Carbon-based sorbents impregnated with iron oxides for removing mercury in energy generation processes

Gaseous phase mercury emissions into the atmosphere from fossil fuel combustion processes for energy production are a matter of serious environmental concern. Several technologies have been studied and proposed to address this problem, but none of them is mature enough from a commercial point of vie...

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Bibliographic Details
Published in:Energy (Oxford) 2018-09, Vol.159, p.648-655
Main Authors: Trobajo, J.R., Antuña-Nieto, C., Rodríguez, E., García, R., López-Antón, M.A., Martínez-Tarazona, M.R.
Format: Article
Language:English
Subjects:
Activated carbon
Adsorption
Deactivation
Electricity generation
Emissions
Energy
Environmental perception
Fossil fuels
Fuel combustion
Gases
Hematite
Iron oxides
Mercury
Mercury (metal)
Mercury atmosphere
Oxides
Regenerable
Regeneration
Retention
Sorbents
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Summary:Gaseous phase mercury emissions into the atmosphere from fossil fuel combustion processes for energy production are a matter of serious environmental concern. Several technologies have been studied and proposed to address this problem, but none of them is mature enough from a commercial point of view. This study aims to provide new insights into the interaction between mercury and iron oxides in order to enable the design of cost-effective mercury capture technology based on regenerable sorbents. Different iron oxides supported on an activated carbon were prepared and tested for the removal of elemental mercury (Hg0). It was found that 1) maghemite promoted the removal of mercury to a greater extent than goetite/hematite achieving 100% efficiencies and 2) the mercury-sorbent interaction is determined by the oxygen vacancies present in the iron oxide. The mercury retention efficiency is maintained after the sorbent is regenerated and it is not deactivated by the presence of acid gases. The results obtained with the sorbent loaded with maghemite open new perspectives for the retention of gaseous Hg0, combining high efficiency, good regenerability and lower price in comparison with sorbents developed to date. Once the regeneration capacity is assessed, the adsorption process will be scaled. [Display omitted] •Maghemite showed better performance for mercury removal than other iron species.•Oxygen vacancies in maghemite act as active centers for Hg adsorption.•The Fe/AC sorbent is effective at low (40 °C) and high (140 °C) temperatures.•The Fe/AC sorbent can be regenerated without losing efficiency.•Acid gases do not poison the sorbent.
ISSN:0360-5442
1873-6785
DOI:10.1016/j.energy.2018.06.189