Review on Magnetic Adsorbents for Removal of Elemental Mercury from Flue Gas

Yang, Wei; Wang, Zhihua; Liu, Yangxian

doi:10.1021/acs.energyfuels.0c02931

Cited by 52 publications

(18 citation statements)

References 140 publications

(292 reference statements)

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“…The CO 2 adsorption capacity of NSK (2) decreases from 4.06 to 3.31 mmol/g, and the CO 2 adsorption capacity of NEK (2) decreases from 3.25 to 2.83 mmol/g. This may be because the H 2 O (g) will condense and form a water film on the surface of adsorbents, thereby blocking the pores. − Another possible reason is that H 2 O (g) may compete with CO 2 to adsorb at the active sites on the adsorbent surface, thereby reducing the adsorption performance of CO 2 . − The research of Chen et al also found that the adsorption capacity of CO 2 decreased correspondingly with the increase of water molecules.…”

Section: Resultsmentioning

confidence: 99%

Removal of CO₂ from Flue Gas Using Seaweed Porous Carbons Prepared by Urea Doping and KOH Activation

et al. 2020

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Capture of CO 2 and utilization of marine biomass resources have attracted more and more attention due to climate change and lack of terrestrial resources. In this article, using sargassum and enteromorpha as raw materials, two kinds of seaweed porous carbons adsorbents were prepared using urea doping and KOH activation to capture CO 2 from flue gas. Characterization methods such as BET, pH, SEM, FTIR, and XPS were used to investigate the physicochemical properties of seaweed porous carbon adsorbents. The main parameters and flue gas components that may affect the CO 2 adsorption, as well as the adsorption mechanism were also studied. The results show that compared with inactivated biochars, all of the specific surface areas, the surface functional groups, and the CO 2 adsorption capacities of the seaweed porous carbons adsorbents (e.g., NSK (2) and NEK (2)) are significantly increased. The highest CO 2 adsorption capacities of NSK (2) and NEK (2) are up to 4.06 and 3.25 mmol/g at 25 °C, respectively. Moreover, NSK (2) and NEK (2) still show excellent CO 2 adsorption performance after 10 regeneration experiments (reaching 3.69 and 2.93 mmol/g, respectively). Other flue gas components such as O 2 and NO have no effect on the CO 2 adsorption performance of NSK (2) and NEK (2), while H 2 O (g) and SO 2 exhibit an inhibitory effect. The pseudo-first-order model can reasonably explain the CO 2 adsorption processes of two kinds of seaweed porous carbons adsorbents, showing that external mass transfer is the main control step for the CO 2 capture. Thermodynamic analysis results demonstrate that physical adsorption is dominant in the CO 2 adsorption process over NSK (2) and NEK (2), and chemical adsorption only plays a supplementary role.

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Section: Resultsmentioning

confidence: 99%

Removal of CO₂ from Flue Gas Using Seaweed Porous Carbons Prepared by Urea Doping and KOH Activation

et al. 2020

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“…Then, these formed new active substances can further participate in the process of Hg 0 removal, thus being able to increase the Hg 0 capture efficiency. The specific reaction steps are described by eqs –. − …”

Section: Resultsmentioning

confidence: 99%

Removal of Elemental Mercury Using Seaweed Biomass-Based Porous Carbons Prepared from Microwave Activation and H₂O₂ Modification

Yang

Liu

2021

Energy Fuels

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In this article, two kinds of seaweed biomass-based porous carbons were prepared by a green and efficient method of microwave activation/H 2 O 2 synergistic modification from seaweed biomass resources. The Hg 0 capture performance of seaweedbased porous carbons was tested in a fixed-bed reactor system. The results show that microwave activation greatly increases the surface area of porous carbons. The porous carbons (S8W30 and E8W30) modified with 30% H 2 O 2 exhibit excellent Hg 0 removal capacity at 120 °C. NO, O 2 , and low concentrations of SO 2 in flue gas have a positive effect on the removal of Hg 0 . Water vapor and high concentrations of SO 2 exhibit a negative effect on the process of Hg 0 capture. The oxygen-containing functional groups (CO and C−OH/C−O−C groups) on the surface of the modified porous carbon, which are mainly produced by H 2 O 2 modification, are considered to be the main active sites for Hg 0 capture. The X-ray photoelectron spectroscopy (XPS) analysis shows that the adsorbed Hg 0 can be oxidized to Hg 2+ . The modified porous carbons exhibit good development and application prospects compared with commercial activated carbon (AC) or other activated carbons.

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“…The Ag nanoparticles tended to grow to larger and nonuniform particles, which will decrease the Hg 0 removal performance of Ag/ zeolite. 34 Several effective strategies for controlling the size and 19…”

Section: Natural Mineral Sorbentsmentioning

confidence: 99%

Mercury Removal from Flue Gas by Noncarbon Sorbents

Yang

Zhao

et al. 2021

Energy Fuels

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Mercury emitted from coal-fired power production industries is an enormous threat to human health and ecosystems. Sorbent injection is a promising and feasible strategy for mercury removal from the flue gas. Activated carbons (ACs) are the most explored mercury sorbents, which generally displayed high adsorption capacity. However, ACs still suffer from some disadvantages, such as impeding the utilization of fly ash in concrete production, difficulty to be regenerated for recycle, and so on. Thus, many noncarbon sorbents have been developed as supplementary options besides ACs for mercury removal. A review on the recent progress regarding noncarbon sorbents for removing mercury is provided. In this contribution, the Hg 0 removal capacities of natural minerals, waste-derived sorbents, metal oxides, metal sulfides, and magnetic adsorbents have been summarized. Particularly, the modification methods as well as their intrinsic roles for each types of noncarbon sorbents have been presented and discussed in depth. This work provides guidance for the design and exploration of noncarbon adsorbents, which can be applied in both coal-fired power plants and other nonpower production industries.

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Review on Magnetic Adsorbents for Removal of Elemental Mercury from Flue Gas

Cited by 52 publications

References 140 publications

Removal of CO₂ from Flue Gas Using Seaweed Porous Carbons Prepared by Urea Doping and KOH Activation

Removal of CO₂ from Flue Gas Using Seaweed Porous Carbons Prepared by Urea Doping and KOH Activation

Removal of Elemental Mercury Using Seaweed Biomass-Based Porous Carbons Prepared from Microwave Activation and H₂O₂ Modification

Mercury Removal from Flue Gas by Noncarbon Sorbents

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Review on Magnetic Adsorbents for Removal of Elemental Mercury from Flue Gas

Cited by 52 publications

References 140 publications

Removal of CO2 from Flue Gas Using Seaweed Porous Carbons Prepared by Urea Doping and KOH Activation

Removal of CO2 from Flue Gas Using Seaweed Porous Carbons Prepared by Urea Doping and KOH Activation

Removal of Elemental Mercury Using Seaweed Biomass-Based Porous Carbons Prepared from Microwave Activation and H2O2 Modification

Mercury Removal from Flue Gas by Noncarbon Sorbents

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Removal of CO₂ from Flue Gas Using Seaweed Porous Carbons Prepared by Urea Doping and KOH Activation

Removal of CO₂ from Flue Gas Using Seaweed Porous Carbons Prepared by Urea Doping and KOH Activation

Removal of Elemental Mercury Using Seaweed Biomass-Based Porous Carbons Prepared from Microwave Activation and H₂O₂ Modification