Aerobic respiration uses oxygen as the final electron acceptor in the electron transport chain, allowing for the complete oxidation of glucose and the production of ATP. In contrast, anaerobic respiration does not utilize oxygen, relying instead on other molecules, such as nitrate or sulfate, as electron acceptors. This fundamental difference leads to lower energy yields in anaerobic respiration compared to aerobic respiration.
At the end of a aerobic respiration carbon is the molecule that makes hydrogen ions. This is taught in science.
in the mitochondria
The equation for aerobic cellular respiration is as follows: C6H12O6 + 6O2 --> 6H2O + 6CO2 + 32-36ATP
In Cellular Respiration, there are two ways of making ATP: Aerobic and Anaerobic. These processes occur in the Mitochondria. The first step of Aerobic Respiration is anaerobic (Yes, it's a bit confusing). This step is called Glycolysis, the process of turning Glucose into Pyruvate Acids, NADP, and ADP. From here is where Aerobic Respiration occurs if there is oxygen present. It goes on into Citric Acid Cycle, where it adds Hydrogen ions to the NADP, FAD, and ADP to make high-energy molecules. Next is the Electron Transport Chain, where the rest of the ATP is made. In all, around 36 ATP is made.
Aerobic reactions are more efficient for cellular metabolism because they fully oxidize glucose in the presence of oxygen, yielding a higher energy output of approximately 36-38 ATP molecules per glucose molecule. In contrast, anaerobic reactions, such as fermentation, only partially break down glucose, producing only about 2 ATP molecules per glucose. The complete oxidation in aerobic respiration also results in the production of water and carbon dioxide, while anaerobic processes can lead to the accumulation of byproducts like lactic acid or ethanol, which can be detrimental to cells. Thus, aerobic metabolism provides more energy and is more sustainable for long-term cellular function.
At the end of a aerobic respiration carbon is the molecule that makes hydrogen ions. This is taught in science.
2 ATP molecules are produced in anaerobic respiration (where there is no oxygen), while in aerobic (where there is oxygen) respiration, 36 ATP molecules are produced.
in the mitochondria
The Electron Transport Chain.
yes.
The equation for aerobic cellular respiration is as follows: C6H12O6 + 6O2 --> 6H2O + 6CO2 + 32-36ATP
The equation for aerobic cellular respiration is as follows: C6H12O6 + 6O2 --> 6H2O + 6CO2 + 32-36ATP
THROUGH THE BREATHING OF YOUR LUNGS BECAUSE BREATHING IS VERY IMPORTANT ESPECIALLY WHEN YOU HAVE A DISEASE
In Cellular Respiration, there are two ways of making ATP: Aerobic and Anaerobic. These processes occur in the Mitochondria. The first step of Aerobic Respiration is anaerobic (Yes, it's a bit confusing). This step is called Glycolysis, the process of turning Glucose into Pyruvate Acids, NADP, and ADP. From here is where Aerobic Respiration occurs if there is oxygen present. It goes on into Citric Acid Cycle, where it adds Hydrogen ions to the NADP, FAD, and ADP to make high-energy molecules. Next is the Electron Transport Chain, where the rest of the ATP is made. In all, around 36 ATP is made.
Cells use a process called cellular respiration to convert oxygen and food molecules into energy. This involves breaking down glucose into energy in the presence of oxygen, releasing carbon dioxide and water as byproducts. The energy produced is stored in the form of ATP (adenosine triphosphate) for the cell to use.
creatine phosphate, anerobic cellular respiration, and areobic cellular respiration all produce ATP.
Aerobic reactions are more efficient for cellular metabolism because they fully oxidize glucose in the presence of oxygen, yielding a higher energy output of approximately 36-38 ATP molecules per glucose molecule. In contrast, anaerobic reactions, such as fermentation, only partially break down glucose, producing only about 2 ATP molecules per glucose. The complete oxidation in aerobic respiration also results in the production of water and carbon dioxide, while anaerobic processes can lead to the accumulation of byproducts like lactic acid or ethanol, which can be detrimental to cells. Thus, aerobic metabolism provides more energy and is more sustainable for long-term cellular function.