Biomass/Biochar carbon materials for CO2 capture and sequestration by cyclic adsorption processes: A review and prospects for future directions

Karimi, Mohsen; Shirzad, Mohammad; Silva, José A.C.; Rodrigues, Alírio E.

doi:10.1016/j.jcou.2022.101890

Cited by 113 publications

(50 citation statements)

References 288 publications

(418 reference statements)

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“…Furthermore, cement, steel, and iron manufacturers are the subsequent sources of CO 2 emissions [ 4 ]. In this way, significant attention has been paid to carbon capture [ 8 ] and sequestration strategies [ 9 ] to reduce, control, and utilize greenhouse gases, including CO 2 , methane, nitrogen, sulfur, chlorofluorocarbons, and so on [ 10 , 11 ]. To this end, according to the BLUE map scenario of the international energy agency [ 12 ], sustainable energy sources, including biomass [ 13 ], biogas [ 14 ], and solar energy [ 15 ], have been introduced as promising candidates to replace traditional fossil fuels.…”

Section: Introductionmentioning

confidence: 99%

Introducing a Linear Empirical Correlation for Predicting the Mass Heat Capacity of Biomaterials

et al. 2022

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This study correlated biomass heat capacity (Cp) with the chemistry (sulfur and ash content), crystallinity index, and temperature of various samples. A five-parameter linear correlation predicted 576 biomass Cp samples from four different origins with the absolute average relative deviation (AARD%) of ~1.1%. The proportional reduction in error (REE) approved that ash and sulfur contents only enlarge the correlation and have little effect on the accuracy. Furthermore, the REE showed that the temperature effect on biomass heat capacity was stronger than on the crystallinity index. Consequently, a new three-parameter correlation utilizing crystallinity index and temperature was developed. This model was more straightforward than the five-parameter correlation and provided better predictions (AARD = 0.98%). The proposed three-parameter correlation predicted the heat capacity of four different biomass classes with residual errors between −0.02 to 0.02 J/g∙K. The literature related biomass Cp to temperature using quadratic and linear correlations, and ignored the effect of the chemistry of the samples. These quadratic and linear correlations predicted the biomass Cp of the available database with an AARD of 39.19% and 1.29%, respectively. Our proposed model was the first work incorporating sample chemistry in biomass Cp estimation.

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Section: Introductionmentioning

confidence: 99%

Introducing a Linear Empirical Correlation for Predicting the Mass Heat Capacity of Biomaterials

et al. 2022

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“…In the academic and industrial fields, extensive attention has been attracted to the development of diverse solid sorbents towards efficient CO 2 capture, [4] including but not limited to porous organic polymers (POPs), [5] metal‐organic frameworks (MOFs), [6] carbon‐related materials, [7] modified silica, [8] zeolites, [9] and metal oxides [10] . Among those categories, carbon materials, such as activated carbon, mesoporous carbon, carbon nanofiber, and carbon nanotubes, which could be derived from different carbon precursors (e. g., biomass, biochar, polymer, ionic liquids, and MOFs) and synthesized via various thermal treatment procedures, have been widely deployed in post‐combustion CO 2 capture [11–17] . In order to improve the CO 2 capture capacity of the carbon materials, extensive studies have been conducted via strategies such as heteroatoms‐doping (e. g., O, N, F, or S), [18] inorganic base activation (e. g., NaOH, KOH, NaNH 2 ), [19] utilization of templates during the preparation process, [20–21] and anchoring CO 2 ‐philic functionalities on the surface, [17] aiming at increasing the surface areas, tuning the porosity distributions, and enhancing the interaction strength with CO 2 .…”

Section: Introductionmentioning

confidence: 99%

“…[10] Among those categories, carbon materials, such as activated carbon, mesoporous carbon, carbon nanofiber, and carbon nanotubes, which could be derived from different carbon precursors (e. g., biomass, biochar, polymer, ionic liquids, and MOFs) and synthesized via various thermal treatment procedures, have been widely deployed in post-combustion CO 2 capture. [11][12][13][14][15][16][17] In order to improve the CO 2 capture capacity of the carbon materials, extensive studies have been conducted via strategies such as heteroatoms-doping (e. g., O, N, F, or S), [18] inorganic base activation (e. g., NaOH, KOH, NaNH 2 ), [19] utilization of templates during the preparation process, [20][21] and anchoring CO 2 -philic functionalities on the surface, [17] aiming at increasing the surface areas, tuning the porosity distributions, and enhancing the interaction strength with CO 2 . For example, the carbon spheres being obtained by the KOH activation pathway exhibited abundant small micropores (< 0.8 nm), high surface area (2400 m 2 g À 1 ), and promising CO 2 uptake capacity up to 8.9 mmol g À 1 at 273 K and CO 2 pressure of 1 bar.…”

Section: Introductionmentioning

confidence: 99%

Enhanced Carbon Capture Behavior of Carbon Fibers via Ionic Liquid Modification

et al. 2022

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Carbon-based materials are widely deployed in carbon capture but are only limited to physisorption procedures. Further extending functionalized carbon materials to CO 2 chemisorption under low CO 2 concentration is highly desirable yet challenging. Herein, a carbon fiber composed of solely ultra-micropores (~0.45 nm) was deployed as the precursor to avoid the pore blocking effect, which was modified by superbase-derived ionic liquids (ILs) containing strong interaction sites with CO 2 . By forming a thin coating layer on the surface, the as-afforded surfacefunctionalized fiber materials demonstrated enhanced CO 2 uptake capacity and improved CO 2 sorption kinetics, as evaluated by both the volumetric method and thermogravimetric analysis, as well as the calculated energy distribution curves. The achievements made in this work provide guidance on the functionalization of carbon-based materials towards enhanced CO 2 chemisorption by forming a thin layer of selected IL coating.

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“…Separation technologies, like ionic liquid-based 1 , 2 and microvaiwe assisted 3 absorption, adsorption 4 – 7 , membrane 8 , circulating purification 9 , and fluidizedization 10 – 12 have a wide ranges of application in different applications. The distillation column is likely the most well-known process to separate either feedstock and product stream by considering the relative volatility 13 – 15 .…”

Section: Introductionmentioning

confidence: 99%

Employing computational fluid dynamics technique for analyzing the PACK-1300XY with methanol and isopropanol mixture

Cao

Dhahad

Khandakar

et al. 2022

Sci Rep

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In this study, an innovative wire gauze structured packing, namely PACK-1300XY with a specific surface area of 1300 m2/m3 has been characterized by performing computational fluid dynamics (CFD) approach. Indeed, different features of this packing (height equivalent to a theoretical plate, wet/dry pressure drop, and mass transfer efficiency) were analyzed by analyzing the flow regime using the three-dimensional CFD approach with the Eulerian–Eulerian multiphase scenario. The results showed the mean relative deviation of 16% (for wet pressure drop), 14% (for dry pressure drop), and 17% (for mass transfer efficiency) between the CFD predictions and experimental measurements. These excellent levels of consistency between the numerical findings and experimental observations approve the usefulness of the CFD-based approach for reliable simulation of separation processes.

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Biomass/Biochar carbon materials for CO2 capture and sequestration by cyclic adsorption processes: A review and prospects for future directions

Cited by 113 publications

References 288 publications

Introducing a Linear Empirical Correlation for Predicting the Mass Heat Capacity of Biomaterials

Introducing a Linear Empirical Correlation for Predicting the Mass Heat Capacity of Biomaterials

Enhanced Carbon Capture Behavior of Carbon Fibers via Ionic Liquid Modification

Employing computational fluid dynamics technique for analyzing the PACK-1300XY with methanol and isopropanol mixture

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