They are not absorbing protons. They absorb only electrons.
If it were possible to add a proton to atoms, then the germanium would turn into arsenic.
Plants that are unlucky enough to loose all of their chlorophyll will not be able to produce glucose through photosynthesis and will die. This is happens if the entire plant looses chlorophyll; there are other examples of plants (such as white variegated ones) where only certain portions of the leaf have no chlorophyll, in these instances the food is produced and distributed from the areas that do contain chlorophyll to those which don't.
When the energy from the sun is trapped by chlorophyll, it excites electrons within the chlorophyll molecules. These excited electrons are then used to fuel the process of photosynthesis, where carbon dioxide and water are converted into glucose and oxygen.
nothing, they both even out!
i turns into the element on the left of it on the periodic table
Light reaction is not produced by chlorophyll .
They convert in to two photons
The chloroplast contains chlorophyll and is located in the cytoplasm. Photosynthesis happens because of the chloroplast and the chlorophyll captures the energy from the sunlight.
I don know
If it were possible to add a proton to atoms, then the germanium would turn into arsenic.
Plants that are unlucky enough to loose all of their chlorophyll will not be able to produce glucose through photosynthesis and will die. This is happens if the entire plant looses chlorophyll; there are other examples of plants (such as white variegated ones) where only certain portions of the leaf have no chlorophyll, in these instances the food is produced and distributed from the areas that do contain chlorophyll to those which don't.
They head out of the sun at nearly the speed of light
When the energy from the sun is trapped by chlorophyll, it excites electrons within the chlorophyll molecules. These excited electrons are then used to fuel the process of photosynthesis, where carbon dioxide and water are converted into glucose and oxygen.
It becomes excited.
As the moving proton gets closer to the stationary proton, the electric force between them increases. This causes the moving proton to slow down and eventually come to a stop as the electrostatic force of repulsion between them balances the initial kinetic energy of the moving proton.
They form a hydrogen atom.
If chlorophyll a is blocked, chlorophyll b can still function in photosynthesis to capture light energy and transfer it to chlorophyll a. However, chlorophyll b cannot directly pass electrons to the photosynthetic electron transport chain without chlorophyll a, so the overall photosynthetic process may be impaired.