The electron configuration of an element describes how electrons are distributed in its atomic orbitals. Electron configurations of atoms follow a standard notation in which all electron-containing atomic subshells (with the number of electrons they hold written in superscript) are placed in a sequence. For example, the electron configuration of sodium is 1s22s22p63s1.
However, the standard notation often yields lengthy electron configurations (especially for elements having a relatively large atomic number). In such cases, an abbreviated or condensed notation may be used instead of the standard notation. In the abbreviated notation, the sequence of completely filled subshells that correspond to the electronic configuration of a noble gas is replaced with the symbol of that noble gas in square brackets. Therefore, the abbreviated electron configuration of sodium is [Ne]3s1 (the electron configuration of neon is 1s22s22p6, which can be abbreviated to [He]2s22p6).
Electron Configurations are useful for:
This notation for the distribution of electrons in the atomic orbitals of atoms came into practice shortly after the Bohr model of the atom was presented by Ernest Rutherford and Niels Bohr in the year 1913.
Shells
The maximum number of electrons that can be accommodated in a shell is based on the principal quantum number (n). It is represented by the formula 2n2, where ‘n’ is the shell number. The shells, values of n, and the total number of electrons that can be accommodated are tabulated below.
Shell and ‘n’ value | Max. Electrons in the Electron Configuration |
K shell, n = 1 | 2*12 = 2 |
L shell, n = 2 | 2*22 = 8 |
M shell, n = 3 | 2*32 = 18 |
N shell, n = 4 | 2*42 = 32 |
Subshells
All the possible subshells for values of n up to 4 are tabulated below.
Principle Quantum Number Value | Value of Azimuthal Quantum Number | Resulting Subshell in the Electron Configuration |
n = 1 | l = 0 | 1s |
n = 2 | l = 0 | 2s |
l = 1 | 2p | |
n = 3 | l = 0 | 3s |
l = 1 | 3p | |
l = 2 | 3d | |
n = 4 | l = 0 | 4s |
l = 1 | 4p | |
l = 2 | 4d | |
l = 3 | 4f |
Thus, it can be understood that the 1p, 2d, and 3f orbitals do not exist because the value of the azimuthal quantum number is always less than that of the principal quantum number.
Notation
Aufbau Principle
The order in which electrons are filled in atomic orbitals as per the Aufbau principle is illustrated below.
It is important to note that there exist many exceptions to the Aufbau principle such as chromium and copper. These exceptions can sometimes be explained by the stability provided by half-filled or completely filled subshells.
Pauli Exclusion Principle
Hund’s Rule
An illustration detailing the manner in which electrons are filled in compliance with Hund’s rule of maximum multiplicity is provided above.
Examples
The electron configurations of a few elements are provided with illustrations in this subsection.
The atomic number of hydrogen is 1. Therefore, a hydrogen atom contains 1 electron, which will be placed in the s subshell of the first shell/orbit. The electron configuration of hydrogen is 1s1, as illustrated below.
Electron Configuration of Hydrogen
The atomic number of oxygen is 8, implying that an oxygen atom holds 8 electrons. Its electrons are filled in the following order:
Therefore, the electron configuration of oxygen is 1s2 2s2 2p4, as shown in the illustration provided below.
Electron Configuration of Oxygen
Chlorine has an atomic number of 17. Therefore, its 17 electrons are distributed in the following manner:
The electron configuration of chlorine is illustrated below. It can be written as 1s22s22p63s23p5 or as [Ne]3s23p5
Electron Configuration of Chlorine
The electronic configuration of an atom is the numerical representation of the arrangement of electrons distributed in the orbitals of the atom. This determines the position of an element in the periodic table and in turn its chemical behavior. It explains how the atoms are held together by the chemical bonds, and the peculiar trends which are observed in the rows and columns of the periodic table. In this article, we will discuss the electronic configuration of elements in the same periods and groups of the periodic table.
Electronic Configuration in Periods
Elements in the same group have the same number of electrons in their outermost shell leading to similar valence shell electronic configuration. Thus, we observe a similar trend in the properties and chemistry of the elements in the same group.
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1. What is an electron configuration? |
2. How does electron configuration vary across periods in the periodic table? |
3. How does electron configuration vary within groups in the periodic table? |
4. How can electron configuration be determined using the periodic table? |
5. What role does electron configuration play in determining the chemical properties of elements? |
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