Iron-Rich Biochar to Adsorb Volatile Organic Compounds Emitted from Asphalt-Surfaced Areas

Mousavi, Masoumeh; Aldagari, Sand; Crocker, Michael S.; Ackerman-Biegasiewicz, Laura K.G.; Fini, Elham H.

doi:10.1021/acssuschemeng.2c06292

Cited by 30 publications

(14 citation statements)

References 78 publications

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“…From Figure b, some alkane gases and a small amount of CO and CO 2 are still generated in the FR asphalt pyrolysis process . No new substances are generated, indicating that CFR is not involved in chemical reactions within asphalt .…”

Section: Results and Discussionmentioning

confidence: 96%

“…From Figure 3b, some alkane gases and a small amount of CO and CO 2 are still generated in the FR asphalt pyrolysis process. 20 No new substances are generated, indicating that CFR is not involved in chemical reactions within asphalt. 21 Comparing Figure 3a,b, the concentrations of gaseous products generated from asphalt are higher than those of FR asphalt.…”

Section: Cfr Effects On Dynamic Emission and Constituents Of Gaseous ...mentioning

confidence: 99%

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Suppressing Actions of Inorganic Flame Retardants on the Pyrolysis Behavior of Asphalt

Wang,

Xia,

2023

Langmuir

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To understand the suppressing actions of inorganic compound flame retardant (CFR) on the pyrolysis behavior of asphalt, five halogen-free flame retardants, such as expanded graphite, aluminum hydroxide, magnesium hydrate, calcium hydroxide, and microencapsulated red phosphorus, were selected to match the pyrolysis temperature ranges of four asphalt components, respectively. The pyrolysis behaviors, volatile emissions, and pyrolysis residues from asphalt and CFR-modified asphalt (FR asphalt) were compared. Also, the effects of CFR on the microscopic morphology, microstructures, and micromechanical performance of asphalt were analyzed. The high-temperature stability of asphalt is increased by the presence of CFR, and there is a flame-retardant constituent in CFR that suppresses the pyrolysis of each component in the overall asphalt pyrolysis process. Additionally, the FR asphalt pyrolysis process is endothermic. The added CFR retards the asphalt pyrolysis process. The formation of the surface carbon layer impedes heat transfer. Also, the volatile emissions during asphalt pyrolysis are reduced by the presence of CFR. The added CFR promotes an increase in the size of the asphalt microstructure. The surface of FR asphalt becomes rougher and more rugged than that of asphalt. Finally, the elastic modulus, deformation resistance, and micromechanical performance of asphalt are increased as the level of FR presence is increased. FR asphalt has a higher adhesive force, which is conducive to increasing the adhesivity of FR asphalt with mineral aggregate in the FR asphalt mixture.

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Section: Results and Discussionmentioning

confidence: 96%

Section: Cfr Effects On Dynamic Emission and Constituents Of Gaseous ...mentioning

confidence: 99%

Suppressing Actions of Inorganic Flame Retardants on the Pyrolysis Behavior of Asphalt

Wang,

Xia,

2023

Langmuir

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“…[95] It has been documented that introduction of select biochar can not only reduce this number, but also retain emission of volatile organic compounds (VOCs) which otherwise emits from asphalt during its service life. [29,96] It should be noted that VOCs contain significant amounts of carbon; for instance, hexadecane (C 16 H 34 ) which is typically emitted from asphalt-surfaced areas during construction and service life contains 0.847 g carbon per mole, and its release into the atmosphere contributes to air pollution and negative health impacts. [97] When biochar is added to asphalt latter loss can be reduced by as much as 76%.…”

Section: Implication Of Using Biochar In Roadwaysmentioning

confidence: 99%

“…[97] When biochar is added to asphalt latter loss can be reduced by as much as 76%. [96] If only 1% biochar is added in paving mixture, ≈22 tons of biochar would be used in every lane-mile (3.7 m wide and 15.2 cm thick). [49] Since biochar contains 33-48% carbon, this would sequester 7-10 tons of CO 2 per lane-mile of road.…”

Section: Implication Of Using Biochar In Roadwaysmentioning

confidence: 99%

Bio‐Carbon as a Means of Carbon Management in Roads

Pahlavan

Aldagari

Park

et al. 2023

Advanced Sustainable Systems

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This paper introduces biocarbon, referred to as biochar, as a novel eco‐friendly and cost‐effective additive to increase interactions among bitumen components while facilitating carbon management in roadway infrastructures. It is hypothesized that functional groups on biochar surfaces enhance interactions between biochar and bitumen constituents. This in turn enhances mechanical properties and durability of asphalt pavements. This study uses biochars derived from six different types of woody biomass and one type of algae, and polyethylene terephthalate granules as a carrier to introduce biochar to bitumen. Quantum‐based molecular modeling and noncovalent interaction analysis show that algal biochar interacts more effectively with bitumen components. The enhanced interaction of algal biochar is attributed to its surface functional groups including reactive nitrogen‐ and oxygen‐carrying functional groups. The rheological characterization of bitumen doped with different biochars confirms that the lowest separation index occurs for bitumen containing algal biochar, which also exhibits the highest percent of elastic recovery and resistance to permanent deformation. The study suggests that asphalt pavement durability can be enhanced by selection of the proper biochar to increase intermolecular interactions. Promising results for the algae biochar promote its use in carbon management for roadway infrastructure by sequestering CO2 from air through photosynthesis of algae biomass.

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“…Biochar (BC), produced via pyrolysis of waste biomass, has been received increasing attention for its environmentally friendly and cost-effective superiority. , Especially, after further modification, BC has been widely accepted as a low-cost sorbent for the removal of various inorganic and organic pollutants, owing to its adequate chemical and physical stability, high surface area, and functional groups. , Among the various of biochar-modified chemicals, the alkalis can alter pore structures, crystallinity, and surface area of the biomass. , Ca(OH) 2 , as a mineral prevalently existing in the terrestrial environment, has been found to have superiority for heavy-metal immobilization in the river sediment . Besides, Ca(OH) 2 can also capture CO 2 generated during biomass pyrolysis processes with the potential to form CaCO 3 and was also reported to have the ability to enrich oxygen-containing functional groups on the biochar surface .…”

Section: Introductionmentioning

confidence: 99%

Long-Term Lead Immobilization in River Sediment by Ca(OH)₂-Modified Rice Straw Biochar

Liu,

Tang,

Cai

et al. 2023

ACS Agric. Sci. Technol.

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Remediation of lead pollution is of great significance to water and sediment, in which Pb plays an important role and is leading the way. Therefore, the control of lead pollution has become the most concerning environmental issue at present. Among many removal techniques for polluted river sediment, immobilization is a cost-effective remediation technology. Biochar (BC) derived from the straw stalk was developed based on the recycling of agricultural byproducts, and further, the biomass was treated with calcium hydroxide to obtain a modified biochar (BCC). The immobilization mechanism on Pb removal by BC and BCC was deeply investigated through combination with Pb(II)-targeted adsorption in aqueous solution. In addition, the immobilization effect was also evaluated by using the TCLP and modified TCLP (−28 days) methods for river sediment. The leaching concentration was beyond the Chinese criteria for hazardous waste (5 mg/L, GB5085−2007) after 18 h and it did not exceed the limit of 0.75 after 2 days for BCC, the performance of which is much better than that of BC. What's more, pH remained relatively stable (around 4.5 for BCC) in the whole leaching period. The composition of C-containing groups on the surface of the biochars showed that the weight of carboxyl groups was increased after modification (from 2.66 to 19.94%), whereas carboxyl groups were decreased after adsorption for Pb(II) (from 19.94 to 8.51% for the BCC). A series of batch studies suggested that metal adsorption by BC/BCC occurs by both chemical reduction and complexation processes that follow a Langmuir isotherm model (R 2 = 0.99) and pseudo-second-order kinetics (R 2 = 0.99). The adsorption results indicated that the maximum adsorption capacity of BCC was up to 913.0 mg/g. Therefore, the removal mechanisms of Pb(II) can be summarized as electrostatic attraction, cation exchange, and metal/functional group exchange reactions for a surface inner-sphere complex or coprecipitation.

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Iron-Rich Biochar to Adsorb Volatile Organic Compounds Emitted from Asphalt-Surfaced Areas

Cited by 30 publications

References 78 publications

Suppressing Actions of Inorganic Flame Retardants on the Pyrolysis Behavior of Asphalt

Suppressing Actions of Inorganic Flame Retardants on the Pyrolysis Behavior of Asphalt

Bio‐Carbon as a Means of Carbon Management in Roads

Long-Term Lead Immobilization in River Sediment by Ca(OH)₂-Modified Rice Straw Biochar

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Iron-Rich Biochar to Adsorb Volatile Organic Compounds Emitted from Asphalt-Surfaced Areas

Cited by 30 publications

References 78 publications

Suppressing Actions of Inorganic Flame Retardants on the Pyrolysis Behavior of Asphalt

Suppressing Actions of Inorganic Flame Retardants on the Pyrolysis Behavior of Asphalt

Bio‐Carbon as a Means of Carbon Management in Roads

Long-Term Lead Immobilization in River Sediment by Ca(OH)2-Modified Rice Straw Biochar

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Product

Resources

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Long-Term Lead Immobilization in River Sediment by Ca(OH)₂-Modified Rice Straw Biochar