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The amount of energy that is absorbed is the same as the amount of energy that is released.
When an excited electron is passed to an electron acceptor in a photosystem, energy in sunlight is transformed to chemical energy.
No, It is due to the fact that without energy an electron can not go to excited state.
It releases the same amount of energy that it absorbed when it was excited to a higher energy state.
if an electron gains enough energy it jumps to a higher energy level. when this happens the atom is in an "excited" state.
To get excited, it must absorb energy. To get back to its ground state, it releases energy.
The amount of energy that is absorbed is the same as the amount of energy that is released.
This electron is called excited.
An excited electron releases a photon as it returns to ground state.
To move an electron from the ground state to an excited state, it requires an input of energy. It should be equal to the energy difference between the two levels. This energy comes from collision with other molecules and atoms.
When an excited electron is passed to an electron acceptor in a photosystem, energy in sunlight is transformed to chemical energy.
The excited electron move up.
It depends on the amount of energy it absorbs. There isn't a single specific number.
No, It is due to the fact that without energy an electron can not go to excited state.
It releases the same amount of energy that it absorbed when it was excited to a higher energy state.
He said that electrons can become excited and begin to hop energy levels; when this happens an electron is in the excited state.
Depending on the energy (frequency) of the specific photon hitting the electron, one of three events happens: nothing, the electron is excited, or the electron leaves the atom. If the energy of the photon very high, the electron can absorb the energy and escape the nucleus' pull. This is called ionization. If the energy of the photon lines up with the energy spacing in the atoms energy levels, the electron will move to a higher energy state, becoming excited. The electron then returns to its original energy level, releasing the energy as light. If the energy of the photon does not fall into one of these categories, the electron does not interact with it. In terms of actually changing the electron, it only changes in energy, not any other property.