Describing Physical Properties of the Period 3 Elements
- Elements in the periodic table are arranged in order of increasing atomic number and placed in vertical columns (groups) and horizontal rows (periods)
- The elements across the periods show repeating patterns in chemical and physical properties
- This is called periodicity
Arrangement of elements in the periodic table 
Elements are arranged by increasing atomic number from left to right
Atomic radius
- The atomic radius is the distance between the nucleus and the outermost electron of an atom
- The atomic radius is measured by taking two atoms of the same element, measuring the distance between their nuclei and then halving this distance
- In metals, this is also called the metallic radius and in non-metals, the covalent radius
Atomic radius 
The atomic radius gives a measure of the size of atoms
Atomic radii of Period 3 elements table
| Period 3 element | Na | Mg | Al | Si | P | S | Cl | Ar |
| Atomic radius (nm) |
0.157 | 0.136 | 0.125 | 0.117 | 0.110 | 0.104 | 0.099 | - |
Graph of atomic radii across Period 3
There is a decrease in atomic radii of Period 3 elements across the period
- Across the period, the atomic radii decrease
- This is because the number of protons (the nuclear charge) and the number of electrons increases by one every time you go an element to the right
- The elements in a period all have the same number of shells (so the shielding effect is the same)
- This means that as you go across the period the nucleus attracts the electrons more strongly pulling them closer to the nucleus
- Because of this, the atomic radius (and thus the size of the atoms) decreases across the period
Explaining why atomic radius decreases across Period 3
The diagram shows that across Period 3, the elements gain extra electrons in the same principal quantum shell
Ionic radius
- The ionic radius is the distance between the nucleus and the outermost electron of an ion
- Metals produce positively charged ions (cations) whereas nonmetals produce negatively charged ions (anions)
- The cations have lost their valence electrons which causes them to be much smaller than their parent atoms
- This is because there are less electrons, which also means that there is less shielding of the outer electrons
- Going across the period from Na+ to Si4+ the ions get smaller due to the increasing nuclear charge attracting the outer electrons in the second principal quantum shell nucleus (which has an increasing atomic number)
- The anions are larger than their original parent atoms because each atom has gained one or more electrons in their third principal quantum shell
- This increases the repulsion between electrons, while the nuclear charge is still the same, causing the electron cloud to spread out
- Going across P3- to Cl-, the ionic radii decrease as the nuclear charge increases across the period and fewer electrons are gained by the atoms (P gains 3 electrons, S 2 electrons and Cl 1 electron)
Ionic radii of ions of Period 3 elements table
| Period 3 ion | Na+ | Mg2+ | Al3+ | Si4+ | P3– | S2– | Cl– | Ar |
| Ionic radius (nm) |
0.095 | 0.065 | 0.050 | 0.041 | 0.212 | 0.184 | 0.181 | No data |
Graph of ionic radii across Period 3 ions
Ions of Period 3 elements with increasing positive charge (metals) and increasing outer electrons across the period
Explaining why ionic radius changes across Period 3
The diagram shows the electron configuration of the ions of Period 3 elements and their relative sizes
Melting point
Melting points of the elements across Period 3 table
| Period 3 element | Na | Mg | Al | Si | P | S | Cl | Ar |
| Melting point (K) |
371 | 923 | 932 | 1683 | 317 | 392 | 172 | 84 |
Graph of melting points across Period 3
There is a general increase in melting point from Na to Si, followed by a sharp drop to the lower melting points of P to Ar
- A general increase in melting point for the Period 3 elements up to silicon is observed
- Silicon has the highest melting point
- After the Si element, the melting points of the elements decrease significantly
Electrical conductivity
- Electrical conductivity refers to how well a substance can conduct electricity
- Unlike the melting points, the electrical conductivity of the Period 3 elements shows a clear trend
- Going across the period, the electrical conductivity of the elements decreases significantly
- Initially there is an increase in the electrical conductivity from Na to Al and then this decreases across the remaining elements
Trends in electrical conductivity across Period 3 table
| Period 3 element | Na | Mg | Al | Si | P | S | Cl | Ar |
| Electrical conductivity (S m-1) |
0.218 | 0.224 | 0.382 | 2 x 10-10 | 10-17 | 10-23 | - | - |
