More than ten times as much can be generated.
Fermentation yields a net gain of 2 ATP molecules synthesized per glucose molecule broken down.
Within the mitochondria, pyruvate is broken down aerobically to give a yield that, in theory, could reach 36 ATP molecules, but in practice is probably only about 30. The amount varies, as some of the energy released may go into other processes than ATP synthesis.
Respiration produces 38 ATP.
Fermentation produces 2 ATP
Aerobic respiration.
It produces 34 more ATP.
AEROBIC RESPIRATION-38 ATP per molecule
FERMENTATION-2 ATP per molecule
total 40-4=36 ATP
net 38-2=36 ATP
yes, it does
Both start with glycolysis, which is an anaerobic process that produces a net gain of 2 ATP. Glycolysis can be followed by fermentation or aerobic respiration, depending on the organism and available oxygen for aerobic respiration. If glycolysis is followed by fermentation, no more ATP will be produced, so glycolysis and fermentation produce only 2 ATP for every glucose molecule. However, if aerobic respiration occurs, around 34 to 36 more molecules of ATP can be produced from every glucose molecule. So, aerobic respiration is much more efficient at producing ATP.
Anaerobic respiration takes place in the Cytoplasma.
36-38 for aerobic respiration 2 in fermentation sooo.. yes
Glycolysis itself anaerobic process and forms pyruvate. If there is oxygen present, pyruvate is reduced to acetyl-coenzyme A; if there is no oxygen present, pyruvate goes through fermentation, forming either lactic acid or ethanol.
yes
Both start with glycolysis, which is an anaerobic process that produces a net gain of 2 ATP. Glycolysis can be followed by fermentation or aerobic respiration, depending on the organism and available oxygen for aerobic respiration. If glycolysis is followed by fermentation, no more ATP will be produced, so glycolysis and fermentation produce only 2 ATP for every glucose molecule. However, if aerobic respiration occurs, around 34 to 36 more molecules of ATP can be produced from every glucose molecule. So, aerobic respiration is much more efficient at producing ATP.
aerobic respiration give more energy than anaerobic respiration.
Anaerobic respiration only glycolysis occurs which forms 2ATP. However, in aerobic respiration there is the Krebs cycle which is responsible for making 2 ATP and the electron transport chain which is responsible for making 30 ATP. Most textbooks say that for aerobic respiration around 36-38 ATP is made. When compared to the 2 from anaerobic it is a major difference in energy production.
Cells produce more ATP under aerobic conditions because aerobic means that you need air and ATP needs air to operate so i made sence that cells would make more ATP under aerobic conditions.
36 atp is produced in areobic respiration and a net gain of 2 in glycolisis so 38 in total
Anaerobic respiration takes place in the Cytoplasma.
36-38 for aerobic respiration 2 in fermentation sooo.. yes
Glycolysis itself anaerobic process and forms pyruvate. If there is oxygen present, pyruvate is reduced to acetyl-coenzyme A; if there is no oxygen present, pyruvate goes through fermentation, forming either lactic acid or ethanol.
yes
There are anaerobic and aerobic types of cellular respiration. Anaerobic (including glycolysis) respiration does not involve oxygen. Aerobic (including the Kreb's, or citric acid, cycle and oxidative phosphorylation) respiration requires oxygen, and generates much more energy than anaerobic respiration.
Cellular RespirationSource: Holt Biology by Johnson Raven* Aerobic cellular respiration. Anaerobic cellular respiration yields a net gain of 2 ATP molecules for each glucose molecule broken down. Aerobic respiration yields a variable number, but always more than ten times as many ATP molecules.
Anaerobic respiration involves only glycolysis, which has a net gain of 2 ATP. In aerobic respiration, the Krebs Cycle and electron transport occur after glycolysis, producing a net gain of 36 ATP. Most of the 36 ATP molecules are produced during electron transport, which does not occur in glycolysis.