It ends up in the chlorophyll. Also, the electron flow produces ATP and NADPH.
Cycle photophosphorylation occurs in cyclic electron flow, where electrons are recycled to produce ATP but not NADPH. Noncyclic photophosphorylation involves both photosystems I and II to produce both ATP and NADPH using electrons extracted from water.
You can slow down electron flow by increasing resistance in the circuit, using resistors for example. By increasing the obstruction to electron flow, you reduce the rate at which electrons can move through the circuit. Additionally, lowering the voltage in the circuit will also slow down electron flow.
If a compass is suspended next to a conductor that is not carrying an electron flow, there will be no effect on the compass. The flow of electrons is what creates a magnetic field, so without electron flow in the conductor, there will be no interaction with the compass needle.
To slow down electron flow, you can increase the resistance in the circuit by adding resistors or using materials that hinder electron movement. Another way is to reduce the voltage across the circuit, which in turn reduces the push on the electrons, slowing down their flow. Additionally, increasing the length of the conductor can also impede electron flow.
Electrical energy results in a flow of electrons. This flow of electrons is what powers electronic devices and electrical systems.
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as soon as the sun hits them they get all hiper and crazy.
The products of non-cyclic electron flow in photosynthesis are ATP (adenosine triphosphate) and NADPH (nicotinamide adenine dinucleotide phosphate). This process occurs during the light-dependent reactions of photosynthesis and helps to generate energy-rich molecules that are used in the Calvin cycle to produce glucose.
in non-cyclic the electrons do not return the source and the cyclic the electrons come back to the source. Mostly the non-cyclic process occurs to produce ATP AND NADH which will be used by the Calvin cycle to produce the carbohydrate but some times there occurs a cyclic process to produce ATP to cope up with Calvin cycle as it requires more ATP than the NADH In addition to the above, cyclic electron flow could operate independent of photosystem II. The production of oxygen and NADPH take place in non-cyclic electron flow and the system could switch to cyclic flow upon accumulation of oxygen and NADPH
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In dim light, the number of photons reaching the solar panel is lower, which results in a lower generation of electron-hole pairs and therefore less current being produced. Bright light provides more photons, resulting in a higher generation of electron-hole pairs and a stronger current flow.
Electrons are in random motion in a material, such that there is no resultant electron movement. Hence a material has no current flow by its own. Only the directed flow of this charge in a direction, will results in current. when we provide sufficient energy (for example by mean of applied potential difference ) the net motion of the electron gives rise to the current flow.
ATP produced by noncyclic flow electrons in thylakoid membrane.
Cycle photophosphorylation occurs in cyclic electron flow, where electrons are recycled to produce ATP but not NADPH. Noncyclic photophosphorylation involves both photosystems I and II to produce both ATP and NADPH using electrons extracted from water.