1 / 18

Diffusion of Water (Osmosis)

Diffusion of Water (Osmosis). To survive, plants must balance water uptake and loss Osmosis determines the net uptake or water loss by a cell and is affected by solute concentration and pressure. Water potential is a measurement that combines the effects of solute concentration and pressure

kamea
Download Presentation

Diffusion of Water (Osmosis)

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Diffusion of Water (Osmosis) • To survive, plants must balance water uptake and loss • Osmosis determines the net uptake or water loss by a cell and is affected by solute concentration and pressure

  2. Water potential is a measurement that combines the effects of solute concentration and pressure • Ψ =ΨP + ΨS • Water potential determines the direction of movement of water • Water flows from regions of higher water potential to regions of lower water potential

  3. Water potential is abbreviated as Ψand measured in units of pressure called megapascals (MPa) • Ψ = 0 MPa for pure water at sea level and room temperature

  4. How Solutes and Pressure Affect Water Potential • Both pressure and solute concentration affect water potential • The solute potential (ΨS) of a solution is proportional to the number of dissolved molecules • Solute potential is also called osmotic potential

  5. Pressure potential (ΨP) is the physical pressure on a solution • Turgor pressure is the pressure exerted by the plasma membrane against the cell wall, and the cell wall against the protoplast

  6. Measuring Water Potential • Consider a U-shaped tube where the two arms are separated by a membrane permeable only to water • Water moves in the direction from higher water potential to lower water potential

  7. Fig. 36-8a (a) 0.1 Msolution The addition of solutes reduces water potential Purewater H2O ψP= 0ψS = −0.23 ψP= 0ψS= 0 ψ= −0.23 MPa ψ= 0 MPa

  8. Fig. 36-8b (b) Positivepressure Physical pressure increases water potential H2O ψP= 0.23ψS = −0.23 ψP= 0ψS= 0 ψ= 0 MPa ψ= 0 MPa

  9. Fig. 36-8c (c) Increasedpositivepressure Further Physical pressure increases water potential more H2O ψP =  ψS = −0.23 ψP= 0ψS= 0 0.30 ψ= 0.07 MPa ψ= 0 MPa

  10. Fig. 36-8d (d) Negativepressure(tension) Negative pressure decreases water potential H2O ψP =ψS = −0.23 ψP = −0.30ψS = 0 0 ψ= −0.30 MPa ψ= −0.23 MPa

  11. Fig. 36-9a If a flaccid cell is placed in an environment with a higher solute concentration, the cell will lose water and undergo plasmolysis Initial flaccid cell: ψP= 0ψS = −0.7 0.4 M sucrose solution: ψ= −0.7 MPa ψP= 0 ψS = −0.9 ψ= −0.9 MPa Plasmolyzed cell ψP= 0 ψS = −0.9 ψ= −0.9 MPa (a) Initial conditions: cellular ψ > environmental ψ

  12. Fig. 36-9b If the same flaccid cell is placed in a solution with a lower solute concentration, the cell will gain water and become turgid Initial flaccid cell: ψP = 0ψS = −0.7 Pure water: ψ= −0.7 MPa ψP = 0ψS = 0 ψ= 0 MPa Turgid cell ψP = 0.7ψS = −0.7 ψ = 0 MPa (b) Initial conditions: cellular ψ < environmental ψ

  13. solute potential (ΨS) ΨS = - iCRT i is the ionization constant C is the molar concentration R is the pressure constant (0.0831 liter bars/mole-K) T is the temperature in K (273 + C°)

  14. Calculating Water potential • Say you have a 0.15 M solution of sucrose at atmospheric pressure (ΨP = 0) at 25 °Ccalculate Ψ1st use ΨS = - iCRT to calculate ΨS i = 1 (sucrose does not ionize) C = 0.15 mole/literR = 0.0831 liter bars/ mole-KT = 25 + 273 = 298 K • ΨS = - (1)(.15M)(0.0831 liter bars/mole-K)(298 K) = -3.7 bars • 2nd use Ψ =ΨP + ΨS to calculate Ψ • Ψ =ΨP + ΨS = 0 + (-3.7bars) = -3.7 bars

  15. You try it Calculate Ψ of a 0.15M solution of of NaCl at atmospheric pressure (ΨP = 0) at 25 °C. Note: NaCl breaks into 2 pieces so i = 2. ΨS = - (2)(0.15mole/liter)(0.0831 liters bars/mole-K)(298 K) ΨS = - 7.43 bars Ψ = 0 + (-7.43 bars) Ψ = -7.43 bars

  16. You try it again Calculate the solute potential of a 0.1 M NaCl solution at 25 °C. If the NaCL concentration inside a plant cell is 0.15 M, which way will the water diffuse if the cell is placed into the 0.1 M NaCl solution? ΨS = - (2)(0.10 mole/liter)(0.0831 liters bars/mole-K)(298 K) = - 4.95 bars (solution) ΨS = - (2)(0.15mole/liter)(0.0831 liters bars/mole-K)(298 K) = - 7.43 bars (cell) Water will move from solution to cell.

  17. What must Turgor Pressure (ΨP)equal if there is no net diffusion between the solution and the cell? ΨP in cell must equal 2.49 Goal to make Ψ of cell = Ψ of solution (-4.95) Ψ =ΨP + ΨS (of cell) Ψ = 2.49 + (-7.43) Ψ = -4.95

  18. Diffusion & Osmosis Lab Read the background material for Lab 4 – Diffusion and Osmosis Procedure 1 – Plasmolysis Procedure 2 – Osmosis & Diffusion on Plant Tissue Procedure 3 – Inquiry

More Related