Development of selective mercury recovery technology by using iron iodide from waste sludge of non-ferrous metal smelting process

Abstract

The waste sludge from non-ferrous metal smelter contains high concentrations of mercury (Hg), arsenic (As) and sulfur (S). The Article 11 of the Minamata Convention on Mercury mandates the recovery of Hg before the disposal stage of Hg waste. However, As compounds have similar boiling points with Hg compounds, and they are considered interfering substances in the recovery of Hg. Moreover, a high concentration of S requires significant energy to volatilize Hg. This study examined the optimal conditions for selective recovery of Hg and energy reduction by introducing FeI2 as an additive during thermal treatment. Thermogravimetric analysis was utilized to evaluate the conversion of HgS to HgI2 under the influence of FeI2. The optimal conditions for thermal treatment such as temperature, treatment time, and molar ratio of [Hg]:[As]:[FeI2] were explored. The simulated waste indicated that the maximum separation efficiency of Hg was ∼95%, thereby allowing a selective separation of 81.5% of Hg from waste sludge with an Hg content of 0.33%, As content of 23.8%, and S content of 30.7%. Sequential extraction procedure was applied to evaluate the stability of Hg and As for residues. As a result, most Hg was vaporized and As was stabilized in sulfide, crystalline, and amorphous forms.