The Krebs cycle, also known as the citric acid cycle, produces the most NADH.
The electron transport chain produces the most ATP during cellular respiration. It is the final stage of aerobic respiration and occurs in the inner mitochondrial membrane. Here, electrons are passed down a series of protein complexes, generating a proton gradient that drives ATP synthesis.
The Electron Transport process is the third process in cell respiration, it requires oxygen directly. The electron transport "chain" is a series of electron carriers in the membrane of the mitochondria. Through a series of reactions, the "high energy" electrons are passed to oxygen. In the process, a gradient is formed, and ultimately ATP (Adinosine triphosphate), an energy molecule is formed.Therefore this stage produces the most ATP.
Cellular respiration isn't the same thing as regular human respiration (most of us use the words "breathing" and "respiration" interchangeably, even though biologists use the term "respiration" to mean something a little different). Cellular respiration is when living cells convert fuel - either oxygen or sunlight- into energy that they can use. For example, cellular respiration in humans is the process by which oxygen used to power the synthesis of ATP (ATP is a high-energy molecule that our cells depend on to survive). Plants use a similar process to convert the energy of the sun into building blocks they can use.
The chemical process most living things use oxygen for is called cellular respiration. During cellular respiration, cells break down glucose in the presence of oxygen to produce energy in the form of adenosine triphosphate (ATP), which is essential for various cellular functions. CO2 and H2O are byproducts of this process.
Most are created by the mitochondria through cellular respiration, but some amounts of ATP are also created by the cytoplasm via glycolysis.
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.
Cellular Respiration produces the most ATP, out of Cellular respiration, Photosynthesis, lactic acid Fermentation, and alcohol fermentation.
Electron transport chain Monkey was here @(^o^)@
cellular respiration
The citric acid cycle (also known as the Krebs cycle) produces the most NADH, generating 3 NADH molecules per cycle. The least ATP is produced in the electron transport chain, where each NADH molecule can produce up to 3 ATP through oxidative phosphorylation.
In the Krebs cycle, 10 NADH molecules are generated here :-)
No, aerobic cellular respiration produces more energy than anaerobic respiration. Anaerobic respiration (like fermentation) produces just 2 ATP molecules per glucose molecule, while aerobic respiration produces up to 36-38 ATP molecules per glucose molecule.
In most cases iron shift between ferrous and ferric states to carry and transport electrons in cellular respiration. The cytochrome b and c complexes also play a major role. In aerobic organisms, oxygen is the final electron acceptor in cellular respiration.
Electron Transport Chain. It produces 32 while the citric acid cycle (your teacher might call it the Krebs Cycle) produces 2 and glycolysis produces 2 (all those numbers are per ONE GLUCOSE MOLECULE) Electron Transport Chain. It produces 32 while the citric acid cycle (your teacher might call it the Krebs Cycle) produces 2 and glycolysis produces 2 (all those numbers are per ONE GLUCOSE MOLECULE)
The most important stage of cellular respiration is the electron transport chain, where the majority of ATP is produced. This stage relies on the transfer of electrons from NADH and FADH2 to generate a proton gradient across the inner mitochondrial membrane, driving ATP synthase to produce ATP.
The electron transport chain in the mitochondria produces the most ATP in cellular respiration. This is where the majority of ATP is generated through oxidative phosphorylation by harvesting the energy from electrons transferred along the chain.
The electron transport chain during aerobic respiration produces the most ATP, generating up to 34 molecules of ATP per molecule of glucose. This process occurs in the inner mitochondrial membrane and involves a series of redox reactions that drive ATP synthesis.