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3. Adsorption and photocatalytic degradation performances of TiO2/diatomite composite for volatile organic compounds: Effects of key parameters

Author

G Zhang, Y Liu, Z Hashisho, Z Sun, S Zheng, L Zhong

Abstract

The TiO2/diatomite composites with excellent adsorption and photo-degradation performances were leveraged to investigate the influences of calcination temperature and operating factors on their properties. The results showed that the calcination temperature was closely bound up with the crystallization of TiO2 and the specific surface area of composite. The composite with calcination temperature of 550 °C exhibited enhanced photocatalytic owing to the high surface area and small TiO2 crystallite size. A series of dynamic degradation experiments were conducted to investigate the effect of various operating parameters on acetone and p-xylene adsorption/degradation performances of the composite. The results illustrated that when the relative humidity (0–70%), gas flow rate (1–4 L/min), and VOC concentration (10–40 ppm) were set as the low values, the high total organic carbon degradation rate could be acquired. The total organic carbon degradation rate reached to a high value when the composite dosage was 3.76 mg/cm2. With the increase of light intensity (0.48–1.33 mW/cm2), the total organic carbon degradation rate presented an upward trend and then kept stable. The absorbent photocatalyst hybrid TiO2/diatomite composite could be the promising VOC purification materials.

Published
2023
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9. Satellite Remote Sensing of Air Quality in the Oil Sands Region

Author

Fu, L., Marey, H.S., and Hashisho, Z.

Subjects
Oil Sands, Remote Sensing, Carbon Monoxide, Tar Sands, Monitoring, Forest fires, OSRIN, TR-49, Air Quality, Alberta
Abstract

The rapid expansion of oil sands activities and massive energy requirements to extract and upgrade the bitumen have led to a need for more comprehensive understanding of their potential environmental impacts, particularly on air quality. There are many oil sands developments and natural sources (point, area and mobile) that generate significant emissions, including nitrogen (NO2) and sulphur oxides (SO2), carbon monoxide (CO), and particulate matter. These chemicals are known to affect human health and climate. Thus an environmental monitoring program that measures the ambient air quality is needed to understand air pollutant emissions, their chemical transformation in the atmosphere, long‐range transport and subsequent deposition to the local and regional environment. Several studies have been conducted to understand the impact of the oil sands projects on the air quality over Alberta using ground-based measurements. However, data from these measurements are limited in spatial coverage as they reflect local air quality and cannot provide information about the overall regional air quality. A complementary approach to ground-based measurements is satellite-based monitoring which can provide large spatial and vertical coverage and allow monitoring of local and regional air quality. The objective of this report is to review available remote sensing technologies for monitoring and understanding the tropospheric constituents in the atmosphere, and potential use for monitoring the air quality over the oil sands region. The report includes a summary of the basic principles of remote sensing using satellites for tropospheric composition measurements; a detailed description of the instruments and techniques used for atmospheric remote sensing from space; demonstration of the key findings and results of using satellite data for air quality application; a brief summary of future missions; and, a case study to demonstrate the use of satellite data to study the impact of oil sands and other sources on carbon monoxide levels over Alberta. The science of atmospheric remote sensing has dramatically evolved over the past two decades and proved to be capable of observing a wide range of chemical species (e.g., aerosols, tropospheric O3, tropospheric NO2, CO, HCHO, and SO2) at increasingly higher spatial and temporal resolution. The integrated use of ground-based and satellite data for air quality applications has proven to be of enormous benefit to our understanding of the global distribution, sources, and trends of air pollutants. Despite the significance of using satellites in characterizations of air quality, there is limited research on using satellite-based remote sensing technology over Alberta. As satellite-based techniques now provide an essential component of observational strategies on regional and global scales, it is recommended to integrate data from satellite, and ground-based measurements as well as chemical transport models for air quality monitoring. This report provides an in depth review of the developments in the atmospheric remote sensing area that may support air quality management, policy, and decision makers at the national, and regional level to take actions to control the exposure to air pollution.

Published
2014
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13. Review of Technologies for the Characterization and Monitoring of VOCs, Reduced Sulphur Compounds and CH4

Author

Hashisho, Z., Morshed, G., and Small, C.C.

Subjects
Remote Sensing, Oil Sands, Tar Sands, Reduced Sulphur, Monitoring, OSRIN, VOC, Tailings, Methane, TR-19, Air Quality, Alberta
Abstract

The overall goal of this project is to better understand the advantages and limitations of air emission pollutant characterization and monitoring techniques from area sources. This will allow for the selection of current technologies that are most suitable for measuring fugitive emissions of air pollutants from oil sands tailings ponds. The project consists of the following tasks: Task 1: Review concentration measurement technologies for volatile organic compounds (VOCs) reduced sulphur compounds (including H2S), and CH4. Task 2: Review flux measurement technologies that are used or can be used to measure air pollutant emissions from oil sand tailing ponds. Task 1: Review concentration measurement technologies for volatile organic compounds (VOCs), reduced sulphur compounds, and CH4 Methodology A review was conducted to determine the available technologies for characterizing and measuring the flux of each of the three groups of pollutants (VOCs, reduced sulphur compounds, and CH4). The review of the technologies included the following: a short description of the technology and its operating principle; instrument sensitivity (detection limit); advantages and limitations of the technique (performance, versatility, reliability); and cost, whenever possible. Costs do not include the labour to collect samples or the costs involved in running the analyses at other laboratories, as these are variable. However, such costs should be weighed when considering the application of the different technologies. Sample collecting procedures are important as they may affect the accuracy and precision of the technologies; these techniques are generally standard and have not been focused on for this report. Technologies for VOC Characterization The technologies for VOC characterization were classified into conventional analytical technologies (based on laboratory and field techniques) and remote sensing monitoring technologies (based on field techniques). The following technologies have been reviewed and assessed: • Conventional Analytical Technologies o Flame Ionization Detection (FID) o Infrared (IR) Absorption Spectroscopy o Photo Ionization Detection (PID) o Gas Chromatography-Mass Spectrometry (GC-MS) o Proton-Transfer-Reaction Mass Spectrometry (PTR-MS) o Fourier Transform Infrared (FT-IR) Spectroscopy • Remote Sensing Monitoring Technologies o Open Path Fourier Transform Infrared (OP-FTIR) Spectroscopy o Differential Optical Absorption Spectroscopy (DOAS) o Tunable Diode Laser Absorption Spectroscopy (TDLAS) o Differential Absorption LIDAR (DIAL) o Solar Occultation Flux (SOF) Technologies for Reduced Sulphur Compound Characterization The technologies for reduced sulphur compound characterization were classified into conventional analytical technologies (based on laboratory techniques and field techniques) and remote sensing monitoring technologies (based on field techniques). The following technologies have been reviewed and assessed: • Conventional Analytical Technologies o Flame Photometric Detection (FPD) o Pulsed Flame Photometric Detection (PFPD) o Sulphur Chemiluminescence Detection (SCD) o Photo Ionization Detectors (PID) o Ultraviolet (UV) Spectrometric Detection • Remote Sensing Monitoring Technologies o Tunable Diode Laser Absorption Spectroscopy (TDLAS) o Image Multi-Spectral Sensing (IMSS) o Differential Absorption LIDAR (DIAL) o Open Path Fourier Transform Infrared (OP- FTIR) Spectroscopy Technologies for CH4 Characterization The technologies for CH4 characterization were classified into conventional analytical technologies (based on laboratory and field techniques) and remote sensing monitoring technologies (based on field techniques). The following technologies have been reviewed and assessed: • Conventional Analytical Technologies o Infrared (IR) Absorption o Mid-Infrared Polarization Spectroscopy o Photoacoustic Absorption Spectroscopy (PAS) o Solid State (SS) sensor o Wavelength Modulation Spectroscopy (WMS) • Remote Sensing Monitoring Technologies o Radial Plume Mapping (RPM) o Differential Optical Absorption Spectroscopy (DOAS) o Correlation Spectroscopy (CS) o Airborne Natural Gas Emission Lidar (ANGEL) Task 2: Review flux measurement technologies that are used or can be used to measure emissions from air pollutant emissions and greenhouse gases from oil sand tailing ponds. The technologies for measuring concentration fluxes of fugitive emissions within the atmosphere were also classified into conventional analytical techniques and remote sensing monitoring technologies (all based on field techniques). The following technologies have been reviewed and assessed: • Conventional Analytical Techniques o Chamber Methods o Eddy Covariance (EC) o Eddy Accumulation and Relaxed Eddy Accumulation o Flux Gradient Techniques o Mass Balance Techniques o Tracer Gas Method • Remote Sensing Monitoring Technologies o Solar Occultation Flux (SOF) o Nocturnal Boundary Layer Box Method o Radial Plume Mapping (RPM) The report concludes with recommendations for technologies to use for monitoring air emissions from oil sands tailings ponds based on the following factors: spatial coverage, quantification of the pollutants, determination of emission factor, characterization of VOC speciation, and frequency of monitoring. For a variety of reasons there may not be one technology that is best suited for emission measurements across the oil sands region, and it is important to understand the different advantages and limitations of the technologies when selecting an option and interpreting the resulting data.

Published
2012
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16. Physical and Chemical Properties of Pan-Derived Electrospun Activated Carbon Nanofibers and Their Potential for Use As An Adsorbent for Toxic Industrial Chemicals (Postprint)

Author

ILLINOIS UNIV AT URBANA-CHAMPAIGN, Sullivan, P, Moate, J, Stone, B, Atkinson, J D, Rood, M J, Hashisho, Z, ILLINOIS UNIV AT URBANA-CHAMPAIGN, Sullivan, P, Moate, J, Stone, B, Atkinson, J D, Rood, M J, and Hashisho, Z

Abstract

A recently developed carbon material, electrospun Activated Carbon nanoFiber (ACnF), exhibits strong potential for use as an adsorbent for toxic industrial chemicals (TICs). As-prepared ACnF contains as much as 9.6 wt% nitrogen, creating a basic surface that enhances acid-gas adsorption. ACnF shows 4-20 times greater HCN adsorption capacities and 2-5 times greater SO2 adsorption capacities in dry nitrogen, compared to commercially available activated carbon fiber cloth (ACFC) and Calgon BPL(trademark) granular activated carbon, which are considered here as reference adsorbents. ACnF has 50 % of the micropore volume (0.30 cm3/g) of these reference adsorbents, which limits its adsorption capacity at high concentrations for volatile organic compounds (500 ppmv). However, at low concentrations (500 ppmv), ACnF has a similar capacity to ACFC and about three times the VOC adsorption capacity of Calgon BPL(trademark). ACnF's small fiber diameters (0.2-1.5 microns) allow for higher mass transfer coefficients, resulting in adsorption kinetics nearly twice as fast as ACFC and eight times as fast as Calgon BPL(trademark). ACnF drawbacks include hydrophilicity and reduced structural strength. The rapid adsorption kinetics and high capacity for acidic TICs warrant further investigation of ACnF as an adsorbent in respiratory protection and indoor air quality applications., Published in Adsorption, v18 p265-274, 2012.

Published
2012

20. Spatial and temporal variation of CO over Alberta using measurements from satellite, aircrafts, and ground stations.

Author

Marey, H. S., Hashisho, Z., Fu, L., and Gille, J.

Abstract

Alberta is Canada's largest oil producer and its oil sand deposits comprise 30 % of the world's oil reserves. The process of bitumen extraction and upgrading releases trace gases and aerosols to the atmosphere. In this study we present satellite-based analysis to explore, for the first time, various contributing factors that affect tropospheric carbon monoxide (CO) levels over Alberta. The multispectral product that uses both near-infrared (NIR) and the thermal-infrared (TIR) radiances for CO retrieval from the Measurements of Pollution in the Troposphere (MOPITT) are examined for the 12 year period from 2002-2013. Moderate Resolution Imaging Spectroradiometer (MODIS) thermal anomaly product from 2001 to 2013 is employed to investigate the seasonal and temporal variations of forest fires. Additionally, in situ CO measurements at industrial and urban sites are compared to satellite data. Furthermore, the available MOZAIC/IAGOS (Measurement of Ozone, Water Vapor, Carbon Monoxide, Nitrogen Oxide by Airbus In-Service Aircraft/In service Aircraft for Global Observing System) aircraft CO profiles (April 2009-December 2011) are used to validate MOPITT CO data. The climatological time curtain plot and spatial maps for CO over northern Alberta indicate the signatures of transported CO for two distinct biomass burning seasons, summer and spring. Distinct seasonal patterns of CO at the urban site s (Edmonton and Calgary cities) point to the strong influence of traffic. Meteorological parameters play an important role on the CO spatial distribution at various pressure levels. Northern Alberta shows stronger upward lifting motion which leads to larger CO total column values while the poor dispersion in central and south Alberta exacerbate s the surface CO pollution. Inter-annual variations of satellite data depict a slightly decreasing trend for both regions while the decline trend is more evident from ground observations, especially at the urban sites. MOPITT CO vertical averages and MOZAIC/IAGOS aircraft profiles were in good agreement within the standard deviation at all pressure levels. There is consistency between the time evolution of high CO episodes monitored by satellite and ground measurements and the fire frequency peak time which implies that biomass burning has affected the tropospheric CO distribution in northern Alberta. These findings have further demonstrated the potential use of MOPITT V5 multispectral (NIR+TIR) product for assessing a complicated surface process. [ABSTRACT FROM AUTHOR]

Published
2014
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22. Evaluation of masks and mask material suitability for bioaerosol capture.

Author

Peyravi A, Quecke E, Kosareva E, Dolez P, Doroshenko A, Smith S, Quemerais B, and Hashisho Z

Subjects
Humans, Aerosols analysis, N95 Respirators, Materials Testing methods, Occupational Exposure prevention & control, Occupational Exposure analysis, Respiratory Protective Devices standards, Respiratory Aerosols and Droplets, Masks standards, SARS-CoV-2, COVID-19 prevention & control, COVID-19 transmission, Filtration instrumentation, Textiles
Abstract

Non-medical masks such as disposable non-medical, commercially produced cloth, and homemade masks are not regulated like surgical masks. Their performance, in terms of filtration efficiency and breathability, is variable and unreliable. This research provides a quantitative evaluation of various non-medical masks, assesses their fabrics' potential for the reduction of transmission of bioaerosols such as the SARS-CoV-2 virus, and compares them to surgical masks and N95 filtering facepiece respirators. Using a testing line with a NaCl challenge aerosol, four types of commercial reusable cloth masks, two types of disposable non-medical masks, three types of surgical or N95 masks, and seven types of commonly available materials were tested individually and in combinations. The testing line and procedure were adapted from the ASTM F2299-03: Standard Test Method for Determining the Initial Efficiency of Materials Used in Medical Face Masks to Penetration by Particulates Using Latex Spheres testing method used for testing surgical masks. Filtration efficiencies at 0.15 µm particle diameter at a face velocity of 25 cm/sec for commercial cloth masks, disposable non-medical masks, surgical masks, commercial mask combinations, and homemade combinations ranged from 16-29%, 39-76%, 91-97%, 51-95%, and 45-94%, respectively. The pressure drop results for the different masks and material combinations were all under 3 mm H 2 O/cm 2 except for one material configuration. This study builds on other research that looks at individual materials and masks by testing combinations alongside the individual masks and materials. With proper layering, household materials can achieve the filtration efficiency and low pressure drop requirements of surgical masks. The filtration capabilities of disposable and cloth mask fabrics vary considerably meaning that they are not a reliable or consistent facemask option, regardless of fit.

Published
2024
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23. Simultaneous effect of oxygen impurity and flow rate of purge gas on adsorption capacity of and heel buildup on activated carbon during cyclic adsorption-desorption of VOC.

Author

Rahmani K, Haghighat Mamaghani A, Peyravi A, Hashisho Z, Crompton D, and Anderson JE

Abstract

Irreversible adsorption, or heel buildup, negatively impacts activated carbon performance and shortens its lifetime. This study elucidates the interconnections between flow rate and the oxygen impurity of desorption purge gas with heel buildup on beaded activated carbon (BAC). Nine thermal desorption scenarios were explored, varying nitrogen purge gas oxygen impurity levels (<5 ppmv, 10,000 ppmv, 210,000 ppm (21 %)) and flow rates (0.1, 1, 10 SLPM or 1 %, 10 %, 100 % of adsorption flow rate) during thermal desorption. Results reveal that increasing purge gas flow rate improves adsorption capacity recovery and mitigates adverse effects of purge gas oxygen impurity. Cumulative heel increased with higher purge gas oxygen impurity and lower flow rates. In the least effective regeneration scenario (0.1 SLPM N 2 , 21 % O 2 ), a 32.8 wt% cumulative heel formed on BAC after five cycles, while the best-case scenario (10 SLPM N 2 , <5 ppmv O 2 ) resulted in only 0.3 wt%. Comparing the pore size distributions of virgin and used BAC shows that heel initially forms in narrow micropores (<8.5Å) and later engages mesopores. Thermogravimetric analysis (TGA) showed that oxygen impurity creates high boiling point and/or strongly bound heel species. TGA confirmed that higher purge gas flow rates reduce heel amounts but encourage chemisorbed heel formation in oxygen's presence. These findings can guide optimization of regeneration conditions, enhancing activated carbon's long-term performance in cyclic adsorption processes., Competing Interests: Declaration of Competing Interest The authors declare the following financial interests/personal relationships which may be considered as potential competing interests Zaher Hashisho reports financial support was provided by Ford Motor Company., (Copyright © 2024. Published by Elsevier B.V.)

Published
2024
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25. Effect of microstructure in mesoporous adsorbents on the adsorption of low concentrations of VOCs: An experimental and simulation study.

Author

Liu Y, Peyravi A, Dong X, Hashisho Z, Zheng S, Chen X, Gao D, Hao Y, Tong Y, and Wang J

Abstract

This study evaluated the adsorption of five volatile organic compounds (VOCs) on Opoka, precipitated silica, and palygorskite, to elucidate the effect of their pore size on VOCs adsorption. The adsorption capacity of these adsorbents is not only highly correlated with their surface area and pore volume, but also notably improved by the presence of micropores. The variation in adsorption capacity for different VOCs was primarily influenced by their boiling point and polarity. Palygorskite, which had the smallest total pore volume (0.357 cm 3 /g) but the largest micropore volume (0.043 cm 3 /g) among the three adsorbents, exhibited the highest adsorption capacity for all tested VOCs. Additionally, the study constructed slit pore models of palygorskite with micropores (0.5 and 1.5 nm) and mesopores (3.0 and 6.0 nm), calculated and discussed the heat of adsorption, concentration distribution, and interaction energy of VOCs adsorbed on different pore models. The results revealed that the adsorption heat, concentration distribution, total interaction energy, and van der Waals energy decrease with increasing pore size. The concentration of VOCs in 0.5 nm pore was nearly three times that in 6.0 nm pore. This work can also provide guidance for further research on using adsorbents with mixed microporous and mesoporous structures to control VOCs., Competing Interests: Declaration of Competing Interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2023 Elsevier B.V. All rights reserved.)

Published
2023
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26. Review of welding fume emission factor development.

Author

Quecke E, Quemerais B, and Hashisho Z

Subjects
Humans, Metals analysis, Gases, Air Pollutants, Occupational analysis, Occupational Exposure analysis, Welding methods
Abstract

The fumes created from welding activities present a unique occupational hazard. Due to the complex processes which govern fume formation, the characterization of welding fumes is difficult. Emission factors (EFs) are one method to characterize fume formation from different processes and scenarios. This paper reviews the development of EFs and similar metrics both historic research which contributed to the US EPAs AP-42 summary of welding emission factors released in 1995, and more recent research initiatives. Through a critical analysis of what research has been done in this area and the strength of the emission factors developed, this paper proposes a set of recommendations for future research. Research on emission factors for gas metal arc welding (GMAW) is the most complete amongst the different types of electric arc welding. Despite it being generally known that flux core arc welding (FCAW) creates significant fume emissions compared to some of the other processes few studies have looked at FCAW since the AP-42. Shielded metal arc welding is also under-researched particularly in terms of metal-specific emission factors. The influence of different welding activity parameters such as welding location, speed or current is well defined for GMAW but requires more attention for other welding processes. Further effort towards compiling and comparing available emission factor data of quality, evaluating the available data statistically and organizing this data in a practically useful way is required. The availability of reliable emission factors will allow the development or improvement of exposure modelling tools that would be very useful for exposure assessment when monitoring is not practical.s., (© The Author(s) 2023. Published by Oxford University Press on behalf of the British Occupational Hygiene Society.)

Published
2023
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29. Graphene oxide enhances thermal stability and microwave absorption/regeneration of a porous polymer.

Author

Peyravi A, Ahmadijokani F, Arjmand M, and Hashisho Z

Abstract

Microwave regeneration of adsorbents offers several advantages over conventional regeneration methods; however, its application for microwave transparent adsorbents such as polymers is challenging. In this study, hypercrosslinked polymer/graphene oxide (GO) nanocomposites with large surface area and enhanced microwave absorption ability were synthesized. Polymers of 4, 4´-bis ((chloromethyl)-1, 1´-biphenyl- benzyl chloride) were hypercrosslinked through the Friedel-Crafts reactions. GO sheets were synthesized through the Hummer's method. Nanocomposites with different GO contents (1-8 wt%) were synthesized by solution mixing method. Thermogravimetry analysis revealed a large enhancement in the thermal stability of GO-filled nanocomposites compared to pristine polymer. N 2 adsorption isotherm analysis showed 7% and 10% reduction in BET surface area and total pore volume of the nanocomposite with 8 wt% GO. Compared to the pristine polymer, the dielectric constant and dielectric loss factor increased from 5 to 17 and 0.05-1.6, respectively, for the nanocomposites with 8 wt% GO. Microwave-assisted desorption of toluene from samples revealed more than 160 ºC and 4 times improvement in the desorption temperature and desorption efficiency, respectively, by addition of 4 wt% GO to the polymer. This study showed the important role of GO addition for efficient microwave-assisted regeneration of polymer adsorbents., (Copyright © 2022 Elsevier B.V. All rights reserved.)

Published
2022
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30. Prediction of heel build-up on activated carbon using machine learning.

Author

Rahmani K, Mamaghani AH, Hashisho Z, Crompton D, and Anderson JE

Subjects
Adsorption, Machine Learning, Charcoal, Volatile Organic Compounds
Abstract

Determining the long-term performance of adsorbents is crucial for the design of air treatment systems. Heel buildup i.e., the accumulation of non-desorbed/ non-desorbable adsorbates and their reaction byproducts, on the surface/pores of the adsorbent is a primary cause of adsorption performance deterioration. However, due to the complexity of heel buildup mechanisms, theoretical models have yet to be developed to map the extent of heel buildup to the adsorption/desorption parameters. In this work, two machine learning (ML) algorithms (XGBoost and neural network (NN)) were applied to predict volatile organic compounds (VOCs) cyclic heel buildup on activated carbons (ACs) by considering the adsorbent characteristics, adsorbate properties and regeneration conditions. The NN algorithm showed better performance in prediction of cyclic heel buildup (R 2 = 0.94) than XGBoost (R 2 = 0.81). To analyze interaction between heel buildup and adsorbent characteristics, adsorbate properties, and regeneration conditions, partial dependency plots were generated. The proposed ML-based heel prediction methods can be ultimately used to: (i) optimize adsorption/desorption operating conditions to minimize heel buildup on activated carbon in cyclic adsorption/desorption processes and (ii) quickly screen various adsorbents for efficient adsorption/desorption of a particular family of VOCs by excluding adsorbents prone to high heel formation., (Copyright © 2022. Published by Elsevier B.V.)

Published
2022
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31. Porous carbon black-polymer composites for volatile organic compound adsorption and efficient microwave-assisted desorption.

Author

Peyravi A, Hashisho Z, Crompton D, and Anderson JE

Subjects
Adsorption, Carbon, Polymers, Porosity, Soot, Microwaves, Volatile Organic Compounds
Abstract

Adsorbents with high surface area, thermal stability and microwave absorption ability are highly desired for cyclic adsorption and microwave regeneration processes. However, most polymeric adsorbents are transparent to microwaves. Herein, porous hyper-crosslinked polymers (HCP) of (4,4'-bis((chloromethyl)-1,1'-biphenyl-benzyl chloride)) with different carbon black (CB) contents were synthesized via the Friedel-Crafts reaction. CB was selected as the filler due to its low cost and high dielectric loss and was embedded inside the polymer structure during polymerization. CB-containing composites showed enhanced thermal stability at elevated temperatures, and more than a 90-times increase in the dielectric loss factor, which is favorable for microwave regeneration. Nitrogen physisorption analysis by the Bruner-Emmett-Teller isotherms demonstrated that CB presence in the polymer structure nonlinearly decreases the surface area and total pore volume (by 38% and 26%, respectively at the highest CB load). Based on the characterization testing, 4 wt% of CB was found to be an optimum filler content, having the highest MW absorption and minimal effect on the adsorbent porosity. HCP with 4 wt% CB allowed a substantial increase in the desorption temperature and yielded more than a 450% enhancement in the desorption efficiency compared to HCP without CB., Competing Interests: Declaration of Competing Interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2021. Published by Elsevier Inc.)

Published
2022
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32. Mathematical correlations in two-phase modeling of fluidized bed adsorbers.

Author

Davarpanah M, Hashisho Z, Crompton D, and Anderson JE

Abstract

Choosing proper formulas for estimating different variables is imperative when modeling a fluidized bed using two-phase theory. In this study, a two-phase model was used to model the adsorption of volatile organic compounds (VOC) in a multistage fluidized bed adsorber. Two different approaches were used to describe gas flow and mixing in the emulsion phase, perfectly mixed (EGPM: Emulsion Gas - Perfectly Mixed) and plug flow (EGPF: Emulsion Gas - Plug flow). The impact of different formulas for estimating bubble size, bed porosity at minimum fluidization velocity, adsorption and interphase mass transfer coefficients, as well as tortuosity on the performance of the model was determined by comparing the model outcomes with experimental data. Finally, using a large dataset obtained from fluidized bed adsorption systems with different adsorbents, adsorbates, bed sizes, and operating conditions, a broadly-applicable set of formulas was suggested which could be used to describe the behavior of different countercurrent fluidized bed adsorbers. From the results, the two-phase model could successfully predict the experimental data, with EGPF showing better performance than EGPM. Proper use of formulas, especially those describing bed voidage and interphase mass transfer coefficient, could markedly improve the performance of the two-phase model. The two-phase model using the set of formulas proposed here was able to accurately replicate a large dataset of fluidized bed adsorption experiments over a wide range of operating conditions., (Copyright © 2021. Published by Elsevier B.V.)

Published
2022
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33. Mesoporous MCM-41 derived from natural Opoka and its application for organic vapors removal.

Author

Liu Y, Li C, Peyravi A, Sun Z, Zhang G, Rahmani K, Zheng S, and Hashisho Z

Abstract

Mesoporous silica MCM-41 was synthesized by a facile hydrothermal treatment using sodium silicate extracted from natural Opoka as the Si source. The dynamic adsorption and desorption of organic vapors mixture on the MCM-41 were investigated. Characterization of the textural properties of the samples showed that the sample synthesized with a molar ratio of CTAB/Si = 0.16 possessed the largest specific surface area (988 m 2 /g) and pore volume (1.02 cm 3 /g), also uniform pore size distribution centered at 2.8 nm. The adsorption capacity of this sample for organic vapors mixture improved remarkably over raw Opoka and reached 158.5 mg/g at 20 ℃, which is comparable to that of commercial activated carbon. The reusability of the adsorbent was tested by 5 adsorption and regeneration cycles. Obtained results demonstrate that the MCM-41 adsorbent can be easily regenerated by thermal desorption in air, and the cumulative heel on the adsorbent can be markedly reduced by increasing the desorption temperature, making it a promising adsorbent for VOCs abatement., (Copyright © 2020. Published by Elsevier B.V.)

Published
2021
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34. Modeling VOC adsorption in lab- and industrial-scale fluidized bed adsorbers: Effect of operating parameters and heel build-up.

Author

Davarpanah M, Hashisho Z, Crompton D, Anderson JE, and Nichols M

Abstract

Scale-up and optimization of fluidized beds are challenging due to the difficulty in accounting for the interrelated effect of various phenomena, which are typically described by empirical and/or semi-empirical equations. In this study, a two-phase model was introduced to simulate the adsorption of VOCs on beaded activated carbon (BAC) in a lab-scale fluidized bed adsorber. The model assumes the presence of a bubble phase free from adsorbent particles, and an emulsion phase composed of the adsorbent particles and interstitial gas. The versatility of the proposed model was then evaluated using data from an industrial scale adsorber with different operating conditions, adsorbent properties, and bed geometry. The response of the model to the operating conditions (adsorbent feed rate, air flow rate and initial concentration) showed better agreement with the experimental lab-scale data when the emulsion gas in two-phase model was considered in plug flow than in perfectly-mixed flow (R 2 = 0.96 compared to 0.91). To simulate the performance of BACs with different service lifetimes (degree of exhaustion as a result of heel developed inside their pores), the main characteristics of the BACs (pore diameter, porosity, and adsorption capacity) were first correlated to their apparent densities. The model could accurately predict the experimental lab-scale VOC concentrations in each stage (R 2 = 0.92) as well as overall removal efficiencies (R 2 = 0.99) for BACs ranging from virgin to fully-spent. Finally, the model was used to predict the performance of an industrial-scale fluidized bed adsorber for VOC removal at different operating conditions and apparent densities. Predicted and measured VOC removal efficiencies were in good agreement (R 2 = 0.94). Although the model was verified for adsorption of VOCs on BAC, the modeling approach presented in this study could be used for describing adsorption in different adsorbate-adsorbent systems in multistage counter-current fluidized bed adsorbers., (Copyright © 2020 Elsevier B.V. All rights reserved.)

Published
2020
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35. Modeling the Effect of Relative Humidity on Adsorption Dynamics of Volatile Organic Compound onto Activated Carbon.

Author

Laskar II, Hashisho Z, Phillips JH, Anderson JE, and Nichols M

Subjects
Adsorption, Carbon, Charcoal, Humidity, Models, Theoretical, Volatile Organic Compounds
Abstract

A two-dimensional heterogeneous mathematical model was developed and validated to study the effect of relative humidity on volatile organic compound (VOC) adsorption onto activated carbon. The dynamic adsorption model consists of the macroscopic mass, momentum, and energy conservation equations and includes a multicomponent adsorption isotherm to predict the competitive adsorption equilibria between VOC and water vapor, which is described by an extended Manes method. Experimental verifications show that the model predicted the breakthrough profiles during competitive adsorption of the studied VOCs (2-propanol, acetone, n-butanol, toluene, 1,2,4-trimethylbenzene) at relative humidity range 0-95% with an overall mean relative absolute error (MRAE) of 11.8% for dry (0% RH) conditions and 17.2% for humid (55 and 95% RH) conditions, and normalized root-mean-square error (NRMSE) of 5.5 and 8.4% for dry and humid conditions, respectively. Sensitivity analysis was also conducted to test the robustness of the model in accounting for the impact of relative humidity on VOC adsorption by varying the adsorption temperature. Good agreement was observed between the experimental and simulated results with an overall MRAE of 12.4 and 7.1% for the breakthrough profiles and adsorption capacity, respectively. The model can be used to quantify the impact of carrier gas relative humidity during adsorption of contaminants from gas streams, which is useful when optimizing adsorber design and operating conditions.

Published
2019
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36. Adsorption of volatile organic compounds onto natural porous minerals.

Author

Zhang G, Liu Y, Zheng S, and Hashisho Z

Abstract

The abundance of natural porous minerals and their low cost make them the potential adsorbents for VOCs (volatile organic compounds). In this paper, three natural minerals (diatomite, stellerite and vitric tuff) and their corresponding acid-treated minerals were used as adsorbents. The adsorption performances of minerals were investigated by the adsorption breakthrough curves of VOCs. The results indicated that the properties of organic compounds such as boiling point and polarity and the surface area and pore volume of minerals had obvious effects on the adsorption of VOCs over minerals. Increasing adsorption temperature and relative humidity would have negative effects on the VOC adsorption of minerals. The adsorption capacity of 2-heptanone over acid stellerite decreased by 7.2% as the temperature rose from 25°C to 45°C. The adsorption capacity of acid stellerite for 2-heptanone reduced by 60.9% when relative humidity increased from 0% to 75%. Minerals were tested for five adsorption-regeneration cycles to study the reusability. Better fittings of Thomas model, pseudo-first order kinetics model, and Freundlich model were showed in fitting the adsorption. Overall, porous minerals with high specific surface area and pore volume have promising prospect in VOCs adsorption., (Copyright © 2018 Elsevier B.V. All rights reserved.)

Published
2019
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37. Effect of naphtha diluent on greenhouse gases and reduced sulfur compounds emissions from oil sands tailings.

Author

Gee KF, Poon HY, Hashisho Z, and Ulrich AC

Abstract

The long-term storage of oil sands tailings has resulted in the evolution of greenhouse gases (CH 4 and CO 2 ) as a result of residual organics biodegradation. Recent studies have identified black, sulfidic zones below the tailings-water interface, which may be producing toxic sulfur-containing gases. An anaerobic mesocosm study was conducted over an 11-week period to characterize the evolution of CH 4 , CO 2 and reduced sulfur compounds (RSCs) (including H 2 S) in tailings as it relates to naphtha-containing diluent concentrations (0.2, 0.8, and 1.5% w/v) and microbial activity. Our results showed that RSCs were produced first at 0.12μmol°RSCs/mL MFT (1.5% w/v diluent treatment). RSCs contribution (from highest to lowest) was H 2 S and 2-methylthiophene>2.5-dimethylthiophene>3-methylthiophene>thiofuran>butyl mercaptan>carbonyl sulfide, where H 2 S and 2-methylthiophene contributed 81% of the gas produced. CH 4 and CO 2 production occurred after week 5 at 40.7μmolCH 4 /mL MFT and 5.9μmolCO 2 /mL MFT (1.5% w/v diluent treatment). The amount of H 2 S and CH 4 generated is correlated to the amount of diluent present and to microbial activity as shown by corresponding increases in sulfate-reducers' Dissimilatory sulfite reductase (DsrAB) gene and methanogens' methyl-coenzyme M reductase (MCR) gene., (Copyright © 2017 Elsevier B.V. All rights reserved.)

Published
2017
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38. Autonomous mobile platform for monitoring air emissions from industrial and municipal wastewater ponds.

Author

Fu L, Huda Q, Yang Z, Zhang L, and Hashisho Z

Subjects
Alberta, Carbon Dioxide analysis, Carbon Dioxide chemistry, Environmental Monitoring instrumentation, Methane analysis, Methane chemistry, Oil and Gas Fields, Volatile Organic Compounds chemistry, Air Pollutants analysis, Environmental Monitoring methods, Ponds chemistry, Volatile Organic Compounds analysis, Wastewater chemistry
Abstract

Significant amounts of volatile organic compounds and greenhouse gases are generated from wastewater lagoons and tailings ponds in Alberta, Canada. Accurate measurements of these air pollutants and greenhouse gases are needed to support management and regulatory decisions. A mobile platform was developed to measure air emissions from tailings pond in the oil sands region of Alberta. The mobile platform was tested in 2015 in a municipal wastewater treatment lagoon. With a flux chamber and a CO 2 /CH 4 sensor on board, the mobile platform was able to measure CO 2 and CH 4 emissions over two days at two different locations in the pond. Flux emission rates of CO 2 and CH 4 that were measured over the study period suggest the presence of aerobic and anaerobic zones in the wastewater treatment lagoon. The study demonstrated the capabilities of the mobile platform in measuring fugitive air emissions and identified the potential for the applications in air and water quality monitoring programs., Implications: The Mobile Platform demonstrated in this study has the ability to measure greenhouse gas (GHG) emissions from fugitive sources such as municipal wastewater lagoons. This technology can be used to measure emission fluxes from tailings ponds with better detection of spatial and temporal variations of fugitive emissions. Additional air and water sampling equipment could be added to the mobile platform for a broad range of air and water quality studies in the oil sands region of Alberta.

Published
2017
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39. A Novel Technique for Determining the Adsorption Capacity and Breakthrough Time of Adsorbents Using a Noncontact High-Resolution Microwave Resonator Sensor.

Author

Fayaz M, Zarifi MH, Abdolrazzaghi M, Shariaty P, Hashisho Z, and Daneshmand M

Subjects
Adsorption, Benzene, Polymers, Charcoal, Microwaves
Abstract

A newly developed noncontact high-resolution real-time microwave sensor was used to determine the breakthrough time and adsorption capacity of adsorbents/adsorbates with different dielectric properties. The sensor is a microwave microstrip planar resonator with an enhanced quality factor using a regenerative feedback loop operating at 1.4 GHz and an adjustable quality factor of 200-200000. Beaded activated carbon (BAC, microwave-absorbing) and a polymeric adsorbent (V503, microwave transparent) were completely loaded with 1,2,4-trimethylbenzene (nonpolar) or 2-butoxyethanol (polar). During adsorption, variations in the dielectric properties of the adsorbents were monitored using two microwave parameters; quality factor and resonant frequency. Those parameters were related to adsorption breakthrough time and capacity. Adsorption tests were completed at select relative pressures (0.03, 0.1, 0.2, 0.4, and 0.6) of adsorbates in the influent stream. For all experiments, the difference between the breakthrough time (t 5% ) and the settling time of the quality factor variation (time that the quality factor was 0.95 of its final value) was <5%. Additionally, a linear relationship between the final value of the resonant frequency shift and adsorption capacity was observed. The proposed noncontact sensor can be used to determine the breakthrough time and adsorption capacity.

Published
2017
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40. The role of beaded activated carbon's surface oxygen groups on irreversible adsorption of organic vapors.

Author

Jahandar Lashaki M, Atkinson JD, Hashisho Z, Phillips JH, Anderson JE, and Nichols M

Abstract

The objective of this study is to determine the contribution of surface oxygen groups to irreversible adsorption (aka heel formation) during cyclic adsorption/regeneration of organic vapors commonly found in industrial systems, including vehicle-painting operations. For this purpose, three chemically modified activated carbon samples, including two oxygen-deficient (hydrogen-treated and heat-treated) and one oxygen-rich sample (nitric acid-treated) were prepared. The samples were tested for 5 adsorption/regeneration cycles using a mixture of nine organic compounds. For the different samples, mass balance cumulative heel was 14 and 20% higher for oxygen functionalized and hydrogen-treated samples, respectively, relative to heat-treated sample. Thermal analysis results showed heel formation due to physisorption for the oxygen-deficient samples, and weakened physisorption combined with chemisorption for the oxygen-rich sample. Chemisorption was attributed to consumption of surface oxygen groups by adsorbed species, resulting in formation of high boiling point oxidation byproducts or bonding between the adsorbates and the surface groups. Pore size distributions indicated that different pore sizes contributed to heel formation - narrow micropores (<7Å) in the oxygen-deficient samples and midsize micropores (7-12Å) in the oxygen-rich sample. The results from this study help explain the heel formation mechanism and how it relates to chemically tailored adsorbent materials., (Copyright © 2016 Elsevier B.V. All rights reserved.)

Published
2016
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41. The role of beaded activated carbon's pore size distribution on heel formation during cyclic adsorption/desorption of organic vapors.

Author

Jahandar Lashaki M, Atkinson JD, Hashisho Z, Phillips JH, Anderson JE, and Nichols M

Abstract

The effect of activated carbon's pore size distribution (PSD) on heel formation during adsorption of organic vapors was investigated. Five commercially available beaded activated carbons (BAC) with varying PSDs (30-88% microporous) were investigated. Virgin samples had similar elemental compositions but different PSDs, which allowed for isolating the contribution of carbon's microporosity to heel formation. Heel formation was linearly correlated (R(2)=0.91) with BAC micropore volume; heel for the BAC with the lowest micropore volume was 20% lower than the BAC with the highest micropore volume. Meanwhile, first cycle adsorption capacities and breakthrough times correlated linearly (R(2)=0.87 and 0.93, respectively) with BAC total pore volume. Micropore volume reduction for all BACs confirmed that heel accumulation takes place in the highest energy pores. Overall, these results show that a greater portion of adsorbed species are converted into heel on highly microporous adsorbents due to higher share of high energy adsorption sites in their structure. This differs from mesoporous adsorbents (low microporosity) in which large pores contribute to adsorption but not to heel formation, resulting in longer adsorbent lifetime. Thus, activated carbon with high adsorption capacity and high mesopore fraction is particularly desirable for organic vapor application involving extended adsorption/regeneration cycling., (Copyright © 2016 Elsevier B.V. All rights reserved.)

Published
2016
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42. Automotive Wastes.

Author

Guigard SE, Shariaty P, Niknaddaf S, Lashaki MJ, Atkinson JD, and Hashisho Z

Abstract

A review of the literature from 2014 related to automotive wastes is presented. Topics include solid wastes from autobodies and tires as well as vehicle emissions to soil and air as a result of the use of conventional and alternative fuels. Potential toxicological and health risks related to automotive wastes are also discussed.

Published
2015
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43. Using microwave heating to improve the desorption efficiency of high molecular weight VOC from beaded activated carbon.

Author

Fayaz M, Shariaty P, Atkinson JD, Hashisho Z, Phillips JH, Anderson JE, and Nichols M

Subjects
Alkanes chemistry, Charcoal chemistry, Heating, Microwaves, Volatile Organic Compounds chemistry
Abstract

Incomplete regeneration of activated carbon loaded with organic compounds results in heel build-up that reduces the useful life of the adsorbent. In this study, microwave heating was tested as a regeneration method for beaded activated carbon (BAC) loaded with n-dodecane, a high molecular weight volatile organic compound. Energy consumption and desorption efficiency for microwave-heating regeneration were compared with conductive-heating regeneration. The minimum energy needed to completely regenerate the adsorbent (100% desorption efficiency) using microwave regeneration was 6% of that needed with conductive heating regeneration, owing to more rapid heating rates and lower heat loss. Analyses of adsorbent pore size distribution and surface chemistry confirmed that neither heating method altered the physical/chemical properties of the BAC. Additionally, gas chromatography (with flame ionization detector) confirmed that neither regeneration method detectably altered the adsorbate composition during desorption. By demonstrating improvements in energy consumption and desorption efficiency and showing stable adsorbate and adsorbent properties, this paper suggests that microwave heating is an attractive method for activated carbon regeneration particularly when high-affinity VOC adsorbates are present.

Published
2015
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44. Modeling competitive adsorption of mixtures of volatile organic compounds in a fixed-bed of beaded activated carbon.

Author

Tefera DT, Hashisho Z, Philips JH, Anderson JE, and Nichols M

Subjects
Adsorption, Charcoal chemistry, Complex Mixtures chemistry, Models, Chemical, Volatile Organic Compounds chemistry
Abstract

A two-dimensional mathematical model was developed to study competitive adsorption of n-component mixtures in a fixed-bed adsorber. The model consists of an isotherm equation to predict adsorption equilibria of n-component volatile organic compounds (VOCs) mixture from single component isotherm data, and a dynamic adsorption model, the macroscopic mass, energy and momentum conservation equations, to simulate the competitive adsorption of the n-components onto a fixed-bed of adsorbent. The model was validated with experimentally measured data of competitive adsorption of binary and eight-component VOCs mixtures onto beaded activated carbon (BAC). The mean relative absolute error (MRAE) was used to compare the modeled and measured breakthrough profiles as well as the amounts of adsorbates adsorbed. For the binary and eight-component mixtures, the MRAE of the breakthrough profiles was 13 and 12%, respectively, whereas, the MRAE of the adsorbed amounts was 1 and 2%, respectively. These data show that the model provides accurate prediction of competitive adsorption of multicomponent VOCs mixtures and the competitive adsorption isotherm equation is able to accurately predict equilibrium adsorption of VOCs mixtures.

Published
2014
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45. Two-dimensional modeling of volatile organic compounds adsorption onto beaded activated carbon.

Author

Tefera DT, Jahandar Lashaki M, Fayaz M, Hashisho Z, Philips JH, Anderson JE, and Nichols M

Subjects
Adsorption, Benzene analysis, Gases chemistry, Particle Size, Pressure, Temperature, Charcoal chemistry, Models, Theoretical, Volatile Organic Compounds analysis
Abstract

A two-dimensional heterogeneous computational fluid dynamics model was developed and validated to study the mass, heat, and momentum transport in a fixed-bed cylindrical adsorber during the adsorption of volatile organic compounds (VOCs) from a gas stream onto a fixed bed of beaded activated carbon (BAC). Experimental validation tests revealed that the model predicted the breakthrough curves for the studied VOCs (acetone, benzene, toluene, and 1,2,4-trimethylbenzene) as well as the pressure drop and temperature during benzene adsorption with a mean relative absolute error of 2.6, 11.8, and 0.8%, respectively. Effects of varying adsorption process variables such as carrier gas temperature, superficial velocity, VOC loading, particle size, and channelling were investigated. The results obtained from this study are encouraging because they show that the model was able to accurately simulate the transport processes in an adsorber and can potentially be used for enhancing absorber design and operation.

Published
2013
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46. Effect of the adsorbate kinetic diameter on the accuracy of the Dubinin-Radushkevich equation for modeling adsorption of organic vapors on activated carbon.

Author

Jahandar Lashaki M, Fayaz M, Niknaddaf S, and Hashisho Z

Subjects
Adsorption, Kinetics, Volatilization, Air Pollutants isolation & purification, Charcoal chemistry, Industrial Waste prevention & control, Models, Theoretical, Volatile Organic Compounds isolation & purification
Abstract

This paper investigates the effect of the kinetic diameter (KD) of the reference adsorbate on the accuracy of the Dubinin-Radushkevich (D-R) equation for predicting the adsorption isotherms of organic vapors on microporous activated carbon. Adsorption isotherms for 13 organic compounds on microporous beaded activated carbon were experimentally measured, and predicted using the D-R model and affinity coefficients. The affinity coefficients calculated based on molar volumes, molecular polarizabilities, and molecular parachors were used to predict the isotherms based on four reference compounds (4.3≤KD≤6.8 Å). The results show that the affinity coefficients are independent of the calculation method if the reference and test adsorbates are from the same organic group. Choosing a reference adsorbate with a KD similar to that of the test adsorbate results in better prediction of the adsorption isotherm. The relative error between the predicted and the measured adsorption isotherms increases as the absolute difference in the kinetic diameters of the reference and test adsorbates increases. Finally, the proposed hypothesis was used to explain reports of inconsistent findings among published articles. The results from this study are important because they allow a more accurate prediction of adsorption capacities of adsorbents which allow for better design of adsorption systems., (Copyright © 2012 Elsevier B.V. All rights reserved.)

Published
2012
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47. Adsorption and desorption of mixtures of organic vapors on beaded activated carbon.

Author

Wang H, Jahandar Lashaki M, Fayaz M, Hashisho Z, Philips JH, Anderson JE, and Nichols M

Subjects
Adsorption, Gas Chromatography-Mass Spectrometry, Carbon chemistry, Gases chemistry
Abstract

In this study, adsorption and desorption of mixtures of organic compounds commonly emitted from automotive painting operations were experimentally studied. A mixture of two alkanes and a mixture of eight organic compounds were adsorbed onto beaded activated carbon (BAC) and then thermally desorbed under nitrogen. Following both adsorption and regeneration, samples of the BAC were chemically extracted. Gas chromatography-mass spectrometry (GC-MS) was used to quantify the compounds in the adsorption and desorption gas streams and in the BAC extracts. In general, for both adsorbate mixtures, competitive adsorption resulted in displacing low boiling point compounds by high boiling point compounds during adsorption. In addition to boiling point, adsorbate structure and functionality affected adsorption dynamics. High boiling point compounds such as n-decane and 2,2-dimethylpropylbenzene were not completely desorbed after three hours regeneration at 288 °C indicating that these two compounds contributed to heel accumulation on the BAC. Additional compounds not present in the mixtures were detected in the extract of regenerated BAC possibly due to decomposition or other reactions during regeneration. Closure analysis based on breakthrough curves, solvent extraction of BAC and mass balance on the reactor provided consistent results of the amount of adsorbates on the BAC after adsorption and/or regeneration.

Published
2012
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48. Effect of adsorption and regeneration temperature on irreversible adsorption of organic vapors on beaded activated carbon.

Author

Lashaki MJ, Fayaz M, Wang HH, Hashisho Z, Philips JH, Anderson JE, and Nichols M

Subjects
Adsorption, Porosity, Surface Properties, Thermogravimetry, Time Factors, Volatilization, Charcoal chemistry, Microspheres, Organic Chemicals chemistry, Temperature
Abstract

This paper investigates the effect of adsorption and regeneration temperature on the irreversible adsorption of a mixture of organic compounds typically emitted from automobile painting operations. Adsorption of the organic vapors mixture onto microporous beaded activated carbon (BAC) and regeneration of the saturated BAC were completed under different conditions. Results indicated that increasing the adsorption temperature from 25 to 35 or 45 °C increased heel buildup on BAC by about 30% irrespective of the regeneration temperature due to chemisorption. The adsorption capacity (for the first cycle) of the mixture onto the BAC at these three temperatures remained almost unchanged indicating chemisorption of some of these compounds onto the BAC. Increasing the regeneration temperature from 288 to 400 °C resulted in 61% reduction in the heel at all adsorption temperatures, possibly due to desorption of chemicals from narrow micropores. BET area and pore volumes of the BAC decreased proportionally to the cumulative heel. Pore size distribution and pore volume reduction confirmed that the heel was mainly built up in narrow micropores which can be occupied or blocked by some of the adsorbates.

Published
2012
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49. Concomitant adsorption and desorption of organic vapor in dry and humid air streams using microwave and direct electrothermal swing adsorption.

Author

Hashisho Z, Emamipour H, Rood MJ, Hay KJ, Kim BJ, and Thurston D

Subjects
Adsorption, Thermodynamics, Volatilization, Air Movements, Chemistry Techniques, Analytical methods, Humidity, Microwaves, Organic Chemicals chemistry, Temperature
Abstract

Industrial gas streams can contain highly variable organic vapor concentrations that need to be processed before they are emitted to the atmosphere. Fluctuations in organic vapor concentrations make it more difficult to operate a biofilter when compared to a constant vapor concentration. Hence, there is a need to stabilize the concentration of rapidly fluctuating gas streams for optimum operation of biofilters. This paper describes new concomitant adsorption desorption (CAD) systems used with variable organic vapor concentration gas streams to provide the same gas stream, but at a user-selected constant vapor concentration that can then be more readily processed by a secondary air pollution control device such as a biofilter. The systems adsorb organic vapor from gas streams and simultaneously heat the adsorbent using microwave or direct electrothermal energy to desorb the organic vapor at a user-selected set-point concentration. Both systems depicted a high degree of concentration stabilization with a mean relative deviation between set-point and stabilized concentration of 0.3-0.4%. The direct electrothermal CAD system was also evaluated to treat a humid gas stream (relative humidity = 85%) that contained a variable organic vapor concentration. The high humidity did not interfere with CAD operation as water vapor did not adsorb but penetrated through the adsorbent These results are important because they demonstrate the ability of CAD to effectively dampen concentration fluctuation in gas streams.

Published
2008
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50. Steady-state and dynamic desorption of organic vapor from activated carbon with electrothermal swing adsorption.

Author

Emamipour H, Hashisho Z, Cevallos D, Rood MJ, Thurston DL, Hay KJ, Kim BJ, and Sullivan PD

Subjects
Adsorption, Carbon chemistry, Organic Chemicals chemistry
Abstract

A new method to achieve steady-state and dynamic-tracking desorption of organic compounds from activated carbon was developed and tested with a bench-scale system. Activated carbon fiber cloth (ACFC) was used to adsorb methyl ethyl ketone (MEK) from air streams. Direct electrothermal heating was then used to desorb the vapor to generate select vapor concentrations at 500 ppmv and 5000 ppmv in air. Dynamic-tracking desorption was also achieved with carefully controlled yet variable vapor concentrations between 250 ppmv and 5000 ppmv, while also allowing the flow rate of the carrier gas to change by 100%. These results were also compared to conditions when recovering MEK as a liquid, and using microwaves as the source of energy to regenerate the adsorbent to provide MEK as a vapor or a liquid.

Published
2007
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