1 glucose molecule = 38 ATP
The maximum number of ATP molecules that can be produced from each glucose molecule in aerobic respiration is 36-38 ATP molecules. This occurs through glycolysis, the citric acid cycle, and the electron transport chain.
The maximum number of ATP molecules that can be produced from a single glucose molecule during cellular respiration is 36-38 ATP. This includes ATP generated during glycolysis, the Krebs cycle, and oxidative phosphorylation in the mitochondria. The exact number can vary slightly depending on factors such as the efficiency of ATP production in the electron transport chain.
4-2=2 net gain ATPs. 4 are produced and 2 are consumed during the process.
In aerobic respiration, one glucose molecule typically produces 36-38 ATP molecules through glycolysis, the Krebs cycle, and the electron transport chain. In anaerobic respiration, such as fermentation, the number of ATP molecules produced is lower, around 2 ATP molecules.
For every molecule of pyruvate entering the Krebs cycle, 3 molecules of CO2 are released. Since each glucose molecule produces 2 molecules of pyruvate through glycolysis, the total number of CO2 molecules released per glucose molecule in the Krebs cycle is 6.
Glycolysis is the breakdown of glucose by enzymatic action. It yields 2 NADH molecules and 2 ATP molecules per glucose molecule.
During glycolysis, a net of 2 ATP molecules are produced per glucose molecule. However, it's important to note that 4 ATP molecules are produced during glycolysis, but 2 ATP molecules are consumed in the initial steps, resulting in a net gain of 2 ATP molecules.
The maximum number of ATP molecules that can be produced from each glucose molecule in aerobic respiration is 36-38 ATP molecules. This occurs through glycolysis, the citric acid cycle, and the electron transport chain.
The maximum number of ATP molecules that can be produced from a single glucose molecule during cellular respiration is 36-38 ATP. This includes ATP generated during glycolysis, the Krebs cycle, and oxidative phosphorylation in the mitochondria. The exact number can vary slightly depending on factors such as the efficiency of ATP production in the electron transport chain.
4-2=2 net gain ATPs. 4 are produced and 2 are consumed during the process.
The efficiency of glycolysis would remain the same regardless of the number of ATP molecules produced because efficiency is calculated based on the ratio of ATP molecules produced to glucose molecules consumed. Increasing the number of ATP molecules produced would not affect this ratio, therefore the efficiency would stay constant.
During glycolysis it makes a net amount of 2 molecules of ATP. Fermentation happens anaerobically (without oxygen) and the reduction of pyruvate into lactate itself does not yield any ATP. But I think the answer you are looking for is 2 ATP.
The cell can produce a net of 2 ATP molecules from a single molecule of glucose through glycolysis. This process involves breaking down glucose into pyruvate and generating ATP through substrate-level phosphorylation. Additionally, glycolysis also produces NADH which can contribute to the production of more ATP in the electron transport chain.
What is the smallest number of glucose molecules that can form a polysaccharide?
In aerobic respiration, one glucose molecule typically produces 36-38 ATP molecules through glycolysis, the Krebs cycle, and the electron transport chain. In anaerobic respiration, such as fermentation, the number of ATP molecules produced is lower, around 2 ATP molecules.
For every molecule of pyruvate entering the Krebs cycle, 3 molecules of CO2 are released. Since each glucose molecule produces 2 molecules of pyruvate through glycolysis, the total number of CO2 molecules released per glucose molecule in the Krebs cycle is 6.
2. (1)glucose --> (2)Carbon dioxide + (2) Ethanol + (2) ATP aerobic on the other hand produces 38 Atp per glucose molecule. (1) glucose + (6) oxygen---> (6) oxygen + (1) water + (38) atp