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8.1 and 8.2
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Energy The ability to do work. Different forms Mechanical Thermal
Chemical light
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Thermodynamics Study of the flow of transfer of energy in the universe. 2 laws Energy cannot be created or destroyed When energy is converted to different forms, there is a loss of usable energy. “Entropy Increases”
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Autotrophs and Heterotrophs
Autotrophs make their own food. Heterotrophs get food from autotrophs or other heterotrophs.
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How do organisms obtain energy?
Process of Metabolism -> all the chemical reactions in the cell = cell’s metabolism Photosynthesis -> light energy to chemical energy Cellular respiration-> molecules broken down to release energy
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2 Metabolic Pathways Anabolic -> use energy to build larger molecules from smaller molecules. Catabolic-> Releases energy through breakdown of molecules
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Adenosine Triphosphate
Most important biologic molecule that provides energy. Energy is stored between 2nd and 3rd phosphate bond. When that bond is broken energy is released.
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Basic Anatomy of a Plant
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LEAVES Usually contain chlorophyll and other pigments Other pigments: xanthnophyll, carotene Flat (collects sunlight better) Several layers Cuticle Mesophyll (spongy and palisade) Epidermis
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Stomata CO2 enters and O2 Leaves
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Photosynthesis Know this! It will be on your test
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Photosynthesis Occurs in 2 Phases Phase One: Light -Dependent Reaction
Phase Two: Light- Independent Reaction or Calvin Cycle
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Chloroplast captures light energy.
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The Process Light energy excites electrons in photosystem II and also causes a water molecule to split, releasing an electron into the electron transport system, H+ into the thylakoid space, and O2 as a waste product
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The Process The excited electrons move from photosystem II to an electron-acceptor molecule in the thylakoid. The electron-acceptor molecule transfers the electrons along a series of electron-carriers to photosystem I
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The Process Photosystem I transfers the electrons to a protein called ferrodoxin. Ferrodoxin transfers the electrons to the electron carrier NADP+, forming the energy-storing molecule NADPH.
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Chemiosmosis ATP is produced by the flow of electrons down the concentration gradient. H+ that is released when H2O is split helps drive chemiosmosis. H+ diffuses through ion channels and ATP is formed.
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Phase 2: The Calvin Cycle or light- independent reactions.
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Calvin Cycle Energy is stored in organic molecules like glucose
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Six CO2 molecules combine with six 5-carbon compounds to form twelve 3-carbon molecules called 3-PGA. The chemical energy stored in ATP and NADPH is transferred to the 3-PGA molecules to form high-energy molecules called G3P.
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Two G3P molecules leave the cycle to be used for the production of glucose and other organic compounds. An enzyme called rubisco converts the remaining ten G3P molecules into 5-carbon molecules called RuBP These molecules combine with new carbon dioxide molecules to continue the cycle.
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Alternative Pathways C4 Plants- Corn and Sugarcane
Fix CO2 in to 4- carbon molecules instead of 3- carbon molecules during Calvin Cycle. Close stomata prevent water loss -> 4- carbon molecule used during day so plant has plenty of CO2
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Alternative Pathways CAM plants- crassulacean acid metabolism
Plants in desert and salt marshes. Ex: cacti, orchids, and pineapples Take in and Fix CO2 at night
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