6533b837fe1ef96bd12a27a0

RESEARCH PRODUCT

Nanocrystalline ZnCO3—A novel sorbent for low-temperature removal of H2S

Igor BezverkhyyKevin BalichardCamille Nyikeine

subject

Thermogravimetric analysisEnvironmental EngineeringMaterials scienceSorbentHealth Toxicology and MutagenesisInorganic chemistryCarbonatesTemperatureSulfidationOxideMicrostructureRate-determining stepPollutionNanocrystalline materialchemistry.chemical_compoundchemistryZinc CompoundsNanoparticlesEnvironmental ChemistryReactivity (chemistry)Hydrogen SulfideWaste Management and Disposal

description

Abstract The reactivity of a nanocrystalline ZnCO 3 toward H 2 S (0.2 vol% in N 2 /H 2 mixture) at 140–180 °C was characterized by thermal gravimetric analysis and by breakthrough curves measurements. We have found that under used conditions transformation of ZnCO 3 into ZnS is complete and the rate determining step of the sulfidation is the surface reaction. Such behavior is in strike contrast with that of ZnO whose sulfidation is severely limited by diffusion. The higher reactivity of ZnCO 3 in comparison with ZnO is attributed to the different microstructure of ZnS layer formed in these materials after a partial sulfidation. As in ZnO–ZnS transformation the molar volume increases (from 14.5 to 23.8 cm 3 /mol), a continuous protective ZnS layer is formed hampering the access of H 2 S to the non reacted ZnO core. By contrast, in ZnCO 3 –ZnS transformation the molar volume decreases (from 27.9 to 23.8 cm 3 /mol), which produces a discontinuous non-protective ZnS layer enabling a complete transformation of ZnCO 3 even at 140 °C. The higher reactivity of ZnCO 3 results in a considerable increase of the breakthrough sulfur capacity of the carbonate in comparison with oxide. The material has therefore a good potential for being used as a disposable sorbent for H 2 S capture at low temperature.

yearjournalcountryeditionlanguage
2013-08-03Journal of Hazardous Materials
https://doi.org/10.1016/j.jhazmat.2013.10.068