Wet flue gas desulfurization (WFGD) systems have several benefits, including SO2 removal and Hg pollution control. However, the absorbed ionic mercury may be transformed into insoluble elemental mercury because of the chemical interaction with the aqueous scrubbing solution, which causes mercury re-emission and reduces the mercury capture efficiency of the scrubber. This study investigates the effects of operating temperatures, pH, and O-2 and SO4 concentrations on the reduction of Hg2+ in the presence of SO32- in a simulated desulfurization aqueous solution. The results indicate that excess SO32- inhibits Hg2+ reduction due to the formation of the stable Hg(SO3)(3) complex, whereas a low SO32- concentration (<2 mM) leads to enhanced mercury re-emission due to the formation of more redox-unstable HgSO3. The Hg release increases from 18.6% to 59.6% when the operating temperature increases from 45 degrees C to 55 degrees C. A pH decrease in the slurry from 5 to 3 causes a significant increase in the Hg emission from 6.9 to 127.9 pg/m(3) in a simulated desulfurization slurry. In addition, O-2 caused a secondary emission of Hg by damaging the stable redox complexes of Hg2+ and SO32-. In the presence of oxygen, the Hg emission decreases; subsequently, a HgSO3SO4 complex is formed. Sulfate (HgSO4 and HgSO3SO4) inhibit the emission of Hg. (C) 2017 Published by Elsevier B.V.