Yes, glycolysis, citric acid cycle, and electron transport chain each release certain amount of ATP.
aerobic(36 ATP)
2, 2, and 32
Glycolysis: 2 ATP per molecule of glucose Total ATP yield of aerobic respiration (including glycolysis): 36 ATP per molecule of glucose (theoretical, less in reality due to leaking of protons across the mitochondrial inner membrane)
About 36 ATP for aerobic cellular respiration.
Via the enzyme 'pyruvate kinase' , phosphoenolpyruvate is combined with Adp and Pi to {100%} YIELD pyruvate [pyruvic acid] and Atp. Starting from Glucose, there are at least six separate [because each step "has" its own Enzyme to THOROUGHLY control the yield of the reaction] steps that precede the above.
aerobic(36 ATP)
36 ATP for eukaryotes and 38 ATP for prokaryotes
2, 2, and 32
Cellular respiration- prokaryotic cells can yield a max of 38 ATP & eukaryotic cells can yield a max of 36.
Glycolysis: 2 ATP per molecule of glucose Total ATP yield of aerobic respiration (including glycolysis): 36 ATP per molecule of glucose (theoretical, less in reality due to leaking of protons across the mitochondrial inner membrane)
Aerobic respiration
About 36 ATP for aerobic cellular respiration.
With adequate oxygen, cellular respiration will produce 30-32 ATP (actual yield) OR 36-38 ATP (theoretical yield) per glucose molecule.
Via the enzyme 'pyruvate kinase' , phosphoenolpyruvate is combined with Adp and Pi to {100%} YIELD pyruvate [pyruvic acid] and Atp. Starting from Glucose, there are at least six separate [because each step "has" its own Enzyme to THOROUGHLY control the yield of the reaction] steps that precede the above.
32
In glycolysis of cellular respiration, NADH produces 2ATP because one ATP is used to transport a molecule of NADH into the mitochondria and continue with aerobic respiration. However, in pyruvate decarboxylation and the Krebs cycle, each NADH yields 3ATPs. FADH2 yields 2 ATPs.
In what? I'll make an assumption that you're talking about the coenzyme, and about respiration, then 10 NADH2 molecules are made, each yielding 3 ATP molecules this plus the two FAD's making two ATP each, and glycolysis and the Krebs cycle producing two each, we see a net yield of 38 ATP, theoretically.