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Inherent thermal regeneration performance of different MnO 2 crystallographic structures for mercury removal
Manganese oxides with different crystallographic structures were investigated for gas-phase elemental mercury removal. The inherent thermal regeneration performance and mechanism of α- and γ-MnO were studied. The manganese dioxides were found to possess a mercury removal efficiency of higher than 96...
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| Published in: | Journal of hazardous materials 2019-07, Vol.374, p.267 |
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| Main Authors: | , , , , , , |
| Format: | Article |
| Language: | English |
| Online Access: | Get full text |
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| Summary: | Manganese oxides with different crystallographic structures were investigated for gas-phase elemental mercury removal. The inherent thermal regeneration performance and mechanism of α- and γ-MnO
were studied. The manganese dioxides were found to possess a mercury removal efficiency of higher than 96% even after 120 min mercury exposure except for β-MnO
which removed much less mercury than Mn
O
. The α-MnO
was found to have a higher recyclability of mercury capture and better durability for regeneration than γ-MnO
. During the first 1 h of exposure, α-MnO
showed an excellent mercury capacity of 128 μg/g over 5 regeneration cycles. While for γ-MnO
, the mercury capacity of the fifth cycle was reduced to 68.74 μg/g, which is much lower than 131.42 μg/g for the first cycle. The microstructure of α-MnO
was maintained throughout regeneration cycles due to its capability to retain lattice oxygen. In comparison, γ-MnO
experienced reconstruction and phase transformation induced by oxygen vacancies due to lattice oxygen loss during regeneration process, leading to a degradation in mercury capture. The α-MnO
oriented composite was found to be better developed into a regenerable catalytic sorbent for mercury removal from flue gases of coal-fired power plants. |
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| ISSN: | 1873-3336 |