A quanta of light (one photon).
excitation
The absorption spectrum of an atom shows that the atom emits that spectrum which it absorbs.
When you move an electron in an atom from a lower energy level to a higher energy level, it is called an electron excitation. This process requires the electron to absorb energy to move to a higher energy state.
This process is called excitation, where electrons absorb energy and move to higher energy levels within an atom.
absorbs energy through processes such as absorption of light or collision with other particles, causing its electrons to move to higher energy levels. This excitation is temporary, and the atom will eventually release the excess energy in the form of light or heat as the electrons return to their original energy levels.
An electron changes energy levels within an atom when it absorbs or emits a specific amount of energy, typically in the form of light or heat. This process is known as electron excitation or de-excitation.
Proton emission is a type of radioactive decay where an atom emits a proton with a mass number of 0 and a charge of plus 1. An example of a radioisotope that undergoes proton emission is iodine-123.
excitation
excitation
The absorption spectrum of an atom shows that the atom emits that spectrum which it absorbs.
16O
When you move an electron in an atom from a lower energy level to a higher energy level, it is called an electron excitation. This process requires the electron to absorb energy to move to a higher energy state.
This process is called excitation, where electrons absorb energy and move to higher energy levels within an atom.
No, it's called "radioactive." "Retroactive" is something that's active in regards to the past.
This is a radioactive isotope.
Oxidation is a chemial reaction; the atom and the number of neutrons remains unchanged.
absorbs energy through processes such as absorption of light or collision with other particles, causing its electrons to move to higher energy levels. This excitation is temporary, and the atom will eventually release the excess energy in the form of light or heat as the electrons return to their original energy levels.