36
In aerobic respiration, 36 or 38 molecules of ATP per molecule of glucose, depending on how many are gained through the electron transfer system.In anaerobic respiration 2 molecules of ATP per molecule of glucose, though higher yields can occur in higher temperatures (as much as 9 ATP molecules per molecule of glucose)
Cytochrome Oxidase are most likely to be found in mitochondria and important in cell respiration as an agent of electron transfer from certain cytochrome molecules to oxygen molecules
In the electron transport chain, the main product that is mass produced is adenosine triphosphate (ATP). ATP is a high-energy molecule that serves as the primary source of cellular energy. It is generated by the electron transport chain through a series of redox reactions involving the transfer of electrons from electron donors to electron acceptors, ultimately resulting in the production of ATP.
due to friction temperature increases and the valence electrons get enough energy to transfer from one body to the other. The body which loose electron get positive charge due to deficiency of electron and the body which gains electron become negatively charged due to excess of electrons.
The role of photosynthesis II is the generation of ATP along with splitting of the water molecules. The electron transfer, is another function of photosynthesis II.
Electron transport has the greatest number of ATP molecules.
In aerobic respiration, 36 or 38 molecules of ATP per molecule of glucose, depending on how many are gained through the electron transfer system.In anaerobic respiration 2 molecules of ATP per molecule of glucose, though higher yields can occur in higher temperatures (as much as 9 ATP molecules per molecule of glucose)
Yes. It is common to both kinds. Main goal is to produce ATP
Oxygen is the final electron acceptor in the electron transfer chain and therefore needs to be present in the Kreb's cycle. Without oxygen only anaerobic repiration will occur.
When the water is disturbed, its molecules starts moving fast but do not loose their mean position and transfer this disturbance to other molecules and the waves are produced following this disturbance.
They can accept electrons and transfer mos of their energy to another Molecule.
Do you mean ionic bond? An atom with one extra electron can transfer its electron to an atom that needs an electron so that both atoms will have a full outer shell (valence). Then the two atoms are held together in an ionic bond.
In aerobic respiration, one molecule of glucose yields 38 ATP molecules, eight produced during glycolysis, six from the link reaction and 24 from the Krebs cycle. The net gain is 36 ATP, as two of the ATP molecules produced from glycolysis are used up in the re-oxidation of the hydrogen carrier molecule NAD. Therefore; There are 38 ATP molecules produced but net gain is 36 ATP
Because, the link reaction and the Krebs cycle in respiration can only occur when there is oxygen present. When there is no oxygen available (i.e under anaerobic conditions), the electron transfer chain (etc) can not pass on its electron (as oxygen is the final electron acceptor in the etc). So, the electrons build up in the etc, therefore, electrons from the hydrogen from reduced NAD can no longer be accepted by the cytochromes in the etc. Because of this, no reduced NAD can be converted into oxidised NAD, and hence there is nothing to accept the hydrogens produced in the link reaction and Krebs cycle. Hence the etc and Krebs cycle grind to a halt. Glycloysis, however, can still occur in anaerobic conditions. However, as there is no NAD to accept the hydrogens produced in glycolysis ( due to the blocked etc), the pyruvate formed in glycolysis acts as a hydrogen acceptor. This forms lactic acid, which builds up in the the muscle tissue (and gives you 'stitch') Anaerobic respiration produces a fraction of the ATP that wound be synthesised in aerobic conditions (about 10% i think)
Sound means that some molecules transfer their vibrations to other molecules. So, because of this, obviously you need molecules to transfer sound.Sound means that some molecules transfer their vibrations to other molecules. So, because of this, obviously you need molecules to transfer sound.Sound means that some molecules transfer their vibrations to other molecules. So, because of this, obviously you need molecules to transfer sound.Sound means that some molecules transfer their vibrations to other molecules. So, because of this, obviously you need molecules to transfer sound.
Cytochrome Oxidase are most likely to be found in mitochondria and important in cell respiration as an agent of electron transfer from certain cytochrome molecules to oxygen molecules
The 2 pyruvate molecules created in Glycolysis are oxidised to form Acytl-CoA. This then enters the Citric Acid Cycle. After the Citric Acid Cycle comes the electron-transfer chain, which is where the majority of ATP are produced during respiration.