39.9, respectively. Compute the mass of 1 m<sup>3</sup> of dry air at 1 atm and 20 °C. | |||
====Answer==== | |||
Since for ideal gases the volume ''V'' is proportional to the number of moles ''n'', a volume percentage is equal to a molar percentage. For instance, for a mixture of two gases, it is easily shown that | |||
:<math> | |||
\frac{n_1}{n_1+n_2} = \frac{V_1}{V_1+V_2} | |||
</math> | </math> | ||
which states that the molar percentage of gas 1 is equal to the volume percentage of gas 1. | |||
The mass of 1 mole of dry air is | |||
:M = 0.781×28.0 + 0.201×32.0 + 0.008×39.9 g = 28.6192 g | |||
In problem 1 it is found that the volume of 1 mole of ideal gas at 1 atm and 20 °C is 24.0550 L = 24.0550×10<sup>−3</sup> m<sup>3</sup>, or | |||
:1 m<sup>3</sup> contains 1/(24.0550×10<sup>−3</sup>) = 41.5714 mol | |||
Hence the mass of 1 cubic meter of dry air is | |||
:M = 28.6192 × 41.5714 = 1189.7 g = 1.1897 kg | |||
Latest revision as of 13:03, 16 January 2009
- All gases mentioned below are assumed to be ideal, i.e. their p, V, T dependence is given by the ideal gas law.
- Absolute temperature is given by K = °C + 273.15.
- All pressures are absolute.
- The molar gas constant R = 0.082057 atm·L/(K·mol).
Example problems
See also the tutorials on the Video subpage.
Problem 1
Determine the volume of 1 mol of ideal gas at pressure 1 atm and temperature 20 °C.
![{\displaystyle V={\frac {n\,R\,T}{p}}={\frac {1\cdot 0.082057\cdot (20+273.15)}{1}}\quad \left[{\frac {\mathrm {mol} \cdot {\frac {\mathrm {atm} \cdot \mathrm {L} }{\mathrm {K} \cdot \mathrm {mol} }}\cdot \mathrm {K} }{\mathrm {atm} }}\right]=24.0550\quad [\mathrm {L} ]}](https://wikimedia.org/api/rest_v1/media/math/render/svg/5f41e4ff6378b1316d8dda5d7c950d129f3b8bed)
Problem 2
Compute from Charles' and Gay-Lussac's law (V/T is constant) the volume of an ideal gas at 1 atm and 0 °C (Use the final result of the previous problem). Write VT for the volume at T °C, then
![{\displaystyle {\frac {V_{20}}{273.15+20}}={\frac {V_{0}}{273.15+0}}\quad \Longrightarrow V_{0}=273.15\times {\frac {24.0550}{293.15}}=22.4139\;\;[\mathrm {L} ]}](https://wikimedia.org/api/rest_v1/media/math/render/svg/6ce6920ae22338531a44a7049e2878147a25047e)
Problem 3
A certain amount of gas that has an initial pressure of 1 atm and an initial volume of 2 L, is compressed to a final pressure of 5 atm at constant temperature. What is the final volume of the gas?
Boyle's law (pV is constant)
or
Inserting the given numbers
![{\displaystyle (1.3)\qquad \qquad V_{\mathrm {f} }=\left({\frac {1\cdot 2}{5}}\right)\;\left[{\frac {\mathrm {atm} \cdot \mathrm {L} }{\mathrm {atm} }}\right]=0.4\;[\mathrm {L} ]}](https://wikimedia.org/api/rest_v1/media/math/render/svg/7cbff8c245b52eabb622f3c27bfc13d1538260e7)
Ideal gas law
The number n of moles is constant
It is given that the initial and final temperature are equal, , therefore the products RT on both sides of the equation cancel, and Eq. (1.4) reduces to Eq. (1.1).
Problem 4
How many moles of nitrogen are present in a 50 L tank at 25 °C when the pressure is 10 atm? Numbers include only 3 significant figures.
![{\displaystyle n={\frac {p\,V}{R\,T}}={\frac {10.0\cdot 50.0}{0.0821\cdot (273+25.0)}}\quad \left[{\frac {\mathrm {atm} \cdot \mathrm {L} }{{\frac {\mathrm {atm} \cdot \mathrm {L} }{\mathrm {K} \cdot \mathrm {mol} }}\cdot \mathrm {K} }}\right]={\frac {500}{0.0821\cdot 298}}\quad \left[{\frac {\mathrm {mol} \cdot \mathrm {atm} \cdot \mathrm {L} }{\mathrm {atm} \cdot \mathrm {L} }}\right]=20.4\quad [\mathrm {mol} ]}](https://wikimedia.org/api/rest_v1/media/math/render/svg/89e953932c97ba45e51ff74fb86fde962035cbae)
Problem 5
Given is that dry air consists of 78.1% N2, 20.1% O2, and 0.8% Ar (volume percentages). The atomic weights of N, O, and Ar are 14.0, 16.0 and 39.9, respectively. Compute the mass of 1 m3 of dry air at 1 atm and 20 °C.
Answer
Since for ideal gases the volume V is proportional to the number of moles n, a volume percentage is equal to a molar percentage. For instance, for a mixture of two gases, it is easily shown that
which states that the molar percentage of gas 1 is equal to the volume percentage of gas 1.
The mass of 1 mole of dry air is
- M = 0.781×28.0 + 0.201×32.0 + 0.008×39.9 g = 28.6192 g
In problem 1 it is found that the volume of 1 mole of ideal gas at 1 atm and 20 °C is 24.0550 L = 24.0550×10−3 m3, or
- 1 m3 contains 1/(24.0550×10−3) = 41.5714 mol
Hence the mass of 1 cubic meter of dry air is
- M = 28.6192 × 41.5714 = 1189.7 g = 1.1897 kg