NADH. In oxidative phosphorylation, for every NADH, around 2.5 ATP molecules are made, and for every FADH2 about 1.5 ATP molecules are made.
At the stage of Redox in the Electron transport chain: All of the below are produced 2 ATP from substrate-level phosphorylation 6 NADH yields 18 ATP (assuming 3 ATP per NADH) by oxidative phosphorylation 2 FADH2 yields 4 ATP (assuming 2 ATP per FADH2) by oxidative phosphorylation As you can see from above, NADH is the molecule that conserves most energy.
fermentation??
Fadh2 ..2 Nadh...3
Glycolosis uses two ATP to release the energy, creating four ATP.
carbohydrate
NADH. In oxidative phosphorylation, for every NADH, around 2.5 ATP molecules are made, and for every FADH2 about 1.5 ATP molecules are made.
FADH yields 2 ATP .
It is a highly complex macromolecule if that is what you mean.
Only two ATP is yield of Krebs cycle .
At the stage of Redox in the Electron transport chain: All of the below are produced 2 ATP from substrate-level phosphorylation 6 NADH yields 18 ATP (assuming 3 ATP per NADH) by oxidative phosphorylation 2 FADH2 yields 4 ATP (assuming 2 ATP per FADH2) by oxidative phosphorylation As you can see from above, NADH is the molecule that conserves most energy.
fermentation??
Fadh2 ..2 Nadh...3
Yes. Anaerobic respiration yields a net gain of 2 ATP per molecule of glucose, while aerobic respiration yields 36 -38 ATP per molecule of glucose.
36 molecules by oxydative phosphorylation.
Glycolosis uses two ATP to release the energy, creating four ATP.
Adenosine triphosphate, better known as ATP.