Your search keyword '"Ahmad, Razi"' showing total 13 results

1. BIO-CHAR AND BIO-OIL PRODUCTION FROM PYROLYSIS OF PALM KERNEL SHELL AND POLYETHYLENE.

Author

IBRAHIM, Nur Rahimah, AHMAD, Razi, WAN AHMAD, Wan Amiza Amneera, VIKNESWARAN, Vijean, SANTIAGOO, Ragunathan, MOHAMMED, Syakirah Afiza, KHALID, Amrie Fadzrul, and ANI, Asnida Yanti

Subjects

PYROLYSIS, FOURIER transforms

Abstract

In recent years, palm kernel shell (PKS) has become a viable feedstock for making biofuels and value-added commodities using a variety of thermal conversion routes. Therefore, significant conservation is required for PKS as a resource for fuel production in biofuel facilities. Thus, this research was intended to elucidate the effects on PKS as a solid fuel through torrefaction and the production of bio-char and bio-oil by single and co-pyrolysis of PKS and polyethylene (PE). The PKS was treated through torrefaction at different temperatures and holding times. The optimum parameters for torrefaction were a temperature of 250 oC and a holding time of 60 min. Then the PKS and PE were pyrolyzed in a fixed-bed reactor at different temperatures and ratios. The product yield was analysed for single and co-pyrolysis of PKS and PE for pyrolysis. The properties of the product composition for single and co-pyrolysis of the PKS and PE were determined by proximate analysis, Fourier transform infrared (FTIR) analysis, and gas chromatography-mass spectrometry (GC-MS). The optimum parameter obtained for biochar and bio-oil production from co-pyrolysis of PKS and PE was at temperature of 500 oC at a ratio of 1:2 (PKS: PE). The ester and phenol compounds were increased around 19.02 to 23.18% and 32.51 to 34.80 %, respectively, while amide and amine decreased around 4.94 to 18.87% and 0.63 to 32.39 %, respectively, compared to the single pyrolysis of PKS. Therefore, the PKS and PE co-pyrolysis significantly increased the amount of phenol and ester compounds while slightly reducing the amount of amide and amine compounds in the bio-oil product. As a conclusion, biomass conservation enables the manufacturing of value-added chemicals. [ABSTRACT FROM AUTHOR]

Published

2023

2. Competence of Lepironia articulata in eradicating chemical oxygen demand and ammoniacal nitrogen in coffee processing mill effluent and its potential as green straw

Author

Nor Sakinah Mohd Said, Nur ‘Izzati Ismail, Ahmad Razi Othman, Setyo Budi Kurniawan, Hassimi Abu Hasan, and Siti Rozaimah Sheikh Abdullah

Subjects

Biological Oxygen Demand Analysis, Environmental Engineering, Nitrogen, Chemical oxygen demand, Biomass, Straw, Pulp and paper industry, Pollution, Coffee, Waste Disposal, Fluid, Oxygen, Phytoremediation, Biodegradation, Environmental, Environmental Chemistry, Environmental science, Sewage treatment, Environmental Pollutants, Ammoniacal nitrogen, Waste Management and Disposal, Effluent, Coffee wastewater

Abstract

Phytoremediation is an environmentally friendly technique in wastewater treatment because of its sustainability, cost-effectiveness, and simplicity. This study was conducted to examine the feasibility of use of Lepironia articulata, a potential phytoremediation plant that is native to Malaysia, in remediating coffee processing mill effluent (CPME). The aim was to determine effluent concentration or contaminant load that the plant can resist, while simultaneously results in the good removal of pollutants during phytoremediation. Four brushes of L. articulata were planted individually in a pail/reactor (mentioned as reactor afterward) containing 3 kg of sand and exposed to five different concentrations of CPME (0%, 30%, 50%, 75%, and 100%). The initial chemical oxygen demand (COD) values were 510, 3100, 4200, 7290, and 8470 mg/L, respectively, and ammoniacal nitrogen (AN) concentrations were 26, 128, 225, 376, and 509 mg/L, respectively. The height, appearance, and efficiency in removing COD and AN of each plant was observed throughout the 35-day exposure period. Results showed that plants exposed to 75% CPME demonstrated better growth than those exposed to other concentrations and exhibited the highest COD and AN removal rates (85.0% and 84.0%, respectively), providing evidence that L. articulata can be used as a phytoremediation agent of CPME with an initial COD concentration of 7290 mg/L and AN concentration of 376 mg/L. This study highlights its support to the Sustainable Development Goals adopted by the United Nations, particularly the reclamation of plant biomass used as a treatment agent and conversion into biodegradable straws. Moreover, this study adds an attractive additional point of transforming waste into resource with the proposed wastewater treatment technology.

Published

2021

3. Macrophytes as wastewater treatment agents: Nutrient uptake and potential of produced biomass utilization toward circular economy initiatives

Author

Ipung Fitri Purwanti, Siti Rozaimah Sheikh Abdullah, Nor Sakinah Mohd Said, Ahmad Razi Othman, Setyo Budi Kurniawan, Azmi Ahmad, Hassimi Abu Hasan, and Muhammad Fauzul Imron

Subjects

Environmental Engineering, 010504 meteorology & atmospheric sciences, Biomass, Wastewater, 010501 environmental sciences, 01 natural sciences, Water Purification, Biogas, Bioenergy, Biochar, Animals, Environmental Chemistry, Waste Management and Disposal, 0105 earth and related environmental sciences, fungi, food and beverages, Nutrients, Pulp and paper industry, Pollution, Biofuel, Wetlands, Constructed wetland, Environmental science, Sewage treatment

Abstract

Macrophytes have been widely used as agents in wastewater treatment. The involvement of plants in wastewater treatment cannot be separated from wetland utilization. As one of the green technologies in wastewater treatment plants, wetland exhibits a great performance, especially in removing nutrients from wastewater before the final discharge. It involves the use of plants and consequently produces plant biomasses as treatment byproducts. The produced plant biomasses can be utilized or converted into several valuable compounds, but related information is still limited and scattered. This review summarizes wastewater's nutrient content (macro and micronutrient) that can support plant growth and the performance of constructed wetland (CW) in performing nutrient uptake by using macrophytes as treatment agents. This paper further discusses the potential of the utilization of the produced plant biomasses as bioenergy production materials, including bioethanol, biohydrogen, biogas, and biodiesel. This paper also highlights the conversion of plant biomasses into animal feed, biochar, adsorbent, and fertilizer, which may support clean production and circular economy efforts. The presented review aims to emphasize and explore the utilization of plant biomasses and their conversion into valuable products, which may solve problems related to plant biomass handling during the adoption of CW in wastewater treatment plants.

Published

2021

4. PHYTOTOXICITY OF COFFEE WASTEWATER TO WATER HYACINTH AS PRIOR STEP TO PHYTOTREATMENT ASSESSMENT: INFLUENCE OF CONCENTRATION AND AMOUNT OF PLANT BIOMASS

Author

Ahmad Razi Othman, Nur ‘Izzati Ismail, Siti Rozaimah Sheikh Abdullah, Hassimi Abu Hasan, Setyo Budi Kurniawan, and Hind Munaem Ahmed

Subjects

Phytotreatment, Environmental Engineering, biology, Hyacinth, Environmental science, Biomass, Phytotoxicity, Management, Monitoring, Policy and Law, Pulp and paper industry, biology.organism_classification, Pollution, Coffee wastewater

Published

2021

5. Effects of Leucaena biochar addition on crop productivity in degraded tropical soils

Author

Niall P. McNamara, Jeanette Whitaker, Dafydd M. O. Elias, Mohammad Fadhil Ahmad Razi, Samuel Robinson, and Gin Teng Ooi

Subjects

biology, Renewable Energy, Sustainability and the Environment, Chemistry, 020209 energy, Crop yield, Biomass, Forestry, 02 engineering and technology, engineering.material, biology.organism_classification, Leucaena, Nutrient, Agronomy, Soil pH, Soil water, Biochar, 0202 electrical engineering, electronic engineering, information engineering, engineering, Fertilizer, Waste Management and Disposal, Agronomy and Crop Science

Abstract

Biochar has the potential to increase crop yields on degraded, tropical soils. It can be readily produced in rural community settings using low-cost technology and is most economically feasible if produced from local biomass or waste residues. Biochar was produced from Leucaena biomass using low-cost pyrolysis and sequential pot experiments were then conducted in Malaysia on three degraded soils. We first evaluated the effect of Leucaena biochar on yields of Amaranthus, a leafy vegetable crop and measured changes to soil pH and nutrient availability over two growth cycles. We then tested whether any yield response to biochar was dependent upon the rate of biochar or fertilizer application. We found that biochar application at 30 t ha−1 with maximal fertilizer increased yields between 17 and 53% on very strongly acidic soil. Biochar added at 15 t ha−1 with maximal fertilizer increased yield by 54% on strongly acidic soil whilst there was no significant yield response on fertilized, slightly acidic soil. Unfertilized biochar treatments showed small yield responses across all soils over 2 growth cycles (9–11%), but yields were much lower than in fertilized treatments. Biochar also decreased short-term N availability when applied with fertilizers, which may improve nitrogen retention and substantially increased soil pH. This may reduce mobility of Fe, Mn and Al ions, which were negatively associated with yield. Our results suggest that Leucaena biochar can elicit a positive crop yield response but only when combined with fertilizer additions on very strongly to strongly acidic tropical soils.

Published

2020

6. Catalytic pyrolysis of biomass using calcium-based catalysts.

Author

Ahmad, Razi, Ramasamy, Shamala, Santiagoo, Ragunathan, Kasmuri, Norhafezah, Saede, Nor Amizah, Razak, Rafiza Abd, Abdullah, Mohd Mustafa Al Bakri, Rahim, Shayfull Zamree Abd, Tahir, Muhammad Faheem Mohd, Mortar, Nurul Aida Mohd, and Jamaludin, Liyana

Subjects

*FIXED bed reactors, *PYROLYSIS, *CATALYSTS, *BIOMASS

Abstract

The catalytic pyrolysis of biomass in fixed bed reactor using calcium-based catalysts had been studied in fixed bed reactor. The objective of this study was to determine the influence of parameters on pyrolysis product and to determine the potential of calcium-based catalysts in pyrolysis of palm shell. The results were obtained with various temperature, biomass size and catalyst ratio. The maximum bio oil from this study were at the temperature of 500 °C, biomass size of 425 µm and percentages catalyst ratio of 20%. In this study the use of Cryptomya Elliptica as a calcium-based catalyst produced the highest amount of bio oil yield of 32.71%. [ABSTRACT FROM AUTHOR]

Published

2020

7. CHARACTERIZATION OF BIO-OIL FROM PALM KERNEL SHELL PYROLYSIS

Author

Abidin Che Zulzikrami Azner, Hamidin Nasrul, Md. Ali Umi Fazara, and Ahmad Razi

Subjects

Materials science, lcsh:Mechanical engineering and machinery, palm kernel shell, Computational Mechanics, Analytical chemistry, Energy Engineering and Power Technology, Furfural, Industrial and Manufacturing Engineering, chemistry.chemical_compound, Palm kernel, lcsh:TJ1-1570, Char, Biomass, Fourier transform infrared spectroscopy, char, Mechanical Engineering, Extraction (chemistry), pyrolysis, renewable energy, Fuel Technology, chemistry, Mechanics of Materials, Yield (chemistry), bio-oil, Particle size, lcsh:Mechanics of engineering. Applied mechanics, lcsh:TA349-359, Pyrolysis

Abstract

Pyrolysis of palm kernel shell in a fixed-bed reactor was studied in this paper. The objectives were to investigate the effect of pyrolysis temperature and particle size on the products yield and to characterize the bio-oil product. In order to get the optimum pyrolysis parameters on bio-oil yield, temperatures of 350, 400, 450, 500 and 550 °C and particle sizes of 212–300 µm, 300–600 µm, 600µm–1.18 mm and 1.18–2.36 mm under a heating rate of 50 °C min -1 were investigated. The maximum bio-oil yield was 38.40% at 450 °C with a heating rate of 50 °C min -1 and a nitrogen sweep gas flow rate of 50 ml min -1 . The bio-oil products were analysed by Fourier transform infra-red spectroscopy (FTIR) and gas chromatography–mass spectroscopy (GCMS). The FTIR analysis showed that the bio-oil was dominated by oxygenated species. The phenol, phenol, 2-methoxy- and furfural that were identified by GCMS analysis are highly suitable for extraction from the bio-oil as value-added chemicals. The highly oxygenated oils need to be upgraded in order to be used in other applications such as transportation fuels.

Published

2014

8. The Effect of Pretreated Palm Kernel Shell and Mukah Balingian Coal Co-gasification on Product Yield and Gaseous Composition.

Author

Ahmad, Razi, Ishak, Mohd Azlan Mohd, Ismail, Khudzir, Kasim, Nur Nasulhah, Mohamed, Alina Rahayu, Ani, Asnida Yanti, Deris, Raja Razuan Raja, and Radzun, Khairul Adzfa

Subjects

BIOMASS gasification, COAL products, FIXED bed reactors, STEAM flow, PALMS

Abstract

In this study, co-gasification of palm kernel shell (PKS) and low-rank Malaysian coal (MB) was carried out in a fixed bed reactor. For the pretreated samples, PKS was torrefied at 270°C (PKSTo) and MB was preheated at 250°C (MBPr) for 1 h, respectively, prior to co-gasification at 767°C, with a biomass blending ratio of 52% and a steam flow rate of 55 mL/min. The effect of different blending combinations was investigated towards product yields, namely gas, tar, char and gases composition. The co-gasification on both pretreated (PKSTo/MBPr) and catalyst-pretreated (Cat-PKSTo/MBPr) produced a greater gas yield, with lesser tar and char yield than both untreated PKS and MB (PKSUn/MBUn) and pretreated PKS and untreated MB (PKSTo/MBUn). The PKSTo/MBPr was found to enhance the H2 production by 63.9% and 41% than PKSUn/MBUn and PKSTo/MBUn, respectively, at 45 min of reaction time. Thus, the pretreatment on both samples had a significant impact on the distribution and composition of product yields during co-gasification. As a conclusion, the pretreated sample, which has been upgraded on characteristics such as higher carbon and lower oxygen content than the untreated sample was revealed to enhance gas yield and H2 production during co-gasification. [ABSTRACT FROM AUTHOR]

Published

2020

9. Synergistic Effect on Co-gasification of Pretreated Palm Kernel Shell and Mukah Balingian Coal.

Author

Ahmad, Razi, Mohd Ishak, Mohd Azlan, Kasim, Nur Nasulhah, and Ismail, Khudzir

Subjects

*COAL gasification, *COAL gasification plants, *PALMS, *FIXED bed reactors, *FEEDSTOCK

Abstract

Co-gasification of pretreated palm kernel shell (PKS) and Mukah Balingian (MB) coal and gasification of individual feedstock were carried out in a fixed bed reactor system. The synergistic effect of pretreated feedstock in cogasification was probed. The results showed that the co-gasification of pretreated biomass and coal samples had a synergistic effect at all blending ratios. The experimental value of co-gasification on 50 % biomass blending ratio generated the highest gas yield of 69.43 % and lowest tar yield of 10.11 %. This was supported with the different of experimental value and calculated mean value (Exp-Cal) that showed the highest synergistic effect on product yield using 50 % biomass blending ratio of the pretreated samples. Thus, the pretreated PKS and MB coal, by which their physical and chemical properties have been enhanced through pretreatment process are suitable to be used in co-gasification. [ABSTRACT FROM AUTHOR]

Published

2018

10. Optimization of Co-gasification Process Parameters of Pretreated Palm Kernel Shell and Pretreated Malaysian Low Rank Coal using Response Surface Methodology.

Author

Ahmad, Razi, Mohd Ishak, Mohd Azlan, Kasim, Nur Nasulhah, and Ismail, Khudzir

Subjects

*COAL gasification, *RESPONSE surfaces (Statistics), *FIXED bed reactors, *BIOMASS, *STEAM flow

Abstract

Co-gasification of pretreated palm kernel shell (PKS) and pretreated Malaysian low rank coal has been conducted using a fix bed reactor system. Response surface methodology (RSM) based on central composite design (CCD) was used to determine the optimum condition on gas yield in co-gasification products. The effect of the three factors, i.e. gasification temperature, biomass blending ratio and steam flow rate on response variables (gas, tar and char yield) were examined. The p-value <0.05 for all factors indicated that the factors were significant. The predicted optimum conditions for gasification temperature, biomass blending ratio and steam flow rate were at 767 °C, 52 % and 54 ml/min, correspondingly. These optimum conditions produced maximum gas yield, minimum char and tar yield of 67.28 %, 20.83 % and 11.90 %, respectively. Thus, this study showed that the assessed RSM model has effectively determined the optimum process condition, which designates to the optimum gas yield in co-gasification. [ABSTRACT FROM AUTHOR]

Published

2018

11. Development of cellulase-nanoconjugates with enhanced ionic liquid and thermal stability for in situ lignocellulose saccharification.

Author

Grewal, Jasneet, Ahmad, Razi, and Khare, S.K.

Subjects

*BIOMASS, *CELLULASE, *IONIC liquids, *MAGNETIC nanoparticles, *SACCHARIN, *SILICA nanoparticles

Abstract

The present work aimed to improve catalytic efficiency of Trichoderma reesei cellulase for enhanced saccharification. The cellulase was immobilized on two nanomatrices i.e. magnetic and silica nanoparticles with immobilization efficiency of 85% and 76% respectively. The nanobioconjugates exhibited increase in V max , temperature optimum, pH and thermal stability as compared with free enzyme. These could be efficiently reused for five repeated cycles and were stable in 1-ethyl-3-methylimidazoliumacetate [EMIM][Ac], an ionic liquid. Ionic liquids (IL) are used as green solvents to dissolve lignocellulosic biomass and facilitate better saccharification. The cellulase immobilized on magnetic nanoparticles was used for in situ saccharification of [EMIM][Ac] pretreated sugarcane bagasse and wheat straw for two cycles. The structural deconstruction and decrease in biomass crystallinity was confirmed by SEM, XRD and FTIR. The high hydrolysis yields (∼89%) obtained in this one-pot process coupled with IL stability and recycled use of immobilized cellulase, potentiates its usefulness in biorefineries. [ABSTRACT FROM AUTHOR]

Published

2017

12. Characterization and Thermal Degradation of Rice Husk via TGA.

Author

Md. Isa, Khairuddin, Maung Maung Soe, Ab Rahim, Mohd Asri, Abdullah, Mohd Fauzi, Ismail, Khudzir, Ahmad, Razi, and Saad, Saiful Azhar

Subjects

RICE hulls as fuel, ALTERNATIVE fuels, RENEWABLE energy sources, AGRICULTURAL wastes as fuel, BIOMASS energy, THERMOGRAVIMETRY, PYROLYSIS, LIGNINS

Abstract

New and renewable fuels are the major alternative to conventional fossil fuels. Biomass is a form of agricultural residues and is becoming popular among new renewable energy sources especially in an agricultural country such as Malaysia. Among the biomass, rice husk represents one of the highest agricultural wastes in Malaysia. Pyrolysis of biomass is one of the most important thermal conversion processes to produce bio-oil. The aim of the present study is to determine the characteristics and thermal degradation behavior of rice husk via thermal gravimeiric analysis (TGA). Chemical analyses show that rice husk contains a high amount of organic constituents of hemi-cellulose (24%), cellulose (29%), and lignin (12.2%). Furthermore, the TG results show that the lignin is relatively more thermally stable than hemi-cellulose and cellulose. Evaluation of biomass resources as potential feedstock for conversion to bio-fuel generally requires information about proximate analysis, ultimate analysis, organic component analysis (hemi-cellulose, cellulose and lignin contents), and calorific value determination. [ABSTRACT FROM AUTHOR]

Published

2009

13. Potential of microalgae cultivation using nutrient-rich wastewater and harvesting performance by biocoagulants/bioflocculants: Mechanism, multi-conversion of biomass into valuable products, and future challenges.

Author

Kurniawan, Setyo Budi, Ahmad, Azmi, Imron, Muhammad Fauzul, Abdullah, Siti Rozaimah Sheikh, Othman, Ahmad Razi, and Hasan, Hassimi Abu

Subjects

*MICROALGAE, *BIOMASS, *HARVESTING, *SEWAGE, *BIOMASS conversion

Abstract

Microalgae have been identified as one of the new feedstocks for renewable energy production. The conversion of microalgae into various valuable products has also been increasing in the last decade. Microalgae harvesting, one of the most important stages in microalgae production, has been studied and reviewed by many researchers. However, most harvesting methods still utilize chemicals during the process, which make harvested biomass not directly ready for food/feed production and pharmaceutical-related processes. Biocoagulants/bioflocculants are emerging compounds that can be used during the harvesting of microalgae because their existence does not introduce toxicity in the harvested biomass. Considering its potential to produce ready-to-use biomass, biocoagulants/bioflocculants have a bright future in microalgal biomass production processes. This review article highlights simultaneous wastewater treatment and microalgal biomass production as an emerging method in accommodating a circular economy paradigm. This paper juxtaposes the utilization of chemical-based coagulants/flocculants and biocoagulants/bioflocculants in harvesting microalgae. Biodegradability, effectiveness, harvested biomass characteristics, and potential of medium reuse are emphasized in the discussion. The agglomeration mechanisms of microalgae during harvesting, recent advances in the microalgal biomass conversions, and future challenges related to the utilization of biocoagulants/bioflocculants are also described in detail. Microalgae harvesting by using biocoagulants/bioflocculants is a feasible and promising environmentally friendly technology for microalgal biomass production. [Display omitted] • Performances of microalgae harvesting using biocoagulants/bioflocculants are discussed. • Cultivation of microalgae using wastewater is discussed. • Mechanisms of microalgae harvesting are elaborated. • Conversion of microalgae biomass into valuable products are highlighted. • Future challenges on algae harvesting using biocoagulants/bioflocculants are discussed. [ABSTRACT FROM AUTHOR]

Published

2022