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Biology_A-level_Cie

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  1. 1-1-the-microscope-in-cell-studies
    5 主题
  2. 1-2-cells-as-the-basic-units-of-living-organisms
    5 主题
  3. 2-1-testing-for-biological-molecules
    3 主题
  4. 2-2-carbohydrates-and-lipids
    8 主题
  5. 2-3-proteins
    6 主题
  6. 2-4-water
    2 主题
  7. 3-1-mode-of-action-of-enzymes
    5 主题
  8. 3-2-factors-that-affect-enzyme-action
    8 主题
  9. 4-1-fluid-mosaic-membranes
    4 主题
  10. 4-2-movement-into-and-out-of-cells
    12 主题
  11. 5-1-replication-and-division-of-nuclei-and-cells
    6 主题
  12. 5-2-chromosome-behaviour-in-mitosis
    2 主题
  13. 6-1-structure-of-nucleic-acids-and-replication-of-dna
    4 主题
  14. 6-2-protein-synthesis
    5 主题
  15. 7-1-structure-of-transport-tissues
    4 主题
  16. 7-2-transport-mechanisms
    7 主题
  17. 8-1-the-circulatory-system
    7 主题
  18. 8-2-transport-of-oxygen-and-carbon-dioxide
    5 主题
  19. 8-3-the-heart
    4 主题
  20. 9-1-the-gas-exchange-system
    6 主题
  21. 10-1-infectious-diseases
    3 主题
  22. 10-2-antibiotics
    3 主题
  23. 11-1-the-immune-system
    4 主题
  24. 11-2-antibodies-and-vaccination
    6 主题
  25. 12-1-energy
    5 主题
  26. 12-2-respiration
    11 主题
  27. 13-1-photosynthesis-as-an-energy-transfer-process
    8 主题
  28. 13-2-investigation-of-limiting-factors
    2 主题
  29. 14-1-homeostasis-in-mammals
    8 主题
  30. 14-2-homeostasis-in-plants
    3 主题
  31. 15-1-control-and-coordination-in-mammals
    12 主题
  32. 15-2-control-and-coordination-in-plants
    3 主题
  33. 16-1-passage-of-information-from-parents-to-offspring
    5 主题
  34. 16-2-the-roles-of-genes-in-determining-the-phenotype
    7 主题
  35. 16-3-gene-control
    3 主题
  36. 17-1-variation
    4 主题
  37. 17-2-natural-and-artificial-selection
    7 主题
  38. 17-3-evolution
    2 主题
  39. 18-1-classification
    5 主题
  40. 18-2-biodiversity
    7 主题
  41. 18-3-conservation
    6 主题
  42. 19-1-principles-of-genetic-technology
    11 主题
  43. 19-2-genetic-technology-applied-to-medicine
    4 主题
  44. 19-3-genetically-modified-organisms-in-agriculture
    2 主题
  45. 1-1-the-microscope-in-cell-studies
  46. 1-2-cells-as-the-basic-units-of-living-organisms
  47. 2-1-testing-for-biological-molecules
  48. 2-2-carbohydrates-and-lipids
  49. 2-3-proteins
  50. 2-4-water
  51. 3-1-mode-of-action-of-enzymes
  52. 3-2-factors-that-affect-enzyme-action
  53. 4-1-fluid-mosaic-membranes
  54. 4-2-movement-into-and-out-of-cells
  55. 5-1-replication-and-division-of-nuclei-and-cells
  56. 5-2-chromosome-behaviour-in-mitosis
  57. 6-1-structure-of-nucleic-acids-and-replication-of-dna
  58. 6-2-protein-synthesis
  59. 7-1-structure-of-transport-tissues
  60. 7-2-transport-mechanisms
  61. 8-1-the-circulatory-system
  62. 8-2-transport-of-oxygen-and-carbon-dioxide
  63. 8-3-the-heart
  64. 9-1-the-gas-exchange-system
  65. 10-1-infectious-diseases
  66. 10-2-antibiotics
  67. 11-1-the-immune-system
  68. 11-2-antibodies-and-vaccination
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Water & the transpiration pull

The movement of water

  • The mass flow of water in a plant is helped by the polar nature of water

    • Hydrogen bonds (H-bonds) form between water molecules which results in cohesion between water molecules and adhesion between the cellulose in the cell walls and the water molecules

  • Water moves from the roots to the leaves because of a difference in water potential between the top and bottom of the plant

    • This gradient is present due to the constant loss of water from the leaves by transpiration and the constant uptake of water at the roots by osmosis

  • The evaporation of water into the air spaces in the leaves creates tension in the xylem tissue which is transmitted all the way down the plant because of the cohesive nature of water molecules

    • The cohesive force results in a continuous column of water with high tensile strength (it is unlikely to break) and the adhesive force stops the water column from pulling away from the walls of the xylem vessels

    • This mechanism is called the cohesion-tension theory

  • Xylem vessels have lignified walls to prevent them from collapsing due to the pressure differences created by the mass flow of water down its water potential gradient

Diagram of water molecules moving through xylem cells. It shows adhesion and cohesion by hydrogen bonding along cell walls for transport.
Water molecules move in a continuous stream due to their cohesive nature caused by hydrogen bonds

The transpiration stream

  • The pathway of the water from the soil through the roots up the xylem tissue to the leaves is the transpiration stream

  • Plants aid the movement of water upwards by raising the water pressure in the roots; this is known as root pressure

    • Water enters the roots down a water potential gradient from the surrounding soil

      • Root cells actively transport solutes (e.g. mineral ions) from the cells of the root into the xylem vessels; this lowers the water potential within the xylem

      • Water is drawn into the xylem by osmosis from the surrounding cells, thus increasing the water pressure (root pressure)

  • Water travels across the root either via the apoplast pathway or the symplast pathway

    • Note that water in the apoplast pathway does not cross cell membranes, so does not move by osmosis

Water and the Transpiration pull (1), downloadable AS & A Level Biology revision notes
Diagram illustrating water uptake in roots, showing apoplastic and symplastic pathways through root hair, cortex, endodermis, and xylem vessels.
The transpiration stream involves the movement of water across the roots, up the xylem, and across the leaves of plants

Examiner Tips and Tricks

When answering questions about transpiration it is important to include the following keywords:

  • Water potential gradient (between leaves and roots),

  • Diffusion (of water vapour through the stomata)

  • Transpiration pull (evaporation of water from the mesophyll cells, of leaves, pulls other water molecules from the xylem tissue)

  • Cohesion (between water molecules)

  • Adhesion (between water molecules and cellulose within the cell walls)

  • Cohesion-tension theory (tension present in xylem vessels causes a continuous column of water and is due to cohesive and adhesive forces)

  • Osmosis (water moving via the symplast pathway across the roots and leaves)