Question #0d46c
1 Answer
Explanation:
The first thing to mention here is that the coefficient added to the name of the energy subshell tells you the energy shell in which the subshell is located.
In other words, the coefficient tells you the energy level on which the electron is located inside the atom. This energy level corresponds to the principal quantum number,
In your case, you have the
#n = color(red)(1)#
Next, the letter added to the name of the subshell, which actually gives the identity of the subshell, corresponds to the angular momentum quantum number,
For a given value of
#l = {0, 1, 2, ..., n-1}#
In your case, you have
#n = color(red)(1) implies l= 0 #
This corresponds to the
Now, each subshell can hold a number of orbitals given by the number of values that the magnetic quantum number,
For a given subshell
#m_l = {-1, - (l-1), ..., -1, 0 ,1 ,..., (l-1), l}#
In this case, the
#l = 0 implies m_l = 0#
Finally, the spin quantum number,
#m_s = {+1/2, - 1/2}#
This means that you can put together two quantum number sets to describe an electron located in the
#n = color(red)(1), l =0, m_l = 0, m_s = +1/2# This electron is located in the first energy shell, in the
#1s# subshell, in the#1s# orbital, and has spin-up.
#n = color(red)(1), l =0, m_l = 0, m_s = -1/2# This electron is located in the first energy shell, in the
#1s# subshell, in the#1s# orbital, and has spin-down
