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Use the following information to answer the question:

Ideal Gas Law:
[tex]\[ PV = nRT \][/tex]

Ideal Gas Constants:
[tex]\[ R = 8.314 \frac{L \cdot kPa}{mol \cdot K} \][/tex]
or
[tex]\[ R = 0.0821 \frac{L \cdot atm}{mol \cdot K} \][/tex]

Standard Atmospheric Pressure:
[tex]\[ 1 atm = 101.3 kPa \][/tex]

Celsius to Kelvin Conversion:
[tex]\[ K = °C + 273.15 \][/tex]

Question:

Air is a mixture of many gases. A 25.0-liter jar of air contains 0.0104 mole of argon at a temperature of [tex]\( 273 \, K \)[/tex]. What is the partial pressure of argon in the jar?

Type the correct answer in the box. Express your answer to three significant figures.

The partial pressure of argon in the jar is [tex]\( \boxed{} \)[/tex] kilopascal.

Sagot :

GinnyAnsweridn
To determine the partial pressure of argon in a 25.0-liter jar at a temperature of 273 K containing 0.0104 moles of argon, we'll use the Ideal Gas Law, expressed as [tex]\( PV = nRT \)[/tex].

Here are the steps we need to follow:

1. Identify the given values:
- Volume ([tex]\(V\)[/tex]): 25.0 liters
- Moles of argon ([tex]\(n\)[/tex]): 0.0104 moles
- Temperature ([tex]\(T\)[/tex]): 273 Kelvin
- Ideal gas constant ([tex]\(R\)[/tex]): 8.314 [tex]\(\frac{L \cdot kPa}{mol \cdot K}\)[/tex]

2. Rearrange the Ideal Gas Law to solve for the partial pressure ([tex]\(P\)[/tex]):
The formula for the Ideal Gas Law is [tex]\( PV = nRT \)[/tex]. To find the partial pressure, [tex]\(P\)[/tex], we rearrange this equation:
[tex]\[ P = \frac{nRT}{V} \][/tex]

3. Substitute the given values into the equation:
[tex]\[ P = \frac{(0.0104 \, \text{mol}) \times (8.314 \, \frac{\text{L} \cdot \text{kPa}}{\text{mol} \cdot \text{K}}) \times (273 \, \text{K})}{25.0 \, \text{L}} \][/tex]

4. Calculate the partial pressure:
[tex]\[ P = \frac{(0.0104) \times (8.314) \times (273)}{25.0} \][/tex]

After calculating, we find that:
[tex]\[ P \approx 0.944 \, \text{kPa} \][/tex]

Therefore, the partial pressure of argon in the jar is 0.944 kilopascals.
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