For fermium: 30 electrons.
For fermium: 30 electrons.
Fermium has seven electron shells.
Rubidium
Only two electrons.
The energy of the electron in a hydrogen atom in an excited state of 5s1 is higher than in the ground state. This is due to the electron being in a higher energy level, specifically the 5s orbital. The configuration of the electron in this excited state indicates that it is in the fifth energy level and occupies the s subshell.
The electron configurations provided represent the electron arrangement in the outermost energy level of the atoms. Atom A has a 3s1 electron configuration, indicating it is in the third energy level with one electron in the s orbital. Atom B, on the other hand, has a 5s1 electron configuration, indicating it is in the fifth energy level with one electron in the s orbital. Therefore, the main difference between atom A and atom B is the energy level in which their outermost electrons reside.
Yes, the energy of an electron does vary depending on which energy level it occupies.
The electron would be removed from the outermost energy level, which is the fourth energy level, for calcium.
The fifth electron shell, also known as the fifth energy level or n=5, can hold a maximum of 50 electrons. This is calculated using the formula 2n^2, where n is the principal quantum number.
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.
An alternative name for energy level is electron shell or electron orbital.
No, when an electron drops from a higher energy level to a lower energy level within an atom, the energy released in the form of a photon is given off by the electron itself, not taken from the environment. This process is known as emission.