▼ Part A According to Henry's law, the solubility of a gas in a liquid decreases as the gas pressure above the liquid increases depends on the liquid density increases as the gas pressure above the liquid increases remains the same as the temperature increases depends on the liquid polarity Submit Request Answer Provide Feedback

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**Part A** According to Henry's law, the solubility of a gas in a liquid: - decreases as the gas pressure above the liquid increases - depends on the liquid density - increases as the gas pressure above the liquid increases - remains the same as the temperature increases - depends on the liquid polarity **Buttons:** - Submit - Request Answer [Link: Provide Feedback] --- *Note: Inclusion of answer options allows students to test their understanding of Henry's Law and its implications on gas solubility.*

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**Homework Chapter 9 - Attempt 1** **Problem 9.70 - Enhanced - with Feedback** You may want to reference (Pages 306 - 309) Section 9.6 while completing this problem. --- **Part A** Will a red blood cell undergo crenation, hemolysis, or no change in each of the following solutions? Drag the appropriate items to their respective bins: - **Options:** - 0.9% (m/v) NaCl - 0.4% (m/v) NaCl - 7% (m/v) NaCl - 4% (m/v) glucose - **Bins:** - Crenation - Hemolysis - No change [Submit] [Request Answer] --- **Explanation for Educational Context:** This problem involves understanding the effects of different solutions on red blood cells: 1. **Crenation:** This occurs when red blood cells shrink due to being in a hypertonic solution where there is a higher concentration of solutes outside the cell than inside. Water moves out of the cell, leading to shrinkage. 2. **Hemolysis:** This occurs when red blood cells swell and burst due to being in a hypotonic solution where there is a lower concentration of solutes outside the cell than inside. Water moves into the cell, causing it to swell and potentially burst. 3. **No change:** This occurs when red blood cells are in an isotonic solution, where the concentration of solutes is equal inside and outside of the cell, resulting in no net water movement. This exercise will help deepen your understanding of osmosis and its impact on cell morphology.