Transpiration

1. Transpiration

2. Stomatal Mechanism

3. Stomata

4. Stomatal Mechanism • pores or gaps in the lower epidermis through which gaseous exchange and water loss take place • Found in leaves and stems • Surrounded bytwo guard cells that contain chloroplast and can photosynthesise • Guard cells control the size of the stoma by changes in turgidity

5. Stomatal Mechanism • guard cells consist of cellulose fibres arranged radially around each cell • Cell walls unevenly thickened • inner walls (ventral wall) much more packed with inelastic fibers, thicker, less elastic • Ventral walls expand less during turgidity

6. Stomatal Mechanism • outer walls (dorsal walls) are less packed with these fibres, thinner • they expand more during turgidity. • open during the day to allow the diffusion of CO2 into the plant needed for photosynthesis. • This depends on the structure and arrangement of the cellulose fibres around the guard cells of the stomata.

7. Stomatal Mechanism • during the day the guard cells acquire a lower water potential as ions are secreted into them • water subsequently is lost from them by transpiration • This contributes to a lower potential in the guard cells • water rushes into guard cells from the spongy mesophyll cells allowing for their expansion

8. Stomatal Mechanism • The inner walls will expand less than the outer walls • the inner portion increases in length • expansion outwards is prevented because of the close stacking of the inelastic cellulose fibres • Ends of guard cells joined-dorsal wall strectches more than ventral wall making each guard cell semi-circular • Hence, stoma appears between guard cells

9. Stomatal Mechanism • When the guard cells lose water by transpiration the pore closes • Transpiration is the main driving force for the opening and closing of the stoma • Opening of a stoma is a result in changes in pressure potential of the guard cells resulting from changes in water potential • Stomata open in light and close in darkness • In the light K+ ions and Cl- ions enter guard cells

10. Stomatal Mechanism • This lowers their water potential, water enters by osmosis • Hence, stoma opens • In darkness K+ ions move out of the guard cells into surrounding epidermal cells • Water potential of guard cells increases • Water moves out of the cells • Loss of pressure makes the guard cells change shape and the stoma closes

11. Measuring Transpiration

12. Measuring Transpiration • Use of potometer-measures the rate of water uptake by a cut shoot or young seedling • Does not measure transpiration directly but since most water taken up is lost by transpiration, the two processes are closely linked • As the shoot transpires the water vapour is replaced by water drawn in from the potometer via the xylem of the stem

13. Procedure • Cut a leafy shoot under water if possible to avoid air entering the xylem • Submerge the potometer in water, filling it with water • Fit shoot onto rubber tube ensuring a tight fit • Remove apparatus from water and shake off excess water • Seal joints around tube with vasaline to keep apparatus watertight

14. Procedure • Introduce an air bubble into the water column by using the syringe to push the water almost to the end of the capillary tube • Leave a small air space • Place open end of capillary tube in water • Draw up more water behind the air space • Measure the distance moved by the air space in a given time • Calculate the water uptake

15. Procedure • Repeat experiment under different conditions eg. light, temperature, still and moving air

16. Factors affecting Transpiration Rate • Temperature • Humidity and Vapour Pressure • Air Movement • Light

17. Temperature • a measure of the degree of heat in the environment • Temp affects transpiration because an increased temperature allows for a higher rate of evaporation from the leaves of the plant thus increasing the transpiration rate • temperature decreases the relative humidity of an environment which again increases transpiration rate

18. Humidity and Vapour Pressure • a measure of the concentration of water vapour/vapour pressure • high humidity - greater concentration of water molecules in the atmosphere just outside the leaves • This reduces the steepness of the diffusion gradient of water from inside to outside so that transpiration rate is significantly reduced • as humidity increases transpiration rate decreases and as humidity decreases transpiration rate increases

19. Air movement • allows for the displacement of the saturated water vapour around the leaves • this decreases the relative humidity and subsequently increases the transpiration rate

20. Light • affects the opening and the closing of the stomata • affects the movement of water into and out of the leaves by transpiration. • in the night when the stomata are closed the humidity outside decreases and in the morning the transpiration rate would increase