The process in which particles in a colloid aggregate into larger clumps. The term is used for a reversible aggregation of particles in which the forces holding the particles together are weak and the colloid can be redispersed by agitation.

The stability of a lyophobic colloidal dispersion depends on the existence of a layer of electric charge on the surface of the particles. Around this are attracted electrolyte ions of opposite charge, which form a mobile ionic atmosphere

The result is an electrical double layer on the particle, consisting of an inner shell of fixed charges with an outer mobile atmosphere. The potential energy between two particles depends on repulsive interaction between double layers on adjacent particles and an attractive interaction due to van der walls forces between the particles.

At large separations, the repulsive forces dominate, and this accounts for the overall stability of the colloid. As the particle become closer together, the potential energy increases to a maximum and then falls sharply at very close separations, where the van der walls forces dominate.

This potential-energy minimum corresponds to coagulation and is irreversible

If the ionic strength of the solution is high, the ionic atmosphere around the particle is dense and the potential-energy curve shows a shallow minimum at larger separation of particles. This corresponds to flocculation of the particles.

Ions with a high charge are particularly effective for causing flocculation and coagulation.