There are no 2 specific reactants. Many reactants can 'produce' energy. Gasoline, methane, ethane, propane, butane, etc all burn with a variety of oxidizers (oxygen it self being only one of them) and release heat energy.
NADH and FADH 2 among other molecules. Where do these molecules come from
Correct. Anaerobic cellular respiration takes place in the cytoplasm and gives a net yield of 2 ATP molecules. Anaerobic respiration consists of glycolysis followed by either lactic acid fermentation or alcoholic fermentation.
Anaerobic cellular respiration generates a net gain of 2 ATP. Aerobic cellular respiration generates 36 to 38 ATP.
There are two oxygen atoms in the reactant for hydrogen peroxide. It depends on the reactant.
You can measure the energy content by analyzing the ATP produced during cellular respiration. If there is less ATP produced than the energy contained in the initial reactants, it indicates a loss of energy. The energy released during respiration comes from the breakdown of glucose molecules and is stored in the high-energy bonds of ATP molecules.
The two reactants of cellular respiration are glucose and oxygen. Glucose is broken down into smaller molecules to release energy, and oxygen is needed to help facilitate this process.
Glycolysis breaks down glucose to form the reactants of cellular respiration
NADH and FADH 2 among other molecules. Where do these molecules come from
Correct. Anaerobic cellular respiration takes place in the cytoplasm and gives a net yield of 2 ATP molecules. Anaerobic respiration consists of glycolysis followed by either lactic acid fermentation or alcoholic fermentation.
OK the reactants of cellular respiration is obviously C6H12O6 which is glucose and O2. The product of cellular respiration is fairly simple as well, carbon dioxide, water, and ATP. hope that answers your question.
Anaerobic cellular respiration generates a net gain of 2 ATP. Aerobic cellular respiration generates 36 to 38 ATP.
There are two oxygen atoms in the reactant for hydrogen peroxide. It depends on the reactant.
You can measure the energy content by analyzing the ATP produced during cellular respiration. If there is less ATP produced than the energy contained in the initial reactants, it indicates a loss of energy. The energy released during respiration comes from the breakdown of glucose molecules and is stored in the high-energy bonds of ATP molecules.
Starting with Glycolysis, 2 ATP are required to start. 4 ATP are produced by the end of Glycolysis, with a NET ATP of 2.
ATP is the energy-storage product of cellular respiration. Aerobic cellular respiration produces around 36 ATP molecules for every glucose molecule broken down. Anaerobic respiration results in a net gain of 2 ATP molecules.
lungs and heart
Cellular respiration has three main stages: 1. Glycolysis 2. The Citric Acid Cycle 3. Electron Transport Chain