Key Enthalpy Terms

The ionisation energy (ΔH_IE^ꝋ) is the standard enthalpy change that occurs on the removal of 1 mole of electrons from 1 mole of gaseous atoms or positively charged ions
Ionisation energy is always endothermic as energy is need to overcome the attraction between an electron and the nucleus
The first ionisation energy (ΔH_IE1^ꝋ) is the energy required to remove one mole of electrons from 1 mole of gaseous atoms of an element to form 1 mole of 1+ ions in the gaseous phase

ΔH_IE1^ꝋAl (g) → Al⁺ (g) + e^– ΔH_IE1^ꝋ= +577 kJ mol^-1

The second ionisation energy (ΔH_IE2^ꝋ) is the energy required to remove 1 mole of electrons from 1 mole of gaseous 1+ ions to form 1 mole of 2+ ions in the gaseous phase

ΔH_IE2^ꝋAl⁺ (g) → Al²⁺ (g) + e^– ΔH_IE2^ꝋ= +1820 kJ mol^-1

The enthalpy of atomisation (ΔH_at^ꝋ) is the standard enthalpy change that occurs on the formation of 1 mole of separate gaseous atoms an element in its standard state
The ΔH_at^ꝋis always endothermic as energy is always required to break any bonds between the atoms in the element or to break the element into its gaseous atoms
- Since this is always an endothermic process, the enthalpy change will always have a positive value

Na (s) → Na (g) ΔH_at^ꝋ = +108 kJ mol^-1

½Cl₂ (g) → Cl (g) ΔH_at^ꝋ = +122 kJ mol^-1

The electron affinity (ΔH_EA^ꝋ) of an element is the energy change when 1 mole of electrons is gained by 1 mole of gaseous atoms of an element to form 1 mole of gaseous ions under standard conditions
For example, the first electron affinity of chlorine is:

Cl (g)+ e^– → Cl^– (g) ΔH_EA^ꝋ= -364 kJ mol^-1

The first electron affinity is always exothermic as energy is released when electrons are attracted to the atoms
However, the second electron affinity of an element can be endothermic as illustrated by oxygen:

O^–(g) + e^– → O^2- (g) ΔH_EA^ꝋ= +844 kJ mol^-1

This is because a large force of repulsion must be overcome between the negatively charged ion and the second electron requiring a large input of energy

The lattice enthalpy (ΔH_lat^ꝋ) is defined as the standard enthalpy change that occurs on the formation of 1 mole of gaseous ions from the solid lattice
The ΔH_lat^ꝋis always endothermic as energy is always required to break any bonds between the ions in the lattice
- Since this is always an endothermic process, the enthalpy change will always have a positive value

NaCl (s) → Na⁺ (g) + Cl^- (g) ΔH_lat^ꝋ = +790 kJ mol^-1

The standard enthalpy change of solution (ΔH_sol^ꝋ) is the enthalpy change when 1 mole of an ionic substance dissolves in sufficient water to form an infinitely dilute solution
The symbol (aq) is used to show that the solid is dissolved in sufficient water
ΔH_sol^ꝋ can be exothermic (negative) or endothermic (positive)

LiBr (s) → LiBr (aq) ΔH_sol^ꝋ= -48.8 kJ mol^-1

KCl (s) → KCI (aq) ΔH_sol^ꝋ= +17.2 kJ mol^-1

CaCl₂ (s) → CaCl₂ (aq) ΔH_sol^ꝋ= -82.8 kJ mol^-1

The standard enthalpy change of hydration (ΔH_hyd^ꝋ) is the enthalpy change when 1 mole of a specified gaseous ion dissolves in sufficient water to form an infinitely dilute solution

Mg²⁺(g) → Mg²⁺(aq) ΔH_hyd^ꝋ= -1963 kJ mol^-1

Br^-(g) → Br^-(aq) ΔH_hyd^ꝋ= -328 kJ mol^-1

Hydration enthalpies are the measure of the energy that is released when there is an attraction formed between the ions and water molecules
Hydration enthalpies are exothermic
The term solvation is used in place of hydration if water has been replaced by another solvent
When an ionic solid dissolves in water, positive and negative ions are formed
Water is a polar molecule with a δ- oxygen (O) atom and δ+ hydrogen (H) atoms which will form ion-dipole attractions with the ions present in the solution
The oxygen atom in water will be attracted to the positive ions and the hydrogen atoms will be attracted to the negative ions

Chemical Energetics - Ion-Dipole Bonds, downloadable AS & A Level Chemistry revision notes

The polar water molecules will form ion-dipole bonds with the ions in solution causing the ions to become hydrated

Key Enthalpy Terms (DP IB Chemistry: HL)