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Learn about photosynthesis, the process of converting light energy into chemical energy in plants. Understand how different colors of light are absorbed by chlorophyll and why leaves appear green. Explore the effects of temperature, light intensity, and carbon dioxide concentration on the rate of photosynthesis. Measure the rate of photosynthesis through the production of oxygen or the uptake of carbon dioxide. Design your own experiment to investigate photosynthesis using leaf discs.
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3.8.1 State that photosynthesis involves the conversion of light energy into chemical energy. 3.8.2 State that light from the Sun is composed of a range of wavelengths (colours). 3.8.3 State that chlorophyll is the main photosynthetic pigment. 3.8.4 Outline the differences in absorption of red, blue and green light by chlorophyll.
What is photosynthesis? The conversion of light energy into chemical energy in plants.
The Visible Spectrum Light from the sun is made of a range of colours. This is a result of the different wavelengths of light. Blue light has a shorter wavelength and more energy. Red light has a longer wavelength and less energy.
Chlorophyll Chlorophyll traps sunlight. It is the main photosynthetic pigment in plants
Why do leaves look green? visible light Red and blue light is absorbed by the leaf. Green light is reflected and reaches our eyes
Green light is reflected and reaches our eyes visible light Leaf extract (chlorophyll) The amount of red and blue,light absorbed can be measured using a spectrophotometer
Try this: Why are plants not always green?
Absorption Spectrum If we pass light through a leaf extract and measure how much of each wavelength of light is absorbed we produce an absorption spectrum. The main colours of light absorbed are red and blue. The main colour reflected is green.
Action Spectrum If we pass different wavelengths of light through a leaf extract and measure the rate of photosynthesis we get an action spectrum.
Comparing the Spectra Both show peaks in the red and blue areas of the visible spectrum. However, there is activity in wavelengths where there is no absorption. This is evidence for the presence of other pigments, e.g. carotenoids.
chlorophyll a chlorophyll b carotenoids
Try this: Plant pigment chromatography
Assessment Statements: 3.8.5 State that light energy is used to produce ATP, and to split water molecules (photolysis) to form oxygen and hydrogen. 3.8.6 State that ATP and hydrogen (derived from the photolysis of water) are used to fix carbon dioxide to make organic molecules.
What is the light used for? To produce ATP and to split water molecules to form oxygen (released as a waste product) and hydrogen. The ATP and hydrogen are used to fix carbon dioxide into glucose.
Assessment Statement: 3.8.7 Explain that the rate of photosynthesis can be measured directly by the production of oxygen or the uptake of carbon dioxide, or indirectly by an increase in biomass.
What can we measure? How? How quickly raw materials are used: e.g. water and carbon dioxide How quickly products are formed: e.g. oxygen production and biomass
Controlling Variables Water plants like Elodea are ideal as we can see the oxygen forming. Controlling temperature is always important when enzymes are involved. The water bath keeps the temperature constant.
Photosynthesis Design Lab Design an experiment to investigate photosynthesis using leaf discs.
Assessment Statement: 3.8.8 Outline the effects of temperature, light intensity and carbon dioxide concentration on the rate of photosynthesis.
Effect of changing light intensity Increasing the light intensity has no effect on the rate. Other factors are limiting (carbon dioxide or temperature). As the light intensity increases the rate of photosynthesis also increases. At low light intensity the plant is respiring.
Effect of changing carbon dioxide Increasing the carbon dioxide has no effect on the rate. Leaves are saturated with carbon dioxide. Other factors are limiting. As the carbon dioxide increases the rate of photosynthesis also increases. The limiting factor is the carbon dioxide concentration.
Effect of changing temperature As the temperature and kinetic energy increase the rate of photosynthesis also increases. Enzymes needed for photosynthesis work better in warmer temperatures. Plant enzymes have an optimum of about 25oC and are denatured at 45oC Maximum rate at optimum temperature