The kinetics of physical gelation in aqueous melamine formaldehyde (MF) resin solutions were studied with the aid of low-resolution H-1 NMR T-2 relaxation experiments in combination with both static and dynamic light-scattering measurements. The investigations were conducted on a series of MF resins with increasing degrees of condensation. We show that MF aggregates (aided by hydrogen bonds) were immediately formed upon cooling from reaction to room temperature, that is, storage temperature. Surprisingly, the growth of these aggregates, which eventually led to the formation of a physical gel, did not have a major effect on molecular mobility. By means of light-scattering experiments, we were able to monitor the increase of the size of MF aggregates as a function of storage time. The physically gelled MF solutions were subjected to heating and subsequent cooling runs and again studied by light-scattering and nuclear magnetic resonance (NMR) experiments. MF aggregates were destroyed, depending on the degree of condensation, in the temperature range 35-60 degrees C according to NMR, and 40-75 degrees C as determined by light scattering. The process of physical gelation was reversible; upon subsequent cooling, the MF aggregates were formed anew.