Mohd Ali Hassan scite author profile

Hydrogen is a clean energy carrier which has a great potential to be an alternative fuel. Abundant biomass from various industries could be a source for biohydrogen production where combination of waste treatment and energy production would be an advantage. This article summarizes the dark fermentative biohydrogen production from biomass. Types of potential biomass that could be the source for biohydrogen generation such as food and starch-based wastes, cellulosic materials, dairy wastes, palm oil mill effluent and glycerol are discussed in this article. Moreover, the microorganisms, factors affecting biohydrogen production such as undissociated acid, hydrogen partial pressure and metal ions are also discussed.

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Determination of multiple thermal degradation mechanisms of poly(3-hydroxybutyrate)

Ariffin

Nishida

Shirai

et al. 2008

Polymer Degradation and Stability

103

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Modification of Oil Palm Mesocarp Fiber Characteristics Using Superheated Steam Treatment

et al. 2013

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Abstract:In this study, oil palm mesocarp fiber (OPMF) was treated with superheated steam (SHS) in order to modify its characteristics for biocomposite applications. Treatment was conducted at temperatures 190-230 °C for 1, 2 and 3 h. SHS-treated OPMF was evaluated for its chemical composition, thermal stability, morphology and crystallinity. OPMF treated at 230 °C exhibited lower hemicellulose content (9%) compared to the OPEN ACCESSMolecules 2013, 18 9133 untreated OPMF (33%). Improved thermal stability of OPMF was found after the SHS treatment. Moreover, SEM and ICP analyses of SHS-treated OPMF showed that silica bodies were removed from OPMF after the SHS treatment. XRD results exhibited that OPMF crystallinity increased after SHS treatment, indicating tougher fiber properties. Hemicellulose removal makes the fiber surface more hydrophobic, whereby silica removal increases the surface roughness of the fiber. Overall, the results obtained herewith suggested that SHS is an effective treatment method for surface modification and subsequently improving the characteristics of the natural fiber. Most importantly, the use of novel, eco-friendly SHS may contribute to the green and sustainable treatment for surface modification of natural fiber.

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Baseline study of methane emission from anaerobic ponds of palm oil mill effluent treatment

Yacob

Hassan

Shirai

et al. 2006

Science of The Total Environment

168

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The world currently obtains its energy from the fossil fuels such as oil, natural gas and coal. However, the international crisis in the Middle East, rapid depletion of fossil fuel reserves as well as climate change have driven the world towards renewable energy sources which are abundant, untapped and environmentally friendly. Malaysia has abundant biomass resources generated from the agricultural industry particularly the large commodity, palm oil. This paper will focus on palm oil mill effluent (POME) as the source of renewable energy from the generation of methane and establish the current methane emission from the anaerobic treatment facility. The emission was measured from two anaerobic ponds in Felda Serting Palm Oil Mill for 52 weeks. The results showed that the methane content was between 35.0% and 70.0% and biogas flow rate ranged between 0.5 and 2.4 L/min/m(2). Total methane emission per anaerobic pond was 1043.1 kg/day. The total methane emission calculated from the two equations derived from relationships between methane emission and total carbon removal and POME discharged were comparable with field measurement. This study also revealed that anaerobic pond system is more efficient than open digesting tank system for POME treatment. Two main factors affecting the methane emission were mill activities and oil palm seasonal cropping.

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Baseline study of methane emission from open digesting tanks of palm oil mill effluent treatment

et al. 2005

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Adsorption of crude oil from aqueous solution by hydrogel of chitosan based polyacrylamide prepared by radiation induced graft polymerization

Sokker

El‐Sawy

Hassan³

et al. 2011

Journal of Hazardous Materials

219

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Highly selective transformation of poly[(R)-3-hydroxybutyric acid] into trans-crotonic acid by catalytic thermal degradation

Ariffin¹,

Nishida²,

Shirai³

et al. 2010

Polymer Degradation and Stability

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a b s t r a c tHighly selective transformation of poly[(R)-3-hydroxybutyric acid] (PHB) into trans-crotonic acid was achieved by thermal degradation using Mg compounds: MgO and Mg(OH) 2 as catalysts. Through catalytic action, not only the temperature and E a value of degradation were lowered by 40e50 C and 11e14 kJ mol À1 , respectively, but also significant changes in the selectivity of pyrolyzates were observed. Notably, Mg(OH) 2 showed nearly complete selectivity (w100%) to trans-crotonic acid. Kinetic analysis of TG profiles revealed that the catalytic thermal degradation of PHB was initiated by some random degradation reactions, followed by the unzipping b-elimination from crotonate chain-ends as a main process. It was suggested that the Mg catalysts promote the totality of the b-elimination reactions by acting throughout the beginning and main processes, resulting in a lowering in the degradation temperature and the completely selective transformation of PHB.

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Food waste and food processing waste for biohydrogen production: A review

Yasin

Mumtaz

Hassan

et al. 2013

Journal of Environmental Management

196

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Food waste and food processing wastes which are abundant in nature and rich in carbon content can be attractive renewable substrates for sustainable biohydrogen production due to wide economic prospects in industries. Many studies utilizing common food wastes such as dining hall or restaurant waste and wastes generated from food processing industries have shown good percentages of hydrogen in gas composition, production yield and rate. The carbon composition in food waste also plays a crucial role in determining high biohydrogen yield. Physicochemical factors such as pre-treatment to seed culture, pH, temperature (mesophilic/thermophilic) and etc. are also important to ensure the dominance of hydrogen-producing bacteria in dark fermentation. This review demonstrates the potential of food waste and food processing waste for biohydrogen production and provides a brief overview of several physicochemical factors that affect biohydrogen production in dark fermentation. The economic viability of biohydrogen production from food waste is also discussed.

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Mohd Ali Hassan

Biohydrogen production from biomass and industrial wastes by dark fermentation

Determination of multiple thermal degradation mechanisms of poly(3-hydroxybutyrate)

Modification of Oil Palm Mesocarp Fiber Characteristics Using Superheated Steam Treatment

Baseline study of methane emission from anaerobic ponds of palm oil mill effluent treatment

Baseline study of methane emission from open digesting tanks of palm oil mill effluent treatment

Adsorption of crude oil from aqueous solution by hydrogel of chitosan based polyacrylamide prepared by radiation induced graft polymerization

Highly selective transformation of poly[(R)-3-hydroxybutyric acid] into trans-crotonic acid by catalytic thermal degradation

Food waste and food processing waste for biohydrogen production: A review

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