Fast Synthesis of Gibbsite Nanoplates and Process Optimization using Box-Behnken Experimental Design

Developing the ability to synthesize compositionally and morphologically well-defined gibbsite particles with high yield is an ongoing need that has not yet achieved the required level of rational design. Here we report optimization of a clean inorganic synthesis route based on statistical experimental design examining the influence of Al(OH)(3) gel precursor concentration, pH, and aging time at temperature. At 80 degrees C, the optimum synthesis conditions of gel concentration at 0.5 M, pH at 9.2, and time at 72 h maximized the reaction yield up to similar to 88%. The resulting gibbsite product is composed of highly uniform euhedral hexagonal nanoplates within a basal plane diameter range of 200-400 nm. The independent roles of key system variables in the growth mechanism are considered. On the basis of these optimized experimental conditions, the synthesis procedure, which is both cost-effective and environmentally friendly, has the potential for mass production scale-up of high quality gibbsite material for various fundamental research and industrial applications.