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Optimizing Plant Nutrition: Understanding Soil Profiles and Nutrient Exchange

Explore the importance of mineral nutrient deficiency symptoms, essential elements for plant growth, root signaling for colonization, nitrogen fixation, ion transport mechanisms, and the pressure flow model in plant nutrition. Learn about the significance of water potential, solute potential, and pressure potential in maintaining plant health. Discover how stomata regulate gas exchange and transpiration for optimal plant function.

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Optimizing Plant Nutrition: Understanding Soil Profiles and Nutrient Exchange

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  1. Chapter 25 Opener

  2. In-Text Art, Ch. 25, p. 522

  3. Figure 25.1 Mineral Nutrient Deficiency Symptoms

  4. Figure 25.2 Nickel Is an Essential Element for Plants

  5. Figure 25.2 Nickel Is an Essential Element for Plants (Part 1)

  6. Figure 25.2 Nickel Is an Essential Element for Plants (Part 2)

  7. Figure 25.3 A Soil Profile

  8. Figure 25.4 Ion Exchange

  9. Figure 25.4 Ion Exchange

  10. Figure 25.5 Roots Send Signals for Colonization

  11. Figure 25.5 Roots Send Signals for Colonization

  12. Figure 25.5 Roots Send Signals for Colonization (Part 1)

  13. Figure 25.5 Roots Send Signals for Colonization (Part 2)

  14. Figure 25.5 Roots Send Signals for Colonization (Part 3)

  15. Apply the Concept, Ch. 25, p. 527

  16. Figure 25.6 Nitrogenase Fixes Nitrogen

  17. Figure 25.6 Nitrogenase Fixes Nitrogen

  18. Figure 25.7 Nutrients from Other Organisms

  19. Figure 25.7 Nutrients from Other Organisms (Part 1)

  20. Figure 25.7 Nutrients from Other Organisms (Part 2)

  21. Figure 25.8 Water Potential, Solute Potential, and Pressure Potential

  22. Figure 25.8 Water Potential, Solute Potential, and Pressure Potential

  23. Figure 25.8 Water Potential, Solute Potential, and Pressure Potential (Part 1)

  24. Figure 25.8 Water Potential, Solute Potential, and Pressure Potential (Part 2)

  25. Figure 25.9 A Wilted Plant

  26. Figure 25.9 A Wilted Plant

  27. Figure 25.10 Ion Transport into Plant Cells

  28. Figure 25.10 Ion Transport into Plant Cells

  29. Figure 25.11 Apoplast and Symplast

  30. Figure 25.11 Apoplast and Symplast

  31. Figure 25.11 Apoplast and Symplast (Part 1)

  32. Figure 25.11 Apoplast and Symplast (Part 2)

  33. Figure 25.12 The Transpiration–Cohesion–Tension Mechanism

  34. Figure 25.12 The Transpiration–Cohesion–Tension Mechanism

  35. Figure 25.13 Stomata Regulate Gas Exchange and Transpiration

  36. Figure 25.13 Stomata Regulate Gas Exchange and Transpiration

  37. Figure 25.13 Stomata Regulate Gas Exchange and Transpiration (Part 1)

  38. Figure 25.13 Stomata Regulate Gas Exchange and Transpiration (Part 2)

  39. Apply the Concept, Ch. 25, p. 534

  40. In-Text Art, Ch. 25, p. 535 (1)

  41. In-Text Art, Ch. 25, p. 535 (1)

  42. In-Text Art, Ch. 25, p. 535 (2)

  43. In-Text Art, Ch. 25, p. 535 (2)

  44. Figure 25.14 The Pressure Flow Model

  45. Figure 25.14 The Pressure Flow Model

  46. Figure 25.15 Conservation Tillage

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