The process of photosynthesis

Photosynthesis is a complex process of synthesis of oganic food materials in which water is oxidised and CO2 is reduced to carbohydrates.

This process is summarised by the flow diagram below.

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Light-dependent reaction

  • Light energy results in the excitation of electrons in the chlorophyll.
  • These electrons are passed along a series of electron acceptors in the thylakoid membranes, collectively known as the electron carrier system.
  • Energy from excited electrons funds the production of ATP (adenosine triphosphate).
  • The final electron acceptor forms NADP+
  • Electron loss from chlorophyll causes the splitting of water (photolysis)
    • H2O = H+ + OH then 4OH = 2H2O + O2 + 4e
  • Oxygen is produced, water to re-use, and electrons stream back to replace those lost in the chlorophyll.
  • Hydrogen ions (H+) from photolysis, together with NADP+ form NADPH2


Light-independent reaction

  • Two useful substances are produced by the light-dependent stage, ATP and NADPH2. These are needed to drive the light-independent stage.
  • They react with glycerate-3-phosphate (GP) to produce a triose sugar – triose phosphate.
  • Triose phosphate is used either to produce a 6C sugar or to form ribulose bisphosphate (RuBP).
  • The conversion of triose phosphate (3C) to RuBP begins Calvin’s cycle and utilises ATP, which supplies the energy required.
  • A RuBP molecule (5C) together with a carbon dioxide molecule (1C) forms two GP molecules (2  3C) to complete Calvin’s cycle.
  • The GP is then available to react with ATP and NADPH2 to synthesise more

    triose sugar or RuBP.

Calvin Cycle (C3 Cycle)

  • Observed by Melvin Calvin in chlorella (single-cell green algae).
  • Carbon dioxide is converted into sugar so it is a process of carbon fixation.
  • First stable compound produced is 3-Phosphoglyceric acid (a 3-carbon molecule), often referred to as PGA.

Hatch & Slack Cycle (C4 Cycle)

  • Discovered by Marshall Davidson Hatch and C.R. Slack in Australia in 1966.
  • Alternative pathway of the Calvin Cycle, taking place during the dark phase of photosynthesis.
  • First stable compound formed is Oxaloacatic acid (a 4-carbon molecule).
  • Only produced in C4 plants (about 7,600 species), often possessing a leaf anatomy called kranz anatomy.
  • Evolved from the C3 process to withstand drought, high temperatures and CO2 limitations.

How do the photosystems contribute to photosynthesis?

This can be explained in terms of the Z scheme shown below.

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Non-cyclic photophosphorylation

  • Light reaches the chlorophyll of both photosystems (P680 and P700) which results in the excitation of electrons.
  • Electron acceptors receive these electrons (accepting electrons is reduction!).
  • P680 and P700 have become oxidised (loss of electrons is oxidation!).
  • P680 receives electrons from the lysis (splitting) of water molecules and becomes neutral again.
  • Lysis of water molecules releases oxygen which is given off.
  • Electrons are elevated to a higher energy level by P680 to electron acceptor A and are passed along a series of electron carriers to P700.
  • Passage along the electron carrier system funds the production of ATP.
  • The electrons pass along a further chain of electron carriers to NADP, which becomes reduced, and at the same time this combines with H+ ions to form NADPH2.

Cyclic photophosphorylation

  • Electrons from acceptor B move along an electron carrier chain to P700.
  • Electron passage along the electron carrier system funds the production of ATP.
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