Your search keyword '"Abnisa F"' showing total 31 results

1. Glycerol Electrocatalytic Reduction Using an Activated Carbon Composite Electrode:Understanding the Reaction Mechanisms and an Optimization Study

Author

Md. Rahim, S.A.N., Lee, C.S., Aroua, M.K., Wan Daud, W.M.A., Abnisa, F., Cognet, P., Pérès, Y., Md. Rahim, S.A.N., Lee, C.S., Aroua, M.K., Wan Daud, W.M.A., Abnisa, F., Cognet, P., and Pérès, Y.

Abstract

The conversion of biomass-derived glycerol into valuable products is an alternative strategy for alleviating energy scarcity and environmental issues. The authors recently uncovered an activated carbon composite electrode with an Amberlyst-15 mediator able to generate 1,2-propanediol, diethylene glycol, and acetol via a glycerol electrocatalytic reduction. However, less attention to mechanistic insights makes its application to industrial processes challenging. Herein, two proposed intermediates, acetol and ethylene glycol, were employed as the feedstocks to fill the gap in the mechanistic understanding of the reactions. The results discovered the importance of acetol in producing 1,2-propanediol and concluded the glycerol electrocatalytic reduction process has a two-step reduction pathway, where glycerol was initially reduced to acetol and consecutively hydrogenated to 1,2-propanediol. At 353 K and 0.28 A/cm2, 1,2-propanediol selectivity achieved 77% (with 59.8 C mol% yield) after 7 h of acetol (3.0 mol/L) electrolysis. Finally, the influences of the temperature, glycerol initial concentration, and current density on the glycerol electrocatalytic reduction were evaluated. The initial step involved the C-O and C-C bonds cleavage in glycerol plays a crucial role in producing either acetol or ethylene glycol intermediate. This was controlled by the temperature, which low to moderate value is needed to maintain a selective acetol-1,2-propanediol route. Additionally, medium glycerol initial concentration reduced the hydrogen formation and indirectly improved 1,2-propanediol yield. A mild current density raised the conversion rate and minimized the growth of intermediates. At 353 K and 0.21 A/cm2, glycerol (3.0 mol/L) electrocatalytic reduction to 1,2-propanediol reached the maximum yield of 42.3 C mol%.

Published

2022

2. Glycerol Electrocatalytic Reduction Using an Activated Carbon Composite Electrode : Understanding the Reaction Mechanisms and an Optimization Study

Author

Md. Rahim, S.A.N., Lee, C.S., Aroua, M.K., Wan Daud, W.M.A., Abnisa, F., Cognet, P., Pérès, Y., Md. Rahim, S.A.N., Lee, C.S., Aroua, M.K., Wan Daud, W.M.A., Abnisa, F., Cognet, P., and Pérès, Y.

Abstract

The conversion of biomass-derived glycerol into valuable products is an alternative strategy for alleviating energy scarcity and environmental issues. The authors recently uncovered an activated carbon composite electrode with an Amberlyst-15 mediator able to generate 1,2-propanediol, diethylene glycol, and acetol via a glycerol electrocatalytic reduction. However, less attention to mechanistic insights makes its application to industrial processes challenging. Herein, two proposed intermediates, acetol and ethylene glycol, were employed as the feedstocks to fill the gap in the mechanistic understanding of the reactions. The results discovered the importance of acetol in producing 1,2-propanediol and concluded the glycerol electrocatalytic reduction process has a two-step reduction pathway, where glycerol was initially reduced to acetol and consecutively hydrogenated to 1,2-propanediol. At 353 K and 0.28 A/cm2, 1,2-propanediol selectivity achieved 77% (with 59.8 C mol% yield) after 7 h of acetol (3.0 mol/L) electrolysis. Finally, the influences of the temperature, glycerol initial concentration, and current density on the glycerol electrocatalytic reduction were evaluated. The initial step involved the C-O and C-C bonds cleavage in glycerol plays a crucial role in producing either acetol or ethylene glycol intermediate. This was controlled by the temperature, which low to moderate value is needed to maintain a selective acetol-1,2-propanediol route. Additionally, medium glycerol initial concentration reduced the hydrogen formation and indirectly improved 1,2-propanediol yield. A mild current density raised the conversion rate and minimized the growth of intermediates. At 353 K and 0.21 A/cm2, glycerol (3.0 mol/L) electrocatalytic reduction to 1,2-propanediol reached the maximum yield of 42.3 C mol%.

Published

2022

3. A review of recent progress on electrocatalysts toward efficient glycerol electrooxidation

Author

Alaba, P.A., Lee, C.S., Abnisa, F., Aroua, M.K., Cognet, P., Pérès, Y., Wan Daud, W.M.A., Alaba, P.A., Lee, C.S., Abnisa, F., Aroua, M.K., Cognet, P., Pérès, Y., and Wan Daud, W.M.A.

Abstract

Glycerol electrooxidation has attracted immense attention due to the economic advantage it could add to biodiesel production. One of the significant challenges for the industrial development of glycerol electrooxidation process is the search for a suitable electrocatalyst that is sustainable, cost effective, and tolerant to carbonaceous species, results in high performance, and is capable of replacing the conventional Pt/C catalyst. We review suitable, sustainable, and inexpensive alternative electrocatalysts with enhanced activity, selectivity, and durability, ensuring the economic viability of the glycerol electrooxidation process. The alternatives discussed here include Pd-based, Au-based, Ni-based, and Ag-based catalysts, as well as the combination of two or three of these metals. Also discussed here are the prospective materials that are yet to be explored for glycerol oxidation but are reported to be bifunctional (being capable of both anodic and cathodic reaction). These include heteroatom-doped metal-free electrocatalysts, which are carbon materials doped with one or two heteroatoms (N, B, S, P, F, I, Br, Cl), and heteroatom-doped nonprecious transition metals. Rational design of these materials can produce electrocatalysts with activity comparable to that of Pt/C catalysts. The takeaway from this review is that it provides an insight into further study and engineering applications on the efficient and cost-effective conversion of glycerol to value-added chemicals.

Published

2021

4. Kinetic parameters for glycerol electrooxidation over nitrogen- and fluorine-doped composite carbon:Dynamic electrochemical impedance spectroscopy analysis based

Author

Alaba, P.A., Lee, C.S., Abnisa, F., Aroua, M.K., Cognet, P., Pérès, Y., Wan Daud, W.M.A., Alaba, P.A., Lee, C.S., Abnisa, F., Aroua, M.K., Cognet, P., Pérès, Y., and Wan Daud, W.M.A.

Abstract

This study explores the mechanistic, kinetic process and parameters of nitrogen and fluorine-doped activated carbon black composite catalyst during glycerol electrooxidation in alkaline so under some precise experimental parameters. The influence of catalyst and electrochemical impedance spectroscopy (EIS) perturbation amplitude were systematically studied. The kinetic parameters from steady-state measurement and microkinetic modelling study reveal that glycerol electrooxidation undergoes complicated mechanism. From the chronoamperometry study, the nitrogen-doped sample (ACB-N2) shows a remarkable activity and stability, but the performance was improved upon the simultaneous doping of fluorine to form ACB-N2F2. The best rate constant was obtained by ACB-N2F2 (7.335 × 10−3), which is by far greater than those of ACB-N2 (2.533 × 10−3) and ACB-F2 (2.012 × 10−3) for steady-state. The slope obtained from the Tafel plot of both the voltammetry and the non-linear electrochemical impedance spectroscopy measurement also confirms the superior performance of ACB-N2F2 compared to ACB-N2 and ACB-F2. The rate constant of ACB-N2F2 is almost 6 times of that of ACB-N2, and 4 times of the of ACB-F2 for the forward sweep. The exchange current density of ACB-N2F2 is almost 7 times of that of ACB-N2, and 3 times of the of ACB-F2 for the forward sweep. The methods in this study for evaluation of glycerol electrooxidation kinetic process and kinetic parameters could be used to investigate other electrocatalysts.

Published

2021

5. Kinetic parameters for glycerol electrooxidation over nitrogen- and fluorine-doped composite carbon : Dynamic electrochemical impedance spectroscopy analysis based

Author

Alaba, P.A., Lee, C.S., Abnisa, F., Aroua, M.K., Cognet, P., Pérès, Y., Wan Daud, W.M.A., Alaba, P.A., Lee, C.S., Abnisa, F., Aroua, M.K., Cognet, P., Pérès, Y., and Wan Daud, W.M.A.

Abstract

This study explores the mechanistic, kinetic process and parameters of nitrogen and fluorine-doped activated carbon black composite catalyst during glycerol electrooxidation in alkaline so under some precise experimental parameters. The influence of catalyst and electrochemical impedance spectroscopy (EIS) perturbation amplitude were systematically studied. The kinetic parameters from steady-state measurement and microkinetic modelling study reveal that glycerol electrooxidation undergoes complicated mechanism. From the chronoamperometry study, the nitrogen-doped sample (ACB-N2) shows a remarkable activity and stability, but the performance was improved upon the simultaneous doping of fluorine to form ACB-N2F2. The best rate constant was obtained by ACB-N2F2 (7.335 × 10−3), which is by far greater than those of ACB-N2 (2.533 × 10−3) and ACB-F2 (2.012 × 10−3) for steady-state. The slope obtained from the Tafel plot of both the voltammetry and the non-linear electrochemical impedance spectroscopy measurement also confirms the superior performance of ACB-N2F2 compared to ACB-N2 and ACB-F2. The rate constant of ACB-N2F2 is almost 6 times of that of ACB-N2, and 4 times of the of ACB-F2 for the forward sweep. The exchange current density of ACB-N2F2 is almost 7 times of that of ACB-N2, and 3 times of the of ACB-F2 for the forward sweep. The methods in this study for evaluation of glycerol electrooxidation kinetic process and kinetic parameters could be used to investigate other electrocatalysts.

Published

2021

6. Catalyst characteristics and performance of silica-supported zinc for hydrodeoxygenation of phenol

Author

Pourzolfaghar, H., Abnisa, F., Wan Daud, W.M.A., Aroua, M.K., Mahlia, T.M.I., Pourzolfaghar, H., Abnisa, F., Wan Daud, W.M.A., Aroua, M.K., and Mahlia, T.M.I.

Abstract

The present investigation aimed to study the physicochemical characteristics of supported catalysts comprising various percentages of zinc dispersed over SiO2. The physiochemical properties of these catalysts were surveyed by N2physisorption (BET), thermogravimetry analysis (TGA), H2temperature-programmed reduction, field-emission scanning electron microscopy (FESEM), inductively coupled plasma-optical emission spectrometry (ICP-OES), and NH3temperature-programmed desorption (NH3-TPD). In addition, to examine the activity and performance of the catalysts for the hydrodeoxygenation (HDO) of the bio-oil oxygenated compounds, the experimental reaction runs, as well as stability and durability tests, were performed using 3% Zn/SiO2as the catalyst. Characterization of silica-supported zinc catalysts revealed an even dispersion of the active site over the support in the various dopings of the zinc. The acidity of the calcinated catalysts elevated clearly up to 0.481 mmol/g. Moreover, characteristic outcomes indicate that elevating the doping of zinc metal led to interaction and substitution of proton sites on the SiO2surface that finally resulted in an increase in the desorption temperature peak. The experiments were performed at temperature 500 °C, pressure 1 atm; weight hourly space velocity (WHSV) 0.32 (h-1); feed flow rate 0.5 (mL/min); and hydrogen flow rate 150 (mL/min). Based on the results, it was revealed that among all the prepared catalysts, that with 3% of zinc had the highest conversion efficiency up to 80%. However, the selectivity of the major products, analyzed by gas chromatography flame-ionization detection (GC-FID), was not influenced by the variation in the active site doping.

Published

2020

7. A review of recent developments on kinetics parameters for glycerol electrochemical conversion – A by-product of biodiesel

Author

Rahim, S.A.N.M., Lee, C.S., Abnisa, F., Aroua, M.K., Daud, W.A.W., Cognet, P., Pérès, Y., Rahim, S.A.N.M., Lee, C.S., Abnisa, F., Aroua, M.K., Daud, W.A.W., Cognet, P., and Pérès, Y.

Abstract

Glycerol is a by-product produced from biodiesel, fatty acid, soap and bioethanol industries. Today, the value of glycerol is decreasing in the global market due to glycerol surplus, which primarily resulted from the speedy expansion of biodiesel producers around the world. Numerous studies have proposed ways of managing and treating glycerol, as well as converting it into value-added compounds. The electrochemical conversion method is preferred for this transformation due to its simplicity and hence, it is discussed in detail. Additionally, the factors that could affect the process mechanisms and products distribution in the electrochemical process, including electrodes materials, pH of electrolyte, applied potential, current density, temperature and additives are also thoroughly explained. Value-added compounds that can be produced from the electrochemical conversion of glycerol include glyceraldehyde, dihydroxyacetone, glycolic acid, glyceric acid, lactic acid, 1,2-propanediol, 1,3-propanediol, tartronic acid and mesoxalic acid. These compounds are found to have broad applications in cosmetics, pharmaceutical, food and polymer industries are also described. This review will be devoted to a comprehensive overview of the current scenario in the glycerol electrochemical conversion, the factors affecting the mechanism pathways, reaction rates, product selectivity and yield. Possible outcomes obtained from the process and their benefits to the industries are discussed. The utilization of solid acid catalysts as additives for future studies is also suggested.

Published

2020

8. Gas-phase hydrodeoxygenation of phenol over Zn/SiO2 catalysts:Effects of zinc load, temperature, weight hourly space velocity, and H 2 volumetric flow rate

Author

Pourzolfaghar, H., Abnisa, F., Wan Daud, W.M.A., Aroua, M.K., Pourzolfaghar, H., Abnisa, F., Wan Daud, W.M.A., and Aroua, M.K.

Abstract

The hydrodeoxygenation (HDO) of phenol catalyzed by Zn/SiO2 under atmospheric H2 pressure was investigated in a continuous fixed bed reactor. The effects of several process parameters (zinc load, reaction temperature, weight hourly space velocity (WHSV), and H2 volumetric flow rate) were evaluated to optimize process conditions. Phenol was selected as a stable model component for lignin degradation products in fast pyrolysis bio-oil. Silica-supported zinc catalysts were prepared with different loadings of the active metal (0.5%, 1%, 2%, 3%, and 4%) and assessed using characterization techniques such as XRD, ICP-OES, BET, H2-TPR/TPD, and FESEM–EDX. Reaction products including benzene, cyclohexene, and cyclohexane were identified through GC/FID analysis. Experimental results revealed that process yield increased with reaction temperature, metal loading, and WHSV. The selectivity percentages of the products were slightly changed by varying process parameters. Moreover, H2 volumetric flow rate exerted a negligible effect on product yield and selectivity.

Published

2020

9. Gas-phase hydrodeoxygenation of phenol over Zn/SiO2 catalysts : Effects of zinc load, temperature, weight hourly space velocity, and H 2 volumetric flow rate

Author

Pourzolfaghar, H., Abnisa, F., Wan Daud, W.M.A., Aroua, M.K., Pourzolfaghar, H., Abnisa, F., Wan Daud, W.M.A., and Aroua, M.K.

Abstract

The hydrodeoxygenation (HDO) of phenol catalyzed by Zn/SiO2 under atmospheric H2 pressure was investigated in a continuous fixed bed reactor. The effects of several process parameters (zinc load, reaction temperature, weight hourly space velocity (WHSV), and H2 volumetric flow rate) were evaluated to optimize process conditions. Phenol was selected as a stable model component for lignin degradation products in fast pyrolysis bio-oil. Silica-supported zinc catalysts were prepared with different loadings of the active metal (0.5%, 1%, 2%, 3%, and 4%) and assessed using characterization techniques such as XRD, ICP-OES, BET, H2-TPR/TPD, and FESEM–EDX. Reaction products including benzene, cyclohexene, and cyclohexane were identified through GC/FID analysis. Experimental results revealed that process yield increased with reaction temperature, metal loading, and WHSV. The selectivity percentages of the products were slightly changed by varying process parameters. Moreover, H2 volumetric flow rate exerted a negligible effect on product yield and selectivity.

Published

2020

10. Catalyst characteristics and performance of silica-supported zinc for hydrodeoxygenation of phenol

Author

Pourzolfaghar, H, Abnisa, F, Wan Daud, WMA, Aroua, MK, Mahlia, TMI, Pourzolfaghar, H, Abnisa, F, Wan Daud, WMA, Aroua, MK, and Mahlia, TMI

Abstract

© 2020 MDPI AG. All rights reserved. The present investigation aimed to study the physicochemical characteristics of supported catalysts comprising various percentages of zinc dispersed over SiO2. The physiochemical properties of these catalysts were surveyed by N2physisorption (BET), thermogravimetry analysis (TGA), H2temperature-programmed reduction, field-emission scanning electron microscopy (FESEM), inductively coupled plasma-optical emission spectrometry (ICP-OES), and NH3temperature-programmed desorption (NH3-TPD). In addition, to examine the activity and performance of the catalysts for the hydrodeoxygenation (HDO) of the bio-oil oxygenated compounds, the experimental reaction runs, as well as stability and durability tests, were performed using 3% Zn/SiO2as the catalyst. Characterization of silica-supported zinc catalysts revealed an even dispersion of the active site over the support in the various dopings of the zinc. The acidity of the calcinated catalysts elevated clearly up to 0.481 mmol/g. Moreover, characteristic outcomes indicate that elevating the doping of zinc metal led to interaction and substitution of proton sites on the SiO2surface that finally resulted in an increase in the desorption temperature peak. The experiments were performed at temperature 500 °C, pressure 1 atm; weight hourly space velocity (WHSV) 0.32 (h-1); feed flow rate 0.5 (mL/min); and hydrogen flow rate 150 (mL/min). Based on the results, it was revealed that among all the prepared catalysts, that with 3% of zinc had the highest conversion efficiency up to 80%. However, the selectivity of the major products, analyzed by gas chromatography flame-ionization detection (GC-FID), was not influenced by the variation in the active site doping.

Published

2020

11. Effect of Torrefaction Conditions on Physicochemical Properties of Empty Fruit Bunches

Author

Sukiran, M A, primary, Wan Daud, W M A, additional, Abnisa, F, additional, Nasrin, A B, additional, and Loh, S K, additional

Published

2020

12. The yield prediction of synthetic fuel production from pyrolysis of plasticwaste by Levenberg-Marquardt approach in feedforward neural networks model

Author

Abnisa, F, Sharuddin, SDA, bin Zanil, MF, Daud, WMAW, and Mahlia, TMI

Abstract

© 2019 by the authors. The conversion of plastic waste into fuel by pyrolysis has been recognized as a potential strategy for commercialization. The amount of plastic waste is basically different for each country which normally refers to non-recycled plastics data; consequently, the production target will also be different. This study attempted to build a model to predict fuel production from different non-recycled plastics data. The predictive model was developed via Levenberg-Marquardt approach in feed-forward neural networks model. The optimal number of hidden neurons was selected based on the lowest total of the mean square error. The proposed model was evaluated using the statistical analysis and graphical presentation for its accuracy and reliability. The results showed that the model was capable to predict product yields from pyrolysis of non-recycled plastics with high accuracy and the output values were strongly correlated with the values in literature.

Published

2019

13. Atmospheric hydrodeoxygenation of phenol as pyrolytic-oil model compound for hydrocarbon production using Ag/TiO 2 catalyst

Author

Kay Lup, A.N., Abnisa, F., Daud, W.M.A.W., Aroua, M.K., Kay Lup, A.N., Abnisa, F., Daud, W.M.A.W., and Aroua, M.K.

Abstract

Hydrodeoxygenation (HDO) kinetics of phenol over Ag/TiO 2 catalyst was investigated at 415–600 K and 1 atm. The use of oxophilic TiO 2 support has improved phenol conversion due to its preferential activation of CO bond. Product analysis confirmed the occurrence of direct deoxygenation (DDO) and hydrogenation–dehydration (HYD) pathways to produce benzene and cyclohexane, respectively. Both phenol hydrogenolysis and hydrogenation steps are the respective rate-limiting steps for DDO and HYD pathways of phenol HDO over Ag/TiO 2 . Based on the transition state theory, negative entropy changes of activation during HDO indicated that the HDO reactants formed activated complexes that had more orderly bonding configurations prior to the hydrogenolysis, hydrogenation, and dehydration steps. Under the present conditions, the catalyst was stable after 4 hr of HDO runs and able to be regenerated via H 2 -activation and calcination in air at 553 K with at least 98.9% removal efficiency to remove coke deposits and reform Ag metal species after HDO.

Published

2019

14. Upgrading of oil palm biomass by torrefaction process: A preliminary study

Author

Sukiran, M. A., primary, Abnisa, F., additional, Daud, W. M. A. W., additional, Bakar, N. A., additional, Aziz, A. A., additional, and Loh, S. K., additional

Published

2019

15. Investigation properties of superparamagnetic nanoparticles and magnetic field-dependent hyperthermia therapy

Author

Hedayatnasab, Z, primary, Abnisa, F, additional, and Wan Daud, W M A, additional

Published

2018

16. Pyrolysis of plastic waste for liquid fuel production as prospective energy resource

Author

Sharuddin, S D A, primary, Abnisa, F, additional, Daud, W M A W, additional, and Aroua, M K, additional

Published

2018

17. Natural rubber, a potential alternative source for the synthesis of renewable fuels via Hydrous Pyrolysis

Author

Ahmad, N, primary, Dayana, S A S, additional, Abnisa, F, additional, and Mohd, W A W D, additional

Published

2018

18. Acidity, oxophilicity and hydrogen sticking probability of supported metal catalysts for hydrodeoxygenation process

Author

Lup, A Ng K, primary, Abnisa, F, additional, Daud, W M A W, additional, and Aroua, M K, additional

Published

2018

19. Synthesis of Liquid Fuel Through Hydrothermal Conversion of Natural Rubber.

Author

Ahmad, N., Abnisa, F., and Daud, W. M. A. W.

Subjects

*LIQUID fuels, *BATCH reactors, *RUBBER, *WATER temperature, *WATER masses, *VISCOSIMETERS

Abstract

This study attempted to produce liquid fuel derived from natural rubber by using hydrothermal conversion process. The conversion process was conducted in a batch reactor at diverse temperatures conditions, with varied water to rubber mass proportion, and with different residence times. At optimum conditions of 375 ºC, 3:1 mass proportion, and 30min processing time, the maximum oil yield of 76 wt.% was achieved. Temperature and water to natural rubber ratio showed remarkable influence on oil yield. The quality of oil produced at optimal parameters was evaluated by using different analyses techniques such as CHNS analyzer, viscometer, GCMS, and pH meter. The outcomes of different characterizations results indicated that oil obtained from natural rubber has high HHV, non-acidic, less oxygen and sulfur contents. [ABSTRACT FROM AUTHOR]

Published

2019

20. Recovery of liquid fuel from the aqueous phase of pyrolysis oil using catalytic conversion

Author

Abnisa, F., Wan Daud, W.M.A., Arami-Niya, Arash, Ali, B.S., Sahu, J.N., Abnisa, F., Wan Daud, W.M.A., Arami-Niya, Arash, Ali, B.S., and Sahu, J.N.

Abstract

Oil from the pyrolysis of biomass typically consists of two different layers defined as the aqueous and organic phases. The objective of this study was to determine the yield of liquid fuel that can be produced from the aqueous phase using a catalytic conversion. The process was supported by two different HZSM-5 catalysts with temperatures set at 405, 455, 505, and 555 °C. The oils obtained were then analyzed using Karl Fischer titration, FTIR spectroscopy, GC/MS, TGA, and CHNS/O analysis. The results showed that the oil yields obtained from catalytic cracking of the aqueous phase ranged from 4 to 9.16 wt % depending on the catalyst type and temperature. The optimum performance of deoxygenation activity was obtained with the HZSM-5/50 catalyst at a temperature of 555 °C. The oil produced under the optimum conditions was dominated by aromatics and phenols and had an HHV of 38.44 MJ/kg. © 2014 American Chemical Society.

Published

2014

21. Acidity, oxophilicity and hydrogen sticking probability of supported metal catalysts for hydrodeoxygenation process

Author

K, A Ng, Abnisa, F, W, W M A, and, Daud, and Aroua, M K

Abstract

Hydrodeoxygenation is an oxygen removal process that occurs in the presence of hydrogen and catalysts. This study has shown the importance of acidity, oxophilicity and hydrogen sticking probability of supported metal catalysts in having high hydrodeoxygenation activity and selectivity. These properties are required to ensure the catalyst has high affinity for C-O or C=O bonds and the capability for the adsorption and activation of H2 and O-containing compounds. A theoretical framework of temperature programmed desorption technique was also discussed for the quantitative understanding of these properties. By using NH3-TPD, the nature and abundance of acid sites of catalyst can be determined. By using H2-TPD, the nature and abundance of metallic sites can also be determined. The desorption activation energy could also be determined based on the Redhead analysis of TPD spectra with different heating rates.

Published

2018

22. Exploring the combustion, emission and performance of n-Butanol with Deccan hemp oil methyl ester on dual fuel diesel engine.

Author

Jayaraman K, Anbuchezhiyan G, Mubarak NM, Bandegharaei AH, and Abnisa F

Abstract

This experiment investigated the feasibility of using n-butanol with Deccan hemp oil methyl ester derived from Hibiscus cannabinus. Deccan hemp oil, from warm countries like India is an eco-friendly alternative energy source since it is reusable and easy to locate. The Acetone-Butanol-Ethanol (ABE) process made the n-butanol. Further, 60% Deccan hemp oil methyl ester and 40% diesel were mixed and injected directly into the engine's cylinders. The engine's performance was evaluated by adding varying quantities of n-butanol (10%, 20%, or 30%) to the intake pipe at various intervals throughout the experiment. The results showed that using pure Deccan hemp oil or its methyl ester was much better for the engine's performance than regular diesel fuel. This was compared to how well the engine worked when diesel was used. However, the engine ran much better when fed a mix of 60% Deccan hemp oil methyl ester and 40% diesel (B60). Even though it couldn't compete with diesel engines in speed, this was still the case. The engine was running in dual fuel mode when n-butanol was added to the mixture. This made the carbon monoxide, unburned hydrocarbons, and smoke outputs go down. All of these decreases happened without making the engine less able to work. NOx emissions from the B60Bu10 (10% n-butanol share), B60Bu20, and B60Bu30 dual fuel combinations went up by 2.65%, 6%, and 8.9%, respectively, at full load, while smoke emissions went down by 18.33%, 23.75%, and 30.83%, in that order. The study's results show that adding Deccan hemp oil methyl ester to diesel fuel and injecting n-butanol into a dual-fuel diesel engine could help lower emissions without affecting the engine's performance., Competing Interests: Declarations Competing interests The authors declare no competing interests., (© 2024. The Author(s).)

Published

2024

23. Molecularly imprinted Ag 2 S quantum dots with high photocatalytic activity for dye removal: Experimental and DFT insights.

Author

Malik AQ, Jabeen T, Lokhande PE, Kumar D, Awasthi S, Pandey SK, Mubarak NM, and Abnisa F

Subjects

Catalysis, Coloring Agents chemistry, Polymers chemistry, Water Pollutants, Chemical chemistry, Wastewater chemistry, Silver Compounds chemistry, Quantum Dots chemistry, Molecular Imprinting

Abstract

Molecular imprinted polymers (MIPs) were developed by carrying out the cocktail solution of Template ((Salata, 2004)-Gingerol), monomer, crosslinker, and Ag 2 S Quantum Dots (QDs) by ex-situ dissolved in an appropriate solvent, resulting in an efficient crosslinked polymer composite. Degradation of Alizarin red S (ARS) dye and yellowish sunset (SY) azo dye under visible light irradiation was reported first time by the introduction of prepared MIPs composite. In this research, the result shows efficient photocatalyt activity of Ag 2 S-MIPs composite for the degradation of AR and SY dye with degradation% (80%) and (84%) in the aqueous wastewater. The degradation efficiency of the Ag 2 S-MIPs composite and the Ag 2 S QD associated with non-imprinted polymers (NIPs) (i.e.Ag 2 S-NIPs composite) were calculated by using different parameters such as catalyst dose, pH value, optimum time and concentration variation and the observations are evocative. Moreover, the density functional theory (DFT) approach was also used to analyze the structural, stability/energetics, and electronic features of the organic-inorganic hybrid composites of the Ag 2 S QD with the MIPs based on (Salata, 2004)-gingerol extract. The proposed QD and MIPs (EGDMA and (Salata, 2004)-Gingerol) composite model has been detected to be the most stable because it shows the largest binding energy (BE) among the three chosen composite models. It was found out that imprinted polymers were superior in enhancing the degradation of dyes when compared to non imprinted polymers. Introducing MIPs into the valence band accelerates the catalysis properties to stabilize newly fashioned excitons that are basically generated as a result of light excitation in presence of Ag 2 S Quantum Dots (QDs) and molecular imprinted polymer (MIPs). Motivation behind this work is to address the challenges related to environmental pollution causing by organic dyes. These toxins are known to cause diverse symptoms (e.g., skin irritation, eye infection, respiratory disorders, and even cancer) once exposed through ingestion and inhalation. Through incorporation of Ag 2 S QD into MIP,the purpose of this research is to enhance the selectivity, specificity and photocatalytic activity for dyes and that work holds a potential towards environmental remediation by developing a cost effective and sustainable method for controlling pollution in water., 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 © 2024 Elsevier Ltd. All rights reserved.)

Published

2024

24. Bo-derived waste neem to enriching reinforced hybrid composite for environmental remediation.

Author

Anbuchezhiyan G, Mubarak NM, Hussain Siddiqui MT, Malafaia G, and Abnisa F

Subjects

Materials Testing, Environmental Pollution, Tensile Strength, Composite Resins chemistry, Environmental Restoration and Remediation

Abstract

The utilization of natural fibres often entails a lesser environmental impact when compared to synthetic fibres. Biodegradable natural fibres minimize waste and pollution, and promote sustainability, but their weaker bonds limit their resilience. These issues can be addressed by customizing the composite's mechanical properties with natural and synthetic fibres. In this study, hybrid composites were created using the hand layup method with a novel dissimilar layer arrangement of neem (N), sisal (S), and glass (G) fibre and analyze its mechanical and thermal properties. Experimental observation shows that the GN composite had a higher maximum ultimate tensile strength of 26 N/mm 2 than the GS, GNS, and GSN composites. The GN composite had a percentage elongation of 6.33%, similar to the percentage elongation of the GS composite (6.833%), and it also had a higher ultimate shear strength of 50 MPa. The composite GS absorbed 6.6 J energy, higher than the composites GN, GNS, and GNS, which absorbed 6.1 J, 4.5 J, and 4.5 J, respectively. The fractured surface's SEM images were obtained and analyzed for failure. The results demonstrated that the hybridization was effective, and better properties can be obtained by combining neem, sisal, and glass fiber, and it can be used for other requirements, including strength, weight, cost, and ecological impact., 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 © 2024 Elsevier Ltd. All rights reserved.)

Published

2024

25. Torrefaction of organic municipal solid waste to high calorific value solid fuel using batch reactor with helical screw induced rotation.

Author

Abdulyekeen KA, Daud WMAW, Patah MFA, and Abnisa F

Abstract

The potential of producing high calorific value (CV) solid fuel was investigated in a helical screw rotation-induced (HSRI) fluidized bed reactor based on mechanical fluidization. The study revealed that the HSRI torrefaction improved the torrefied product properties. For the 40 and 0 rpm conditions, the CV, fixed carbon, and ash contents of torrefied solid fuel increased with an increase in temperature. In contrast, volatile matter, moisture content, mass and energy yields decreased. The CV of torrefied solid fuel increased by a factor of 1.43 and 1.58 at 280 °C for the 40 and 0 rpm conditions, respectively. HSRI torrefaction enhanced the removal of hydroxyl functional group. HSRI torrefaction improved the hydrophobicity of the torrefied solid fuel. Therefore, the HSRI fluidized bed reactor promotes uniform temperature distribution, a higher heat transfer rate within the sample particles in the reactor, and a homogenous torrefied solid product compared to the fixed bed reactor., 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 © 2022 Elsevier Ltd. All rights reserved.)

Published

2022

26. Activated carbon-based electrodes for two-steps catalytic/ electrocatalytic reduction of glycerol in Amberlyst-15 mediator.

Author

Md Rahim SAN, Lee CS, Abnisa F, Wan Daud WMA, Aroua MK, Cognet P, and Pérès Y

Subjects

Catalysis, Electrodes, Oxidation-Reduction, Styrenes, Charcoal, Glycerol chemistry

Abstract

Redox mediators supply an effective way to promote electrons (and protons) transport between the electrode and substrate without being in direct physical contact with the electrode. Here, the carbon-based electrodes with Amberlyst-15 as the redox mediator were used in the electrocatalytic reduction to investigate their ability to indirectly convert glycerol into 1,2-propanediol. The process aims to study the influence of different activated carbon compositions (60%, 70%, 80%, and 90% of total weight) in the activated carbon composite (ACC) electrodes on the electrochemical properties, reaction mechanisms, and selectivity of the yielded products. Their electrochemical behavior and physicochemical properties were determined by cyclic voltammetry (CV) and chronoamperometry (CA), followed by FESEM-EDX for the selected ACC electrode. Electroactive surface area (EASA) plays a role in glycerol mass transport and electrons transfer. EASA of 60ACC, 70ACC, 80ACC, and 90ACC (geometrical surface area of 0.50 cm 2 ) were 19.62, 24.50, 36.74 and 30.83 cm 2 , respectively. With the highest EASA, 80ACC enhanced the mass transport and electrons transfer process that eventually improved its electrocatalytic activity. It outperformed other ACC electrodes by generating Amberlyst-15 radicals (A-15 • - ) with high current density at low potential (-0.5 V vs. Ag/AgCl). A-15 • - served as the electron-donor for the homogeneous redox reaction with glycerol in delivering highly reactive glycerol radical for further intermediates development and generated 1,2-propanediol at -2.5 V vs. Ag/AgCl (current density of -0.2018 A cm -2 ). High activated carbon content portrayed a dominant role in controlling EASA and favored consecutive acetol-1,2-propanediol production through the C-O bond breakage. From the galvanostatic electrolysis, 1,2-propanediol selectivity was higher on 80ACC (88.6%) compared to 60ACC (61.4%), 70ACC (70.4%) and 90ACC (72.5%). Diethylene glycol formation was found to be the side reaction but preferred low activated carbon percentage in 60ACC and 70ACC., (Copyright © 2022 Elsevier Ltd. All rights reserved.)

Published

2022

27. Glycerol Electrocatalytic Reduction Using an Activated Carbon Composite Electrode: Understanding the Reaction Mechanisms and an Optimization Study.

Author

Md Rahim SAN, Lee CS, Aroua MK, Wan Daud WMA, Abnisa F, Cognet P, and Pérès Y

Abstract

The conversion of biomass-derived glycerol into valuable products is an alternative strategy for alleviating energy scarcity and environmental issues. The authors recently uncovered an activated carbon composite electrode with an Amberlyst-15 mediator able to generate 1,2-propanediol, diethylene glycol, and acetol via a glycerol electrocatalytic reduction. However, less attention to mechanistic insights makes its application to industrial processes challenging. Herein, two proposed intermediates, acetol and ethylene glycol, were employed as the feedstocks to fill the gap in the mechanistic understanding of the reactions. The results discovered the importance of acetol in producing 1,2-propanediol and concluded the glycerol electrocatalytic reduction process has a two-step reduction pathway, where glycerol was initially reduced to acetol and consecutively hydrogenated to 1,2-propanediol. At 353 K and 0.28 A/cm 2 , 1,2-propanediol selectivity achieved 77% (with 59.8 C mol% yield) after 7 h of acetol (3.0 mol/L) electrolysis. Finally, the influences of the temperature, glycerol initial concentration, and current density on the glycerol electrocatalytic reduction were evaluated. The initial step involved the C-O and C-C bonds cleavage in glycerol plays a crucial role in producing either acetol or ethylene glycol intermediate. This was controlled by the temperature, which low to moderate value is needed to maintain a selective acetol-1,2-propanediol route. Additionally, medium glycerol initial concentration reduced the hydrogen formation and indirectly improved 1,2-propanediol yield. A mild current density raised the conversion rate and minimized the growth of intermediates. At 353 K and 0.21 A/cm 2 , glycerol (3.0 mol/L) electrocatalytic reduction to 1,2-propanediol reached the maximum yield of 42.3 C mol%., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2022 Md. Rahim, Lee, Aroua, Wan Daud, Abnisa, Cognet and Pérès.)

Published

2022

28. Investigating the relevance of Environmental Kuznets curve hypothesis in Saudi Arabia: towards energy efficiency and minimal carbon dioxide emission.

Author

Alsaedi MA, Abnisa F, Alaba PA, and Farouk HU

Abstract

The Saudi economy is driven by the energy sector which mainly derived from petroleum-based resources. Besides export, the Kingdom's consumption of this resource showed a significant increase which linearly promoting CO 2 emission increment. Therefore, it is essential to model the Kingdom's energy consumption to estimate the profile of her future energy consumption. This work explores modelling and multi-step-ahead predictions for energy use, gross domestic product (GDP), and CO 2 emissions in Saudi Arabia using previous data (1980-2018). The dynamic interrelationship of the variable's nexus was tested using the Granger causality and cointegration method in the short-run and long-run. In the long-run, the models reveal an inverted U-shape relation between CO 2 emissions and GDP, validating Environmental Kuznets curve. When energy consumption is increased by 1%, there will be an increase in CO 2 emissions by 0.592% at constant GDP, and when GDP is increased by 1%, there will be an increase in CO 2 emissions by 0.282% at constant energy used. CO 2 emissions appear to be both energy consumption and income elastic in Saudi Arabia in the long-run equilibrium. Granger causality based on vector error correction method reveals unidirectional causality from income to CO 2 emissions, and bidirectional causality from CO 2 emissions to energy consumption and vice versa in the short-run. In the long-run, bidirectional causality from income to CO 2 emissions and vice versa and unidirectional causality from the used energy to CO 2 emissions were observed. Also, there is a bidirectional causality from GDP to energy used and vice versa in the short-run, meaning that GDP and energy consumption are interdependent. Saudi Arabia needs to increase energy infrastructure investments and increase energy efficiency by implementing energy management policies, reducing environmental pollution, and preventing the negative effect on economic growth., (© The Author(s), under exclusive licence to Springer-Verlag GmbH Germany, part of Springer Nature 2021.)

Published

2022

29. A review on production of metal organic frameworks (MOF) for CO 2 adsorption.

Author

Ghanbari T, Abnisa F, and Wan Daud WMA

Abstract

The environment sustenance and preservation of global climate are known as the crucial issues of the world today. Currently, the crisis of global warming due to CO 2 emission has turned into a paramount concern. To address such a concern, diverse CO 2 capture and sequestration techniques (CCS) have been introduced so far. In line with this, Metal Organic Frameworks (MOFs) have been considered as the newest and most promising material for CO 2 adsorption and separation. Due to their outstanding properties, this new class of porous materials a have exhibited a conspicuous potential for gas separation technologies especially for CO 2 storage and separation. Thus, the present review paper is aimed to discuss the adsorption properties of CO 2 on the MOFs based on the adsorption mechanisms and the design of the MOF structures. In addition, the main challenge associated with using this prominent porous material has been mentioned., (Copyright © 2019 Elsevier B.V. All rights reserved.)

Published

2020

30. A review of recent developments on kinetics parameters for glycerol electrochemical conversion - A by-product of biodiesel.

Author

Rahim SANM, Lee CS, Abnisa F, Aroua MK, Daud WAW, Cognet P, and Pérès Y

Subjects

Glycerol, Kinetics, Soaps, Biofuels

Abstract

Glycerol is a by-product produced from biodiesel, fatty acid, soap and bioethanol industries. Today, the value of glycerol is decreasing in the global market due to glycerol surplus, which primarily resulted from the speedy expansion of biodiesel producers around the world. Numerous studies have proposed ways of managing and treating glycerol, as well as converting it into value-added compounds. The electrochemical conversion method is preferred for this transformation due to its simplicity and hence, it is discussed in detail. Additionally, the factors that could affect the process mechanisms and products distribution in the electrochemical process, including electrodes materials, pH of electrolyte, applied potential, current density, temperature and additives are also thoroughly explained. Value-added compounds that can be produced from the electrochemical conversion of glycerol include glyceraldehyde, dihydroxyacetone, glycolic acid, glyceric acid, lactic acid, 1,2-propanediol, 1,3-propanediol, tartronic acid and mesoxalic acid. These compounds are found to have broad applications in cosmetics, pharmaceutical, food and polymer industries are also described. This review will be devoted to a comprehensive overview of the current scenario in the glycerol electrochemical conversion, the factors affecting the mechanism pathways, reaction rates, product selectivity and yield. Possible outcomes obtained from the process and their benefits to the industries are discussed. The utilization of solid acid catalysts as additives for future studies is also suggested., (Copyright © 2019 Elsevier B.V. All rights reserved.)

Published

2020

31. The Yield Prediction of Synthetic Fuel Production from Pyrolysis of Plastic Waste by Levenberg-Marquardt Approach in Feedforward Neural Networks Model.

Author

Abnisa F, Anuar Sharuddin SD, Bin Zanil MF, Wan Daud WMA, and Indra Mahlia TM

Abstract

The conversion of plastic waste into fuel by pyrolysis has been recognized as a potential strategy for commercialization. The amount of plastic waste is basically different for each country which normally refers to non-recycled plastics data; consequently, the production target will also be different. This study attempted to build a model to predict fuel production from different non-recycled plastics data. The predictive model was developed via Levenberg-Marquardt approach in feed-forward neural networks model. The optimal number of hidden neurons was selected based on the lowest total of the mean square error. The proposed model was evaluated using the statistical analysis and graphical presentation for its accuracy and reliability. The results showed that the model was capable to predict product yields from pyrolysis of non-recycled plastics with high accuracy and the output values were strongly correlated with the values in literature.

Published

2019