ch9sec1n2_2013

... make ATP. As H+ ions escape through ion channels ATP SYNTHASE back into the matrix, ________________ spins and adds a phosphate to ADP to ATP form _______ ...

l] energy

... A larger molecule splits into smaller ones. ...

Photosynthesis inter..

... Photosynthesis occurs in two biochemical pathways:  Light reactions - harvest photon energy to synthesize ATP & NADPH. Splits H20  Calvin cycle reactions - use ATP and NADPH from light reactions to reduce (add hydrogen/electrons) to CO2 forming carbohydrates. ...

Cellular respiration - how cells make energy

... - several proteins are embedded in the inside membrane of mitochondria [OVERHEAD, fig. 6.10, p. 98 / 4th: 6.12, p. 100] - these proteins function in the electron transport chain. - electrons are passed down through these proteins - as NADH contributes it's electrons, H+ ions are moved to the outside ...

MYP Chemistry: Final Review

... What is the difference between a bright line spectrum and a continuous spectrum? Continuous spectrum contains all wavelengths (ROYGBV) like a rainbow. Bright line spectrum shows discrete wavelengths like red or blue or green, but not all the colors ...

Review Guide

... a. What is their charge? b. What is their symbol? c. Where in the atom are they located? 2. What does the atomic number on the periodic table tell us? 3. How is the mass number found? What does it tell us? 4. Define and give one example of each: a. Atom (definition only) c. Molecule b. Element d. Co ...

Are You suprised ?

... 1. If you isolate mitochondria and place them in buffer with a low pH they begin to manufacture ATP. Why? A. Low pH increases the OH- concentration in the matrix resulting in ATP production by ATP synthase. B. Low pH increases the acid concentration in the mitochondrial matrix, a condition that norm ...

Sample Question Set 5a

... i. cytochrome c -> cytochrome c oxidase -> NADH dehydrogenase -> ubiquinone ii. cytochrome c oxidase -> cytochrome c -> NADH dehydrogenase -> ubiquinone iii. NADH dehydrogenase -> ubiquinone -> cytochrome c -> cytochrome c oxidase iv. NADH dehydrogenase –> cytochrome c -> ubiquinone -> cytochrome c ...

Chapter 18 Review 18.1 Oxidation-Reduction Reactions Oxidation

... Corrosion- process of returning metals to their natural state Cathodic Protection- the connection of an active metal to another to prevent corrosion - corrosion involves the oxidation of metals - this process creates great economic lose - most metals produce a thin oxide coating, which protect their ...

complex I

... the largest of the respiratory enzyme complexes, containing more than 40 polypeptide chains. It accepts electrons from NADH and passes them through a flavin and at least seven iron-sulfur centers to ubiquinone. Ubiquinone then transfers its electrons to a second respiratory enzyme complex, the cytoc ...

MITOCHONDRIA

... Oval shaped organelles with a double-membrane; randomly scattered around the cytoplasm. The folded inner membrane is known as cristae.  Many proteins and other molecules are embedded in it to help with the process of cellular respiration. The matrix is the protein rich fluid inside the cristae. The ...

Document

... Mitochondria and O2 needed Uses NADH and FADH produced in previous reactions To make more ATP Lots more!! ...

Respiration - College Heights Secondary

... C. Inputs and Outputs 1. Inputs a. pyruvate b. NAD+ and FAD+ c. ADP d. O2 ...

cellular respiration - Aurora City Schools

... the gain of oxygen) and reduction (the gaining of an electron, or hydrogen or losing oxygen by an element) ...

Photosynthesis Chapter 10

... Mr. Knowles ...

Light reactions

... They’re masked by chlorophyll, which is present in great quantities. Why are the other pigments there? They absorb light at different wavelengths than chlorophyll. ...

Lecture, Photosynthesis

...  builds the gradient  drives the flow of protons ADP + Pi through ATP synthase  bonds Pi to ADP ATP  generates the ATP AP Biology … that evolution built ...

CELL ENERGY

... Photosynthetic cells may contain hundreds of chloroplasts. Other pigments like Carotenoids (orange) Anthocyanins (redish) Xanthophylls (yellow) can absorb light that chlorophyll can’t. ...

Understanding Photosynthesis and Cellular Respiration

... when oxygen is not available or when the body is using oxygen faster than it can be supplied. Fermentation is an anarerobic process. ...

Cellular Respiration

... NADH & FADH2 provide electron for ATP and NADPH creation energy for ETC and the H+ that Stage 2: Light independent builds up in the mitochondrial membrane to create gradient for 32 Energy molecules ATP and NADPH ATP production. O2 is used as are used to convert CO2 into electron acceptor and forms H ...

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... 9. The prefix photo- means “light,” and synthesis means “to put together.” How do those ...

2401_Ch2.pdf

... proceed from reactants to products or from products back to reactants When the rate of forward to reverse direction reaction is equal the reaction is said to be in equilibrium For a reaction in equilibrium the ratio of reactants to products remains constant ...

Cellular Respiration

... transport chains are built into the inner membranes of mitochondria ...

key - Greenslime.info

... The elements in group 17, including fluorine, bromine, chlorine and iodine, are called the halogens. Describe the reactivity of the halogens, and why they have this reactivity. The halogens are very reactive, because they each have seven valence electrons, and only need to gain one valence electron ...

10 - Energy Carriers

... In photosynthesis plants catch sunlight energy. Some areas of the leaf don't get light, so the plants must move the energy. They store energy in a type of molecule that acts like a battery. The main energy carrier is called ATP Adenosine TriPhosphate To make ATP we add 1 Phosphate to ADP (Adenosin ...

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Light-dependent reactions

In photosynthesis, the light-dependent reactions take place on the thylakoid membranes. The inside of the thylakoid membrane is called the lumen, and outside the thylakoid membrane is the stroma, where the light-independent reactions take place. The thylakoid membrane contains some integral membrane protein complexes that catalyze the light reactions. There are four major protein complexes in the thylakoid membrane: Photosystem II (PSII), Cytochrome b6f complex, Photosystem I (PSI), and ATP synthase. These four complexes work together to ultimately create the products ATP and NADPH.[.The two photosystems absorb light energy through pigments - primarily the chlorophylls, which are responsible for the green color of leaves. The light-dependent reactions begin in photosystem II. When a chlorophyll a molecule within the reaction center of PSII absorbs a photon, an electron in this molecule attains a higher energy level. Because this state of an electron is very unstable, the electron is transferred from one to another molecule creating a chain of redox reactions, called an electron transport chain (ETC). The electron flow goes from PSII to cytochrome b6f to PSI. In PSI, the electron gets the energy from another photon. The final electron acceptor is NADP. In oxygenic photosynthesis, the first electron donor is water, creating oxygen as a waste product. In anoxygenic photosynthesis various electron donors are used.Cytochrome b6f and ATP synthase work together to create ATP. This process is called photophosphorylation, which occurs in two different ways. In non-cyclic photophosphorylation, cytochrome b6f uses the energy of electrons from PSII to pump protons from the stroma to the lumen. The proton gradient across the thylakoid membrane creates a proton-motive force, used by ATP synthase to form ATP. In cyclic photophosphorylation, cytochrome b6f uses the energy of electrons from not only PSII but also PSI to create more ATP and to stop the production of NADPH. Cyclic phosphorylation is important to create ATP and maintain NADPH in the right proportion for the light-independent reactions.The net-reaction of all light-dependent reactions in oxygenic photosynthesis is:2H2O + 2NADP+ + 3ADP + 3Pi → O2 + 2NADPH + 3ATPThe two photosystems are protein complexes that absorb photons and are able to use this energy to create an electron transport chain. Photosystem I and II are very similar in structure and function. They use special proteins, called light-harvesting complexes, to absorb the photons with very high effectiveness. If a special pigment molecule in a photosynthetic reaction center absorbs a photon, an electron in this pigment attains the excited state and then is transferred to another molecule in the reaction center. This reaction, called photoinduced charge separation, is the start of the electron flow and is unique because it transforms light energy into chemical forms.

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Light-dependent reactions