Optimizing the Preparation of Meso- and Microporous Canola Stalk-Derived Hydrothermal Carbon via Response Surface Methodology for Methylene Blue Removal

Salimi, Mohammad; Balou, Salar; Kohansal, Komeil; Babaei, Khosrow; Tavasoli, Ahmad; Andache, Mahmoud

doi:10.1021/acs.energyfuels.7b02440

Cited by 34 publications

(17 citation statements)

References 86 publications

(195 reference statements)

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“…The experimental procedure for HTC has been described in detail before. 31 Briefly, each HTC process is comprised of mixing CAWL (carbon source), S. platensismicroalgae (nitrogen source), and deionized water in a 100 mL stainless steel Teflon-lined hydrothermal synthesis autoclave reactor (Figure 1, Supporting Information Video). Three grams of CAWL powder was mixed with the appropriate amount of microalgae based on the required microalgae/biomass weight ratio.…”

Section: Introductionmentioning

confidence: 99%

Synergistic Effect of Nitrogen Doping and Ultra-Microporosity on the Performance of Biomass and Microalgae-Derived Activated Carbons for CO₂ Capture

Balou

Babak

Priye

2020

ACS Appl. Mater. Interfaces

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We report a unique naturally derived activated carbon with optimally incorporated nitrogen functional groups and ultra-microporous structure to enable high CO 2 adsorption capacity. The coprocessing of biomass (Citrus aurantium waste leaves) and microalgae (Spirulina) as the N-doping agent was investigated by probing the parameter space (biomass/microalgae weight ratio, reaction temperature, and reaction time) of hydrothermal carbonization and activation process (via the ZnCl 2 /CO 2 activation) to generate hydrochars and activated carbons, respectively, with tunable nitrogen content and pore sizes. The central composite-based design of the experiment was applied to optimize the parameters of the prehydrothermal carbonization procedure resulting in the fabrication of N-enriched carbonaceous products with the highest possible mass yield and nitrogen content. The resulting hydrochars and activated carbon samples were characterized using elemental analysis, X-ray diffraction, Fourier transform infrared spectroscopy, X-ray photoelectron spectroscopy, field emission scanning electron microscopy, and Brunauer−Emmett−Teller surface area analysis. We observe that while N-doping and the activation process can individually enhance the CO 2 adsorption capacity to some extent, it is the combined effect of the two processes that synergistically work to greatly increase the adsorption capacity of the N-doped activated carbon by an amount which is more than the sum of individual contributions. We analyze the origins of this synergy with both physical and chemical characterization techniques. The resulting naturally derived activated carbon demonstrates one of the highest CO 2 adsorption capacities (8.43 mmol/g) with rapid adsorption kinetics and good selectivity and reusability.

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Section: Introductionmentioning

confidence: 99%

Synergistic Effect of Nitrogen Doping and Ultra-Microporosity on the Performance of Biomass and Microalgae-Derived Activated Carbons for CO₂ Capture

Balou

Babak

Priye

2020

ACS Appl. Mater. Interfaces

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“…The extent of the surface area revealed that the HTC process leads to a low porosity-based material. However the value obtained was slightly higher than that for hydrochar prepared from canola stalk by HTC at 207ºC for 82 min (2.69 m 2 •g -1 ) [26]. Tran et al [20] prepared hydrochar from golden shower at 190ºC for 24 h, which produced a surface area (24.80 m 2 •g -1 ) almost three times higher than the precursor (8.14 m 2 •g -1 ), which was due to the weak decomposition of cellulose and lignin during the HTC process.…”

Section: Samplementioning

confidence: 57%

“…The broad band at 3200-3600 cm -1 corresponds to the stretching vibration of O-H groups from the phenol groups of hemicellulose, cellulose, and lignin and N-H stretching vibration [31]. However, the hydroxyl peak in the MOPF was stronger than in the hydrochar due to the organic acid content in the biomass consisting of carboxyls, phenols and/or chemisorbed water [19,30] and due to the removal of the H and O from the hydrochar due to the dehydration and decarboxylation processesduring the formation of H 2 O and CO 2 as liquid products [26]. C-H stretching in the aliphatic CH, CH 2 , and CH 3 groups and aromatic C=C bending (due to the aromatic characteristic of lignin) are apparent at the bands at 2920 cm -1 and 1620 cm -1 , respectively.…”

Section: Samplementioning

confidence: 99%

“…Conversely, the peak at 1249 cm -1 assigned to C-O (alcohols, carboxylic acids, esters, and ethers), did not appear in the hydrochar spectrum because of the decarboxylation reaction during the HTC process. The taper band at 780 cm -1 in the hydrochar indicates deformities due to out-of-plane angular benzene derivatives that were assigned to =CH bending vibration [26].…”

Section: Samplementioning

confidence: 99%

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Investigation of Hydrochar Derived from Male Oil Palm Flower: Characteristics and Application for Dye Removal

Said¹,

Tekasakul²,

Phoungthong³

2019

Pol. J. Environ. Stud.

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Southeast Asia is the region most heavily planted with oil palm tree in the world. As the third-ranking country producing palm oil, a large quantity of oil palm tree waste is generated in Thailand. Thailand's palm oil production achieves roughly 11-13 million tons or a matter of 1.2% of world production [1]. These biomass wastes may come from plantations (oil palm trunks and fronds) or palm oil mills (empty fruit bunches, mesocarp fiber, and palm kernel shells) [2]. Wastes such as trunks of the plant, fronds, and both male and female flower are direct agricultural wastes along pruning and harvesting seasons. Among the parts of the oil palm tree, male flowers are not currently used productively once they have matured. In the life-cycle of the palm tree, the male flower, which grows separately in a spike, fertilizes the female flowers. The oil palm is a monoecious plant with

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“…Nowadays, the membrane-based liquid desiccant air dehumidification which had been mostly applied in wastewater treatment processes has become more interesting for researchers worldwide, who are investigating the field of air conditioning systems [12]. This technology, which is a thermally driven separation process, utilizes the vapor pressure difference across the porous membrane as a driving force to achieve successful separation and dehumidification [13]. The most important difference between this method and the conventional liquid desiccant air dehumidification is the utilization of semi-permeable membranes for the separation of the processing air and liquid desiccant fluids which generally results in the successful inhibition of liquid from penetrating [14].…”

Section: Introductionmentioning

confidence: 99%

Performance optimization of polymeric porous membrane-based liquid desiccant air dehumidifier used in air conditioning system

Jafarpour

Fazelpour

Mousavi

2019

Int J Energy Environ Eng

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In this study an experimental design was developed to optimize the performance and structure of a membrane-based parallelplate liquid desiccant dehumidifier used in air conditioning regeneration system which operates under high humidity weather conditions. We conducted a series of polymeric porous membranes with different compositions fabricated that were prepared with various weight percentages of polysulfone (PSU), mixed with N-methyl-2-pyrrolidone (NMP) and dimethyl form amide (DMF) solvents. Furthermore, the designed experiments were performed under various operating conditions, indicating that the dehumidification efficiency declines with increasing flow rate, temperature, and humidity. Consequently, a membrane with optimized porosity and moisture permeability was selected which resulted in eliminating the carryover of solution droplets in the air, largely due to separating the flow condition of liquid desiccant (Li Cl) and air. This specific design is also greatly benefited by removing the water vapor from the air stream. The results of mathematical model simulations indicate that the DMF solvent had higher dehumidification capability compared with that of NMP under the optimized operating conditions. Additionally, it can clarify the porosity of the membrane which plays a significant role in the overall performance. Therefore, the fabricated membrane produces fresh cool air, and it can be applied as a guiding sample for designing the membrane-based dehumidifier with improved performance.Publisher's Note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

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Optimizing the Preparation of Meso- and Microporous Canola Stalk-Derived Hydrothermal Carbon via Response Surface Methodology for Methylene Blue Removal

Cited by 34 publications

References 86 publications

Synergistic Effect of Nitrogen Doping and Ultra-Microporosity on the Performance of Biomass and Microalgae-Derived Activated Carbons for CO₂ Capture

Synergistic Effect of Nitrogen Doping and Ultra-Microporosity on the Performance of Biomass and Microalgae-Derived Activated Carbons for CO₂ Capture

Investigation of Hydrochar Derived from Male Oil Palm Flower: Characteristics and Application for Dye Removal

Performance optimization of polymeric porous membrane-based liquid desiccant air dehumidifier used in air conditioning system

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Optimizing the Preparation of Meso- and Microporous Canola Stalk-Derived Hydrothermal Carbon via Response Surface Methodology for Methylene Blue Removal

Cited by 34 publications

References 86 publications

Synergistic Effect of Nitrogen Doping and Ultra-Microporosity on the Performance of Biomass and Microalgae-Derived Activated Carbons for CO2 Capture

Synergistic Effect of Nitrogen Doping and Ultra-Microporosity on the Performance of Biomass and Microalgae-Derived Activated Carbons for CO2 Capture

Investigation of Hydrochar Derived from Male Oil Palm Flower: Characteristics and Application for Dye Removal

Performance optimization of polymeric porous membrane-based liquid desiccant air dehumidifier used in air conditioning system

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Product

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Synergistic Effect of Nitrogen Doping and Ultra-Microporosity on the Performance of Biomass and Microalgae-Derived Activated Carbons for CO₂ Capture

Synergistic Effect of Nitrogen Doping and Ultra-Microporosity on the Performance of Biomass and Microalgae-Derived Activated Carbons for CO₂ Capture