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Energy and Photosynthesis

Energy and Photosynthesis. What is Energy? – Ability to do work….. ughh … Kinetic Energy? – Energy in Action Examples Potential Energy? – Stored Energy Examples What is the Conservation of Energy? ENERGY CANNOT BE CREATED OR DESTROYED!. Adenosine Tri Phosphate (ATP). Adenine. Ribose.

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Energy and Photosynthesis

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  1. Energy and Photosynthesis • What is Energy? – Ability to do work…..ughh… • Kinetic Energy? – Energy in Action • Examples • Potential Energy? – Stored Energy • Examples • What is the Conservation of Energy? • ENERGY CANNOT BE CREATED OR DESTROYED!

  2. Adenosine Tri Phosphate (ATP) Adenine Ribose 3 Phosphate groups Who uses it?

  3. ADP and ATP Adenosine diphosphate (ADP) + Phosphate Adenosine triphosphate (ATP

  4. Photosynthesis Goal is to capture kinetic light energy and convert it to stored Potential energy in the form of GLUCOSE • Equation 6CO2 + 6H20  C6H12O6 + 6O2

  5. Electromagnetic Spectrum

  6. Light is a form of kinetic energy called Electromagnetic radiation • Travels in waves (and particles) • Different wavelengths give the energy different properties • Blue light has more energy than red light (its faster for a small wave to move than a long wave----think of jumping rope!)

  7. Plants and Light • Visible light = small part of electromagnetic spectrum • Sunlight is a mixture of all colors of light. Each color of light has a different wavelength, and thus a different amount of energy. • Plants only use visible wavelengths of light.

  8. Chloroplasts

  9. Parts of Chloroplast • Chloroplast: Site of photosynthesis in eukaryotic cells. • Thylakoids: Disk shaped membranes containing photosynthetic pigments. Site of light dependent reactions. • Grana: Stacks of thylakoids. • Stroma: Fluid filled space surrounding grana. Site of light independent reactions.

  10. PHOTOSYNTHESIS CO2 H20 Light Chloroplast NADP+ ADP + P Calvin Cycle Light- Dependent Reactions ATP NADPH C6H12O6 O2

  11. Light Dependent Reactions • All the reactions of photosynthesis that are directly dependent upon light are known as the light dependent reactions. • The light dependent reactions occur in the part of the cell known as the thylakoids (Stacks of thylakoids are known as grana.). • Many chlorophyll molecules are found embedded into the membranes of the thylakoids.

  12. The purpose of the light reactions is to convert light energy into chemical energy in the form of ATP & NADPH. • ATP & NADPH are energy carriers. • ATP carries energy • NADPH carries high energy electrons and hydrogen ions

  13. 2 Parts to Light Reactions • Photosystem II • Happens 1st • Part of light reactions that ultimately generates ATP molecules • Photosystem I • Happen 2nd • Part of light reactions that ultimately generate NADPH molelecules

  14. Calvin Cycle (aka Dark Reactions aka light independent reactions) • All reactions of photosynthesis not directly dependent upon light are known as the light independent reactions. They occur whether there is light present or not. • The light independent reactions occur in the part of the chloroplast known as the stroma. • The purpose of the light independent reactions is to take the energy from ATP and energized electrons and hydrogen ions from NADPH and add them to CO2 to make glucose or sugar.

  15. The purpose of the light independent reactions (Calvin cycles) is to take the energy from ATP and energized electrons and hydrogen ions from NADPH and add them to CO2 to make glucose or sugar.

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