Physical Properties of Transition Elements (HL) | HL IB Chemistry Revision Notes 2025

Physical Properties of Transition Elements

The definition of a transition metal is an element with an incomplete d-subshell or an element that can form at least one stable cation with an incomplete d-subshell
This definition distinguishes them from d-block elements because scandium and zinc do not fit the definition
- Scandium only forms the ion Sc³⁺, configuration [Ar] 3d⁰
- Zinc only forms the ion Zn²⁺, configuration [Ar] 3d¹⁰
The elements of the first transition series are therefore titanium to copper

The transition metals are located in the d-block
- Period 4: From titanium to copper
- Period 5: From zirconium to silver
- Periods 6 and 7 are complicated by the presence of the f-block lanthanides and actinides

Periodic table labelling the different blocks and identifying the transition metals within the d block

The transition elements and the d-block elements

Like other metals, transition metals have a metallic lattice structure
- Layers of positive ions within a sea of delocalised electrons
Since the 3d and 4s subshells are so close in energy, the transition metals are able to delocalise their d-electrons to form metallic bonds
This causes transition metals to have particularly good electrical conductivity and high melting points

The ability to delocalise the d-electrons means that transition metals have a greater electron density
- This means that the electrostatic forces of attraction between the large positive charge of the cations and the sea of delocalised electrons are strengthened
- The stronger forces of attraction result in a higher melting point as more energy is required to overcome them
The melting points of s-block metals range from 27 ^oC for francium to 839 ^oC for calcium
- As the following graph shows, all of the Period 4 transition metals have higher melting points than Group 1 and Group 2 metals
- There is an exception to the lower melting points of s-block metals with a melting point of 1,287 ^oC for beryllium, due to the small size of a beryllium atom resulting in strong metallic bonding

Graph comparing the melting points of Group 1 and 2 metals with transition metals

The Period 4 transition metals have higher melting points than s-block metals

Transition metals have a large number of delocalised electrons
Therefore, more electrons are able to move when a potential difference is applied
This causes transition metals to have high electrical conductivity
The three most conductive metals are:
1. Silver
2. Copper - the most used metal in electrical cables due to a combination of cost and conductivity
3. Gold

For more information about other characteristic properties of transition metals, see our revision note on the Characteristic Properties of Transition Elements