WATER POTENTIAL

1. WATER POTENTIAL

2. Osmosis • Osmosis = the movement of water molecules from a region of higher water potential to a region of lower water potential through a partially permeable membrane. Osmosis is considered in terms of water potential and solute potential.

3. Water Potential • Water potential = a measure of the kinetic energy of water molecules. Here, water molecules are constantly moving in a random fashion. Some of them collide with cell membrane, cell wall, creating a pressure on its known as water potential. • The higher their kinetic energy the more they move and hit the membrane, therefore higher the water potential

4. Water potential How does water move? Why does water move? Downhill 1. Pressure potential 2. Hose, straw 3. Fresh – salty Osmotic/solute potential 4. Sponge Matric potential

5. Components of Water Potential • Pressure potential: pushing (positive pressure, like the hose) sucking (negative pressure, like a straw)Major factor moving water through plants • Osmotic, or Solute potential: reduction in water potential due • to the presence of dissolved solutes • Dissolved substances dilute pure water, so • salty water has lower water potential (lower concentration) than pure water

6. Water Potential • Unit of measurement: megapascals (Mpa) 1 MegaPascal = 10 atm = 145.1 psi • Water potential for pure water: 0 • Anything that lowers the “free energy”of water lowers it potential. -dissolved solutes

7. Water potential = pressure potential + solute potential

8. Clarifying Water Potential Values • (2) Factors to consider: p = pressure potential (outside & inside) s = solute potential system = p + s SO……  presults in “+” value  presults in “-” value

9. Water Potential Values • High water potential (+Value): - less solute - more water - (hypotonic) • Zero (0) Value: - Pure water • Low water potential (-Value): - More solute - less water - (hypertonic) ****Water will move across a membrane in the direction of the lower water potential****

10. Calculating Solute Potential • Variables involved: i, C, R, T i = ionization constant: NaCl = 2.0 (Na+ & Cl-) **for sucrose it will be 1.0 (it doesn’t ionize) C = Molar concentration of your potato (graph) R= rate constant: 0.0821 L · atm (bar) mol · K T = Temperature: K

11. Calculating the Solute Potential (s) • s = - iCRT • Sample Calc. A 1.0 M sugar solution @ 22° C under standard atmospheric conditions: s = -(1)(1.0mol)(0.0821 L · bar )(295K) L mol · K s = -24.22 bars

12. Typical Water Potential Values • Outside air (50% humidity): -100 MPa • Outside air (90% humidity): -13 MPa • Leaf Tissue: -1.5 MPa • Stem: -0.7 MPa • Root: -0.4 MPa • Soil water: -0.1 MPa • Hydrated soil (Saturated) +2 - +5 MPa ** When the soil is extremely dry what happens to the water potential and water movement into the plant? **Does the value become more negative or more positive?

13. Water Potential in Plants

14. Water Balance (pg. 117-118) • Osmoregulation~ control of water balance • Hypertonic~ higher concentration of solutes • Hypotonic~ lower concentration of solutes • Isotonic~ equal concentrations of solutes • Cells with Walls: • Turgid (very firm) • Flaccid (limp) • Plasmolysis~ plasma membrane pulls away from cell wall

15. Dialysis Tubing Experiment

16. An Artificial CellPermeable to: monosaccharides & waterImpermeable to: Disaccharides