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http://swagct.com/uploads/2012/09/1_1347535212.jpg. Test Corrections: Due 3/28. IF you received a “D” or an “F” Answer each question in a bulleted or numbered format (as seen below)

wilma-allen
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  1. http://swagct.com/uploads/2012/09/1_1347535212.jpg

  2. Test Corrections: Due 3/28 • IF you received a “D” or an “F” • Answer each question in a bulleted or numbered format (as seen below) • You can earn ½ of the amount of points you lost on the question, only if you answer all the questions for each question you want points back for: • Why did you chose the answer you did? • Why is that answer incorrect? • What is the right answer? • Why is that answer correct?

  3. Extra Credit Essay • Due Today at 3:30

  4. What Would Plants Look Like On Alien Planets? • Switch papers with your table partner

  5. Visible Light • Light is a form of electromagnetic energy, which travels in waves • When white light passes through a prism the individual wavelengths are separated out.

  6. Light Options When It Strikes A Leaf • Reflect – a small amount of light is reflected off of the leaf. Most leaves reflect the color green, which means that it absorbs all of the other colors or wavelengths. • Absorbed – most of the light is absorbed by plants providing the energy needed for the production of Glucose (photosynthesis) • Transmitted – some light passes through the leaf

  7. Mesophyll Chloroplast 5 µm Outer membrane Intermembrane space Thylakoid Thylakoid space Granum Stroma Inner membrane 1 µm Chloroplast • Are located within the palisade layer of the leaf • Stacks of membrane sacs called Thylakoids • Contain pigments on the surface • Pigments absorb certain wavelengths of light • A Stack of Thylakoids is called a Granum

  8. Chloroplast

  9. Mesophyll Chloroplast 5 µm Outer membrane Intermembrane space Thylakoid Thylakoid space Granum Stroma Inner membrane 1 µm Chloroplast • Are located within the palisade layer of the leaf • One Membrane sacs called Thylakoids • Contain pigments on the surface • Pigments absorb certain wavelenghts of light • A Stack of Thylakoids is called a Granum

  10. PHOTOSYNTHESIS • Comes from Greek Word “photo” meaning “Light” and “syntithenai” meaning “to put together” • Photosynthesis puts together sugar molecules using water, carbon dioxide, & energy from light.

  11. Happens in two phases • Light-Dependent Reaction • Converts light energy into chemical energy • Light-Independent Reaction • Produces simple sugars (glucose) • General Equation • 6 CO2 + 6 H2O+ light energy  C6H12O6 + 6 O2 • INPUTS OUTPUTS

  12. First Phase • Requires Light = Light Dependent Reaction • Sun’s energy excites an electron in the chlorophyll molecule • Electron is passed to nearby protein molecules in the thylakoid membrane of the chloroplast

  13. Excited state e– Heat Energy of election Photon (fluorescence) Ground state Chlorophyll molecule Photon Figure 10.11 A Excitation of Chlorophyll by Light • When a pigment absorbs light it absorbs energy • It goes from a ground state to an excited state, which is unstable

  14. Electron Transport Chain • Electron from Chlorophyll is passed from protein to protein along an electron transport chain • Electrons lose energy (energy changes form) • Finally bonded with electron carrier called NADP+ to form NADPH or ATP • Energy is stored for later use

  15. Two Photosystems • Photosystem II: Clusters of pigments boost e- by absorbing light w/ wavelength of ~680 nm • Photosystem I: Clusters boost e- by absorbing light w/ wavelength of ~760 nm. • Reaction Center: Both PS have it. Energy is passed to a special Chlorophyll a molecule which boosts an e-

  16. e– ATP e– e– NADPH e– e– e– Mill makes ATP Photon e– Photon Photosystem I Photosystem II Figure 10.14  • A mechanical analogy for the light reactions

  17. Thylakoid Photosystem Photon STROMA Light-harvesting complexes Reaction center Primary election acceptor e– Thylakoid membrane Special chlorophyll a molecules Transfer of energy Pigment molecules THYLAKOID SPACE (INTERIOR OF THYLAKOID) Figure 10.12 Photosystem • A photosystem • Is composed of a reaction center surrounded by a number of light-harvesting complexes

  18. H2O CO2 Light NADP  ADP + P LIGHT REACTIONS CALVIN CYCLE ATP NADPH Chloroplast [CH2O] (sugar) O2 Figure 10.5

  19. Where did those electrons come from? • Water • Electrons from the splitting of water supply the chlorophyll molecules with the electrons they need • The left over oxygen is given off as gas

  20. High Quality H2O • Electrolysis: Splitting of water with light energy • Hydrogen ions (H+) from water are used to power ATP formation with the electrons • Hydrogen ions (charged particle) actually move from one side of the thylakoid membrane to the other • Chemiosmosis – Coupling the movement of Hydrogen Ions to ATP production

  21. Vocab

  22. e– ATP e– e– NADPH e– e– e– Mill makes ATP Photon e– Photon Photosystem I (NADPH-producing) Photosystem II (Water-splitting) Figure 10.14  Light-Dependent • Converts light into chemical energy (ATP & NADPH are the chemical products). Oxygen is a by-product

  23. Pigment • Molecules that absorb specific wavelengths of light • Chlorophyll absorbs reds & blues and reflects green

  24. Chlorophyll • Green pigment in plants • Traps sun’s energy • Sunlight energizes electron in chlorophyll

  25. Electron Transport Chain • Series of Proteins embedded in a membrane that transports electrons to an electron carrier

  26. ATP • Adenosine Triphosphate • Stores energy in high energy bonds between phosphates • ATP, or adenosine triphosphate, is a method of energy storage in living organisms

  27. NADPH • During the Light Dependent Cycle of photosynthesis, light is absorbed by the chlorophyll. • The electrons are excited, which starts them moving from one enzyme to another. • A hydrogen atom attaches itself to an NADP+molecule, converting it to NADPH • Stores the high energy electrons for use during light-Independent reaction (Calvin Cycle)

  28. What types of energy are there? Some words you might have used: chemical, potential, gravitational, kinetic, thermal, mechanical…

  29. Engage: What’s Going On Inside a Cell? What types of energy are there? • Food gives us E (energy) but NOT until we break it (down) into anthr (another) form. • Food is stored as chem E (chemical energy). • It has the potential to give us E but not until smthing (something) else is done to it…

  30. Engage: What’s Going On Inside a Cell? Get it Straight… • When we eat a food that has protein (prtn), that protein is notincorp. Immed into our muscles. • The prtn and other nut. are broken into sm. organ. mole. • Remem. from Chap 6 that sm organ. mole.’s r used to build the specific prtn& other mac. mole that r used by plant & animal cells. • So, don’t think that we eat smthg and it goes “straight to our hips” (or muscles or wherever)…

  31. Exit Ticket On a separate sheet of paper answer the following questions: • How do plants get energy and matter for growth? • How is energy transferred from one form to another? • How do plants get their energy from light sources? • What are the inputs and outputs of photosynthesis? • Why does photosynthesis only occur in the chloroplasts?

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