Introduction to the Born-Haber cycle

Enthalpy changes depend on the state of reactants and of products, not on the pathway between them.

The enthalpy change for direct reaction between substances is the same as
the enthalpy change for any set of reactions that sum to give the direct reaction.

The equations in the indirect pathway add
to give the equation for the direct pathway as
each proceeds from reactants to products
of the direct pathway.

Their enthalpy changes add to give
the enthalpy change for the direct pathway.

Direct pathway:
or
Indirect pathway:

S(s) + ³/₂ O₂(g)

SO₃(g)

SO₂(g)

Alternative pathways are often represented as thermodynamic cycles as seen above for sulfur. The Born-Haber cycle shows formation of an ionic solid by reaction of its elements by the set of reactions shown below.

metal

nonmetal

indirect
pathway

M(s)

½X₂(g)

direct
pathway

metallic bond
breaking

covalent bond
breaking

gas phase atoms

M(g)

X(g)

electron loss

electron gain

–e^–

+e^–

gas phase ions

M⁺(g)

X^–(g)

form lattice

MX(s)

The enthalpy changes for several of the reactions in the indirect pathway are known for a variety of metals and nonmetals.

If known enthalpy changes are for reactions that proceed toward the products of the direct pathway, they can be simply added. The sign of any enthalpy change that proceeds toward reactants of the direct pathway must reversed.

The Born-Haber cycle can be used

to determine the magnitude of enthalpy changes that are difficult to measure directly

such as MX(s)

M⁺(g) + X^–(g)

to give insight into the driving force for formation of an ionic solid.

Is it electron transfer?? Is it formation of the lattice??