Abstract
Coupling elemental mercury (Hg0) oxidation, autotrophic denitrifying sulfur oxidation, and sulfur disproportionation offers technologicalpotential for simultaneous Hg0 and nitric oxide (NO) removal. This study shed light onsimultaneous demercuration and denitration of flue gas bya sulfur-oxidizing membrane biofilm reactor (MBfR). Removal efficiency ofHg0 and NO attained 92% and 83%, respectivelyin long-term operation. Taxonomic and metagenomic study revealed that a tremendous variety of Hg0-oxidizing bacteria (MOB) (Thiobacillus, Truepera, etc.), denitrifying/sulfur-oxidizing bacteria (DSOB) (Thioalkalivibrio, Thauera, etc.), sulfur-disproportionating bacteria (SDB) (Desulfobulbus, Desulfomicrobium, etc.), and multi-functional bacteria (Halothiobacillus, Thiobacillus, etc.) significantly increased in abundance during growth under feeding of Hg0 and NO in simulated flue gas. The comprehensive employment of sequential chemical extraction processes, inductive coupled mass spectrometry, X-ray diffraction, X-ray photoelectron spectroscopy, and scanning electron microscopy coupled to energy disperse spectroscopy confirmed that Hg0 was finally biologically oxidized to crystallized metacinnabar (β-HgS) extracellular micromolecular particles. Our findings provided mechanistic insights that MOB, DSOB, and multi-functional bacteria synergistically bio-oxidized Hg0 as the initial electron donor to Hg2+ and denitrified NO as the terminal electron acceptor to N2. SDB disproportionated S0 branched from S2O32- into S2- and SO42-, and β-HgS formation from Hg2+ and disproportionation-derived S2-, thermodynamically favored Hg0 bio-oxidation. This novel biotechnique can be a cost-effective and environmentally friendly alternative toflue gasHg0 and NO treatment. KEY POINTS: • Combination of Hg0 bio-oxidation and autotrophic denitrifying sulfur oxidation achieved simultaneous Hg0 and NO removal. • Thiosulfate disproportionation reinforced Hg0 bio-oxidation for Hg0 removal. • Mercury-oxidizing bacteria, denitrifying/sulfur-oxidizing bacteria, and sulfur-disproportionating bacteria synergistically accomplished Hg0 and NO removal.
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