Modeling Powdered Activated Carbon Injection for the Uptake of Elemental Mercury Vapors

Flora, Joseph R.V.; Vidić, Radisav D.; Liu, Wei; Thurnau, Robert C.

doi:10.1080/10473289.1998.10463763

Cited by 37 publications

(28 citation statements)

References 10 publications

(14 reference statements)

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“…Our work suggests that the dominant Hg II species produced in the gas phase are BrHgONO and BrHgOOH, though the actual speciation of Hg II in the atmosphere would likely be modified through cycling in aerosols and clouds (Hedgecock and Pirrone, 2001;Lin et al, 2006). We did not consider heterogeneous Hg 0 oxidation on particle surfaces (e.g., Vidic et al, 1998;Flora et al, 1998;Lee et al, 2004) due to inadequate information to formulate atmospheric rates. Further study of heterogeneous Hg 0 oxidation is needed (Ariya et al, 2015).…”

Section: Atmosphere-ocean Couplingmentioning

confidence: 99%

A new mechanism for atmospheric mercury redox chemistry: implications for the global mercury budget

et al. 2017

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Abstract. Mercury (Hg) is emitted to the atmosphere mainly as volatile elemental Hg 0 . Oxidation to water-soluble Hg II plays a major role in Hg deposition to ecosystems. Here, we implement a new mechanism for atmospheric Hg 0 / Hg II redox chemistry in the GEOS-Chem global model and examine the implications for the global atmospheric Hg budget and deposition patterns. Our simulation includes a new coupling of GEOS-Chem to an ocean general circulation model (MITgcm), enabling a global 3-D representation of atmosphereocean Hg 0 / Hg II cycling. We find that atomic bromine (Br) of marine organobromine origin is the main atmospheric Hg 0 oxidant and that second-stage HgBr oxidation is mainly by the NO 2 and HO 2 radicals. The resulting chemical lifetime of tropospheric Hg 0 against oxidation is 2.7 months, shorter than in previous models. Fast Hg II atmospheric reduction must occur in order to match the ∼ 6-month lifetime of Hg against deposition implied by the observed atmospheric variability of total gaseous mercury (TGM ≡ Hg 0 + Hg II (g)). We implement this reduction in GEOS-Chem as photolysis of aqueous-phase Hg II -organic complexes in aerosols and clouds, resulting in a TGM lifetime of 5.2 months against deposition and matching both mean observed TGM and its variability. Model sensitivity analysis shows that the interhemispheric gradient of TGM, previously used to infer a longer Hg lifetime against deposition, is misleading because Southern Hemisphere Hg mainly originates from oceanic emissions rather than transport from the Northern Hemisphere.The model reproduces the observed seasonal TGM variation at northern midlatitudes (maximum in February, minimum in September) driven by chemistry and oceanic evasion, but it does not reproduce the lack of seasonality observed at southern hemispheric marine sites. Aircraft observations in the lowermost stratosphere show a strong TGM-ozone relationship indicative of fast Hg 0 oxidation, but we show that this relationship provides only a weak test of Hg chemistry because it is also influenced by mixing. The model reproduces observed Hg wet deposition fluxes over North America, Europe, and China with little bias (0-30 %). It reproduces qualitatively the observed maximum in US deposition around the Gulf of Mexico, reflecting a combination of deep convection and availability of NO 2 and HO 2 radicals for second-stage HgBr oxidation. However, the magnitude of this maximum is underestimated. The relatively low observed Hg wet deposition over rural China is attributed to fast Hg II reduction in the presence of high organic aerosol concentrations. We find that 80 % of Hg II deposition is to the global oceans, reflecting the marine origin of Br and low concentrations of organic aerosols for Hg II reduction. Most of that deposition takes place to the tropical oceans due to the availability of HO 2 and NO 2 for second-stage HgBr oxidation.

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Section: Atmosphere-ocean Couplingmentioning

confidence: 99%

A new mechanism for atmospheric mercury redox chemistry: implications for the global mercury budget

et al. 2017

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“…The median pore diameter was reported to be 150 Å 18 and was used in estimating D Kn . The activated carbon density ( p ϭ 2.04 g/cm 3 ) and porosity (ε p ϭ 0.67) were provided by the manufacturer. Yang 19 reports that the tortuosity ( p ) for activated carbons ranges from 5 to 65, and Bush et al 20 report that the bed porosity (ε b ) for full-scale coalfired power plants employing a baghouse for particulate control ranges from 0.57 to 0.86.…”

Section: Parameter Estimationmentioning

confidence: 99%

“…Flora et al 3 developed a model for a closed-batch reactor system that accounted for both external mass transfer resistance and intraparticle transport. External mass transfer was modeled using Fick's first law, while the intraparticle transport was modeled using the surface diffusion transport mechanism.…”

Section: Introductionmentioning

confidence: 99%

Modeling Sorbent Injection for Mercury Control in Baghouse Filters: I—Model Development and Sensitivity Analysis

Flora

Hargis

O’Dowd

et al. 2003

Journal of the Air & Waste Management Association

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A two-stage mathematical model for Hg removal using powdered activated carbon injection upstream of a baghouse filter was developed, with the first stage accounting for removal in the ductwork and the second stage accounting for additional removal caused by the retention of carbon particles on the filter. The model shows that removal in the ductwork is minimal, and the additional carbon detention time from the entrapment of the carbon particles in the fabric filter enhances the Hg removal from the gas phase. A sensitivity analysis on the model shows that Hg removal is dependent on the isotherm parameters, the carbon pore radius and tortuosity, the C/Hg ratio, and the carbon particle radius.

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“…Figure 3 illustrates the pore-size distribution of activated carbons with a high surface area (NH, H-400S, and H-605S) modified by elemental sulfur at temperatures of 400 and 650 C. The elemental sulfur was initially gasified and mainly composed of chain sulfur molecules at a temperature of 400 C, which diffused with relative ease into the mesopores and macropores of activated carbons. Correspondingly, the elemental sulfur was completely gasified and mostly composed of ring sulfur molecules at the temperature of 650 C, which was relatively difficult to diffuse into the mesopores and macropores of activated carbons (Flora et al, 1998;Sandra and Roberto, 1999). The sulfur molecules partially blocked the mesopores and macropores acting as passages to micropores.…”

Section: Resultsmentioning

confidence: 99%

Enhanced mercuric chloride adsorption onto sulfur-modified activated carbons derived from waste tires

Yuan

Wang

Xue

et al. 2012

Journal of the Air & Waste Management Association

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Modeling Powdered Activated Carbon Injection for the Uptake of Elemental Mercury Vapors

Cited by 37 publications

References 10 publications

A new mechanism for atmospheric mercury redox chemistry: implications for the global mercury budget

A new mechanism for atmospheric mercury redox chemistry: implications for the global mercury budget

Modeling Sorbent Injection for Mercury Control in Baghouse Filters: I—Model Development and Sensitivity Analysis

Enhanced mercuric chloride adsorption onto sulfur-modified activated carbons derived from waste tires

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