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A decrease in the formation of ATP
There will be a decrease in the formation of NADPH apex
there will be a decrease in the formation of NADPH A decrease in the formation of ATP
there will be a decrease in the formation of NADPH A decrease in the formation of ATP
there will be a decrease in the formation of NADPH.
A decrease in the formation of NADPH.
A decrease in the formation of ATP
A decrease in the formation of ATP
there will be a decrease in the formation of NADPH.
There will be a decrease in the formation of NADPH apex
there will be a decrease in the formation of NADPH A decrease in the formation of ATP
there will be a decrease in the formation of NADPH A decrease in the formation of ATP
there will be a decrease in the formation of NADPH.
Well, not enough gradient will be built up so hydrogen comes down it's concentration gradient through the synthase and synthesizes ATP. Also NADPH will be adversely affected.
Depends on the hydrogen gradient. If hydrogen is still flowing down it's concentration gradient through the ATP synthase then some ATP will be made, at least until equilibrium is reached.
Well, not enough gradient will be built up so hydrogen comes down it's concentration gradient through the synthase and synthesizes ATP. Also NADPH will be adversely affected.
Light energy is not exactly trapped. The light energy excites the electron in the reaction centres of photosystem I and photosystem II. The electron excites and transfers to the electron transport chain ( chain of electron carriers), this produces ATP. Then the electron of photosystem II is transferred by photosystem I and the electron of the photosystem I is used with H+ and NADP to form NADPH. Photosystem II gets back an electron from photolysis of water.