Oxygen
Because the electron carrier molecules, such as the cytochromes, are located in the cristae.
NO molecule has 15 (odd) electrons, 8 from oxygen and 7 from nitrogen.
NADPH and ATP are produced by the light reactions. The ATP is a high energy molecule produced by photophosphorylation while the NADPH is produced at the end of the electron transport chain.
its a carbohydrate
An ion is an atom or molecule which has either gained an electron or lost one so that it is no longer neutral.
NADH and FADH2
The electron carrier molecules of the Krebs cycle are NADH and FADH2. In the Calvin cycle, the electron carrier molecule is NADPH.
NADP
Because the electron carrier molecules, such as the cytochromes, are located in the cristae.
The donor is the one who loses the electron. Donor is the elctron carrier.
The molecule you are referring to is NAD+ (nicotinamide adenine dinucleotide). It acts as a coenzyme electron carrier in the Krebs cycle by accepting and donating electrons during the oxidation-reduction reactions that occur in the cycle.
An electron carrier acts as an energy-storage molecule when it is in a reduced state by gaining electrons and storing energy in chemical bonds. Examples of electron carriers involved in energy storage include NADH and FADH2, which are critical molecules in cellular respiration for ATP production.
NO molecule has 15 (odd) electrons, 8 from oxygen and 7 from nitrogen.
No, ATP is not considered an electron carrier. ATP is the primary energy-carrying molecule in cells, storing and transferring energy for cellular processes. Electron carriers like NADH and FADH2 are involved in the transport of electrons during cellular respiration.
No, FADH2 is in the "accepted" state. FADH+ is the form of the molecule that is able to accept electrons.
No. "Diatomic electron" doesn't make any sense.Oxygen is a diatomic molecule, if that's what you meant.
NADPH and ATP are produced by the light reactions. The ATP is a high energy molecule produced by photophosphorylation while the NADPH is produced at the end of the electron transport chain.