Chlorophyll (Science Experiments)
Why leaves change color
Response to Light: Do plants grow differently in different colors of light?
ChlorophyllA green pigment found in plants that absorbs sunlight, providing the energy used in photosynthesis. is the green pigment that gives leaves their color. Acting as a solar collector, chlorophyll absorbs light energy from the sun and traps it. This trapped energy is stored, then used to form sugar and oxygen out of carbon dioxide from the air and water from the soil. This extraordinary process is called . It is the way a plant makes its own food. But the key to this process is chlorophyll.
Pierre Joseph Pelletier and Joseph Biernaime Caventou were French chemists who worked together in the early nineteenth century in a new field called , the science of preparing medical drugs. These chemists would later discover quinine, caffeine, and other specialized plant products. In 1817, however, they isolated an important plant substance they called chlorophyll, from the Greek words meaning "green leaf." Scientists first thought that chlorophyll was distributed throughout...
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Chlorophyll (World of Microbiology and Immunology)
Chlorophyll is a green pigment contained in the foliage of plants, giving them their notable coloration. This pigment is responsible for absorbing sunlight required for the production of sugar molecules, and ultimately of all biochemicals, in the plant.
Chlorophyll is found in the thylakoid sacs of the chloroplast. The chloroplast is a specialized part of the cell that functions as an organelle. Once the appropriate wavelengths of light are absorbed by the chlorophyll into the thylakoid sacs, the important process of photosynthesis is able to begin. In photosynthesis, the chloroplast absorbs light energy, and converts it into the chemical energy of simple sugars.
Vascular plants, which can absorb and conduct moisture and nutrients through specialized systems, have two different types of chlorophyll. The two types of chlorophyll, designated as chlorophyll a and b, differ slightly in chemical makeup and in color. These chlorophyll molecules are associated with specialized proteins that are able to penetrate into or span the membrane of the thylakoid sac.
When a chlorophyll molecule absorbs light energy, it becomes an excited state, which allows the initial chain reaction of photosynthesis to occur. The pigment molecules cluster together in what is called a photosynthetic unit. Several hundred chlorophyll a and chlorophyll b molecules are found in one photosynthetic unit.
A photosynthetic unit absorbs light energy. Red and blue wavelengths of light are absorbed. Green light cannot be absorbed by the chlorophyll and the light is reflected, making the plant appear green. Once the light energy penetrates these pigment molecules, the energy is passed to one chlorophyll molecule, called the reaction center chlorophyll. When this molecule becomes excited, the light reactions of photosynthesis can proceed. With carbon dioxide, water, and the help of specialized enzymes, the light energy absorbed creates chemical energy in a form the cell can use to carry on its processes.
In addition to chlorophyll, there are other pigments known as accessory pigments that are able to absorb light where the chlorophyll is unable to. Carotenoids, like B-carotenoid, are also located in the thylakoid membrane. Carotenoids give carrots and some autumn leaves their color. Several different pigments are found in the chloroplasts of algae, bacteria, and diatoms, coloring them varying shades of red, orange, blue, and violet.
See also Autotrophic bacteria; Blue-green algae