Physical Properties of the Period 3 Elements (Cambridge (CIE) AS Chemistry): Revision Note

Exam code: 9701

Author

Caroline Carroll

Last updated

23 June 2025

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

Periodic table of elements with categories: metals, non-metals, liquids, metalloids. Colour-coded key differentiates element types and states at room temperature. — **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

Two blue overlapping circles with centres marked by dots and a labelled radius "r" between them, illustrating geometric concepts. — **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

Bar chart showing atomic radius of elements: Na, Mg, Al, Si, P, S, Cl, Ar. Heights decrease from Na (0.16 nm) to Ar (0.06 nm). — **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

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 P^3- 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⁺	P^3–	S^2–	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

Bar chart comparing ionic radii of Na⁺, Mg²⁺, Al³⁺, Si⁴⁺, P³⁻, S²⁻, Cl⁻, and Ar in nanometres, showing P³⁻ as the largest and Si⁴⁺ as the smallest. — **Ions of Period 3 elements with increasing positive charge (metals) and increasing outer electrons across the period**

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

Bar chart showing melting points in Kelvin for elements: Na, Mg, Al, Si, P, S, Cl, Ar. Silicon has the highest, while argon has the lowest. — **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	-	-

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Previous:Types of CatalystNext:Structure & Bonding of the Period 3 Elements

Physical Properties of the Period 3 Elements (Cambridge (CIE) AS Chemistry): Revision Note

Describing Physical Properties of the Period 3 Elements

Arrangement of elements in the Periodic Table

Atomic radius

Atomic radius

Atomic radii of Period 3 elements table

Graph of atomic radii across Period 3

Ionic radius

Ionic radii of ions of Period 3 elements table

Graph of ionic radii across Period 3 ions

Melting point

Melting points of the elements across Period 3 table

Graph of melting points across Period 3

Electrical conductivity

Trends in electrical conductivity across Period 3 table

Ready to test your students on this topic?

1. Atomic Structure

Particles in the Atom & Atomic Radius

Atomic Structure & Subatomic Particles

Determining Subatomic Structure

Variations in Atomic & Ionic Radius

Isotopes

Isotopes

Electrons, Energy Levels & Atomic Orbitals

Electronic Structure

Sub-shells & Orbitals

Electronic Configuration

Determining Electronic Configuration

Ionisation Energy

Defining Ionisation Energy

Ionisation Energy Trends

Ionisation Energy & Electronic Configuration

2. Atoms, Molecules & Stoichiometry

Relative Masses of Atoms & Molecules

Relative Masses

The Mole & the Avogadro Constant

The Mole & the Avogadro Constant

Formulas

Formulae

Balancing Equations

Empirical & Molecular Formulae

Water of Crystallisation

Reacting Masses & Volumes (of Solutions & Gases)

Reacting Masses & Volumes

3. Chemical Bonding

Electronegativity & Bonding

Electronegativity

Trends in Electronegativity

Electronegativity & Bonding

Ionic Bonding

Ionic Bonding

Ionic Bonding Examples

Metallic Bonding

Metallic Bonding

Covalent Bonding & Coordinate (Dative Covalent) Bonding

Covalent Bonding

Coordinate Bonding

Hybridisation

Bond Energy & Length

Shapes of Molecules

Shapes of Molecules

Intermolecular Forces, Electronegativity & Bond Properties

Hydrogen Bonding

Bond Polarity & Dipole Moments

Van der Waals' Forces

Inter & Intramolecular Forces

Dot-&-Cross Diagrams

Dot-&-Cross Diagrams

4. States of Matter

The Gaseous State: Ideal & Real Gases & pV = nRT

Gas Pressure

Ideal Gases

Bonding & Structure

Lattice Structures

Bonding & Structure

5 Chemical Energetics

Enthalpy Change, ΔH

Enthalpy Change, ΔH

Reaction Pathway Diagrams

Standard Enthalpy Change