An ionic covalent-organic framework (ICOF-1 containing sp(3 )hybridized boron anionic centers formed by spiroborate linkage and dimethylammonium ions) is explored as an ion exchanger for the removal of lead (Pb2+) ions from aqueous solution. From molecular simulations, the Pb2+ ions are observed to exchange with the nonframework DMA(+) ions in the ICOF-1. At a concentration of 600 ppm, the Pb2+ ions are completely exchanged and reside in the ICOF-1, while the DMA(+) ions are in a dynamic equilibrium with the solution. It is revealed that the exchange between Pb(2+ )and DMA(+) is governed by the stronger attraction of Pb2+ with the negatively charged ICOF-1 framework. The radial distribution functions and mean-squared displacements further show that the exchanged Pb2+ ions are in a closer proximity to the ICOF-1 framework with a smaller mobility than DMA(+) ions. The simulation study provides microscopic insight into the ion-exchange process between Pb2+ and DMA(+), and it suggests that the ICOF-1 might be an intriguing candidate for water purification.