A solution contains 0.010 moles of a nonvolatile solute in 1.00 kg water. Using π = MRT with T = 298 K, R = 0.0821 L atm mol−1 K−1, and M ≈ 0.010 M, what is the osmotic pressure?

Unlock all questions

This demo includes only 20 questions. Upgrade to access hundreds of questions, flashcards, exam simulations, and disable ads.

Full question bankExam simulationsFlashcards
From $9.99Unlock all

Prepare for your Honors Chemistry Exam with our interactive quiz. Use flashcards and multiple choice questions. Gain confidence and pass your test!

Multiple Choice

A solution contains 0.010 moles of a nonvolatile solute in 1.00 kg water. Using π = MRT with T = 298 K, R = 0.0821 L atm mol−1 K−1, and M ≈ 0.010 M, what is the osmotic pressure?

Explanation:
Osmotic pressure is driven by the number of solute particles in solution and increases with temperature. For a dilute solution, the van't Hoff relation π = MRT gives a good estimate, where M is the molarity, R is the gas constant, and T is temperature in kelvin. Here, 0.010 moles of solute are in about 1.00 kg of water. Since 1 L of water has a mass of roughly 1 kg, the solution’s volume is about 1.00 L, so the concentration is about 0.010 mol per liter, i.e., M ≈ 0.010 M. Plug in the values: π = (0.010 mol/L)(0.0821 L atm mol−1 K−1)(298 K). Calculate the product: 0.0821 × 298 ≈ 24.46, and multiplying by 0.010 gives π ≈ 0.2446 atm. Rounding, the osmotic pressure is about 0.245 atm. This result reflects that a small amount of nonvolatile solute in water at room temperature produces a modest osmotic pressure, consistent with dilute-solution behavior.

Osmotic pressure is driven by the number of solute particles in solution and increases with temperature. For a dilute solution, the van't Hoff relation π = MRT gives a good estimate, where M is the molarity, R is the gas constant, and T is temperature in kelvin.

Here, 0.010 moles of solute are in about 1.00 kg of water. Since 1 L of water has a mass of roughly 1 kg, the solution’s volume is about 1.00 L, so the concentration is about 0.010 mol per liter, i.e., M ≈ 0.010 M.

Plug in the values: π = (0.010 mol/L)(0.0821 L atm mol−1 K−1)(298 K).

Calculate the product: 0.0821 × 298 ≈ 24.46, and multiplying by 0.010 gives π ≈ 0.2446 atm. Rounding, the osmotic pressure is about 0.245 atm.

This result reflects that a small amount of nonvolatile solute in water at room temperature produces a modest osmotic pressure, consistent with dilute-solution behavior.

More Multiple Choice Questions
Subscribe

Get the latest from Examzify

You can unsubscribe at any time. Read our privacy policy