ajority of ATP production in aerobic cellular respiration occurs within the mitochondria during electron ort. In this phase of cellular respiration, NADH and FADH, are oxidized to become NAD* and FAD+. otons and electrons released during this oxidation are used to establish a chemiosmotic gradient in the nondrial intermembrane space. The potential established by this gradient is used to convert mechanical vinto the chemical energy needed to join an inorganic phosphate on to ADP, thus creating ATP. Mitochondrial DNA Matrix granule Lamela Inner boundary membrane Cristal membrane auiua i Ribosome Matri Cristae ATP synthase Intermembrane space Intracristal space Peripheral space Outer membrane Parins Mitochondrion structure byKelvin13 (CC BY-SA 30) Outer membrane

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The majority of ATP production in aerobic cellular respiration occurs within the mitochondria during electron transport. In this phase of cellular respiration, NADH and FADH, are oxidized to become NAD+ and FAD+. The protons and electrons released during this axidation are used to establisha chemiosmotic gradient in the mitochondrial intermembrane space. The potential established by this gradient is used to convert mechanical energy into the chemical energy needed to join an inorganic phosphate on to ADP, thus creating ATP. Mitochondrial DNA Lamela er membrane Inner boundary membrane - Cristal membrane Matrin- Cristae Matrix granule Ribosome ATP synthase Intermembrane space Intracristal space Peripheral space Outer membrane Parins Mitochondrion structure by Kelvin13 (CC BY-SA 3.0) Outer membrane Cyt e ATP Synthase NADH NAD+H ATP Citric ADP acid cycle Matrix Suecinate Fumee Inner membrane Intermembrane space Mitochondrial electron transport chain by Fvasconcello (CCO) a. Analyze why mitochondria have such a convoluted (intricately folded) shape to their inner membranes as it relates to the process of cellular respiration. b. Analyze how electron transport relates to the process of establishing a chemiosmotic gradient in the mitochondrial intermembrane space. c Describe how the chemiosmotic gradient is used to convert mechanical energy to chemical energy in order to form ATP. d. Choose another process that utilizes electron transport and the use of a chemiosmotic gradient to provide energy for phosphorylation. Then, describe why this process provides evidence for the evolution and common ancestry of all organisms.