Your search keyword '"Mofijur, M."' showing total 15 results

1. Sustainable production of lutein—an underexplored commercially relevant pigment from microalgae

Author

Muhammad, Gul, Butler, Thomas O., Chen, Bailing, Lv, Yongkun, Xiong, Wenlong, Zhao, Xinqing, Solovchenko, A. E., Zhao, Anqi, Mofijur, M., Xu, Jingliang, and Alam, Md. Asraful

Abstract

Graphical abstract:

Published

2024

2. Environmental and human health impact of single-use plastic-made personal protective equipment used to limit the spread of SARS-CoV-2.

Author

Zakia, Marzuka Ahmed, Akter, Shirin, Rony, Zahidul Islam, Rahaman, Mizanur, Ahmed, Shams Forruque, Vo, Dai-Viet N., and Mofijur, M.

Subjects

PERSONAL protective equipment, ENVIRONMENTAL health, SURGICAL gloves, QUARANTINE, SARS-CoV-2, COVID-19 pandemic, MEDICAL wastes, SINGLE-use plastics

Abstract

The novel Coronavirus (SARS-CoV-2) has wreaked havoc throughout the world, affecting nearly every country. Several countries are currently battling the virus's second or third wave, which is wreaking havoc far worse than the first. A variety of plastic-based personal protective equipment (PPE) was instrumental in protecting people during the COVID-19 pandemic. Every day, a significant amount of single-use PPE including masks, gloves, protective aprons, face shields, safety glasses, sanitiser containers, plastic shoes, and medical gowns (made primarily of polypropylene) is discarded by health care workers and the general public. While this personal protective equipment is lowering the spread of SARS-CoV2, the lacking of sustainable management possesses a serious threat to public health and the environment. As the SARS-CoV-2 virus can survive in discarded medical waste for up to 168 hours, likely, the medical waste originating from hospitals, clinics, medical centres, home isolation, and quarantine facilities where the infected individual is getting treatment could spread and increase the infectivity of the virus. Therefore, this paper discusses the environmental and human health consequences of single-use personal protective equipment used to reduce the spread of SARS-CoV-2. [ABSTRACT FROM AUTHOR]

Published

2023

3. Bio-oil from microalgae: Materials, production, technique, and future

Author

Ahmed, Shams Forruque, Rafa, Sabiha Jannat, Mehjabin, Aanushka, Tasannum, Nuzaba, Ahmed, Samiya, Mofijur, M., Lichtfouse, Eric, Almomani, Fares, Badruddin, Irfan Anjum, and Kamangar, Sarfaraz

Abstract

Because of its low environmental impact and high production, microalgae bio-oil has quickly become a popular renewable fuel option. The process utilizes microalgae which are readily available in nature to produce an alternative to fossil fuel. Although microalgal bio-oil production mechanisms have been previously reviewed in recent studies, comparatively few of them emphasize the significance of algal bio-oil production through all available bio-oil conversion mechanisms from microalgae. Here we review the available and common bio-oil conversion processes from microalgae, bio-oil upgrading, and the commercial aspects of its utilization. The most efficient route to bio-oil production can be identified by analysing both the biomass feedstock and the final product. For example, pyrolysis can produce high-energy bio-oil, but it also produces large amounts of char and gas. Although hydrothermal liquefaction and gasification are more complex and costly, they have the potential to produce bio-oil with greater consistency. However, the expense of using bio-oil in a commercial context is a major concern. The cost of producing bio-oil from microalgae is typically higher than that of producing conventional fossil fuels. Several factors, including cost, availability, and necessary infrastructure, contribute to the uncertainty of bio-oil’s commercial feasibility. With the constant improvements in technology and government support, however, bio-oil has the potential to emerge as a viable alternative to conventional fossil fuels.

Published

2023

4. Waste biorefinery to produce renewable energy: Bioconversion process and circular bioeconomy

Author

Ahmed, Shams Forruque, Kabir, Maliha, Mehjabin, Aanushka, Oishi, Fatema Tuz Zuhara, Ahmed, Samiya, Mannan, Samiha, Mofijur, M., Almomani, Fares, Badruddin, Irfan Anjum, and Kamangar, Sarfaraz

Abstract

Continual global energy scarcity and its future challenges, as well as environmental disasters, are causing global devastation. Additionally, a substantial quantity of food is being wasted regularly. Therefore, the adoption of circular bioeconomy principles and the bioconversion of wasted food appears to be both highly advantageous and urgently required. However, previous studies have placed limited emphasis on the technological progress and circular bioeconomy aspects associated with the bioconversion of wasted food. The present review thus investigates how mass-generated food waste can be used to produce valuable bioproducts through bioconversion techniques such as oleaginous metabolism, anaerobic fermentation, and solventogenesis. These techniques have attracted considerable interest due to their eco-friendly and resource-recycling capacities, as well as their efficiency and sustainability. The paper also discusses approaches to integrate biorefineries within existing economies to establish a circular bioeconomy and analyses the challenges as well as the techno-economic, environmental and life cycle scenarios of these approaches. Analysis of the techno-economic and environmental effects reveals that food waste biorefineries can be lucrative if certain pathways are maintained. The environmental impact of bioconversion methods that produce valuable bioproducts is also found to be substantially lower than that of conventional methods. Integrating bioconversion processes further improves the efficiency of the process and sustainably recovers resources. Developing a circular bioeconomy requires the adoption of a biorefinery strategy with an integrated approach.

Published

2023

5. Effect of butanol additive on the performance and emission of Australian macadamia biodiesel fuel in a diesel engine

Author

Mofijur, M., primary, Rasul, M. G., additional, and Hassan, N. M. S., additional

Published

2017

6. Utilization of nanomaterials in accelerating the production process of sustainable biofuels

Author

Ahmed, Shams Forruque, Debnath, J.C., Mehejabin, Fatema, Islam, Nafisa, Tripura, Ritu, Mofijur, M., Hoang, Anh Tuan, Rasul, M.G., and Vo, Dai-Viet N.

Abstract

[Display omitted]

Published

2023

7. Perovskite solar cells: Thermal and chemical stability improvement, and economic analysis

Author

Ahmed, Shams Forruque, Islam, Nafisa, Kumar, P. Senthil, Hoang, Anh Tuan, Mofijur, M., Inayat, Abrar, Shafiullah, G.M., Vo, Dai-Viet N., Badruddin, Irfan Anjum, and Kamangar, Sarfaraz

Abstract

Perovskite solar cells (PSCs) are highly efficient and are comparatively cheaper than the large silicon crystals primarily used in solar cells. Their outstanding photovoltaic performance makes them a potential alternative to silicon solar cells. While efficiency and photovoltaic performance have been investigated in recent decades, a knowledge gap on the degradation, economic feasibility and stability of PSCs exists, and their poor stability remains a barrier to commercialization. Thus, this review aims to fill this knowledge gap by focusing on approaches to improve PSCs’ thermal and chemical stability, and their economic viability under different conditions. The structure and manufacture of PSCs are also discussed along with an economic analysis of different perovskite devices. Improvements in thermal stability can be reached by incorporating inorganic materials into the PSC. A PSC model optimized with ZnO improves chemical stability by 8% and works well under low temperatures. To make PSCs more economically feasible, certain parts like counter electrodes (CE) and hole transport materials (HTMs) can be replaced with alternative elements like carbon and inorganic HTMs, respectively. PSCs with long durability and high conversion efficiency will expand the commercial prospects for this material. To bridge the lack of knowledge, further investigation is required on the sustainability and longevity of PSCs.

Published

2023

8. A review on socio-economic aspects of sustainable biofuels

Author

Azad, Abul Kalam, Rasul, Mohammad G., Khan, M. Masud K., Sharma, Subhash C., Bhuiya, M. Mostafa K., and Mofijur, M.

Abstract

Biofuels are renewable eco-fuel, produced from biological resources. They are classified into 1st, 2nd and 3rd generations based on their feedstocks. The 2nd and 3rd generation biofuels are called advanced and sustainable biofuel. The study reviewed and discussed about socio-economic aspects of the sustainable biofuel in Australia because economy is seen to be a key driver for use of biofuels. Recent researches focused on sustainable biofuel production, their commercialisation worldwide. The world biofuel scenario is presented in this study which shows that total biofuel production is progressively moving towards advanced biofuels. Australian total biofuel production, consumption and available present production facilities are also outlined. The study briefly discussed about Australian energy economy such as energy export, import and trades etc. The study concluded that the 2nd generation biofuel can be considered as sustainable alternatives to petroleum fuel in transport sector providing great economic and environmental benefits to Australia.

Published

2016

9. Study on the tribological characteristics of plant oil-based bio-lubricant with automotive liner-piston ring materials

Author

Shahabuddin, M., Mofijur, M., Rizwanul Fattah, I.M., Kalam, M.A., Masjuki, H.H., Chowdhury, M.A., and Hossain, Nayem

Abstract

The development of bio-lubricant is an immerging area of research considering the rapid depletion of petroleum reserve and environmental concern. This study aims to develop non-edible jatropha oil-based bio-lubricant and investigate the tribological properties considering commonly used piston ring-cylinder liner materials of stainless steel and cast iron due to their interaction under lubricated conditions in an internal combustion engine. The bio-lubricant was prepared by blending different percentages of vegetable oil with commercial lubricants. The tribological test was carried out using a Reo-Bicerihigh-frequency reciprocating rig (HFRR) for the duration of 6 h under standard operating conditions. Different properties of bio-lubricants were measured before and after the HFRR test using various analytical instruments. The morphology of the worn material surfaces was examined via Hitachi S-4700 FE-SEM cold field emission high resolution scanning electron microscopy (SEM). The result showed that addition of vegetable oil lubricant up to 7.5% concentration can be compared with commercial lubricant in case of wear rate and coefficient of wear as weight loss reduced significantly. Minimum change in viscosity was observed at the addition of 7.5% bio-lubricant. Surface morphology analysis confirmed less damage of metal surface when tribological analysis were performed at mixed lubricated condition.

Published

2022

10. Thermal efficiency analysis of the phase change material (PCM) microcapsules

Author

Mazlan, M., Rahmani-dehnavi, M., Najafi, G., Ghobadian, B., Hoseini, S.S., Fayyazi, E., Mamat, R., Alenezi, Raslan A., and Mofijur, M.

Abstract

The aim of the present study is to evaluate the thermal behavior of cylindrical modules in a thermal energy storage unit as a combined sensible and latent heat. A thermal energy storage unit is designed, fabricated, and connected to a cold and hot water supply at constant temperatures to monitor the performance of the storage unit. The thermal energy storage unit contains the cylindrical microcapsules containing paraffin waxes as a phase change material which is located inside an insulating cylinder storage tank. Water is used as a heat transfer fluid to transfer heat from a hot water reservoir to the thermal energy storage unit during the phase change material charging process and also during the discharging process water receives heat from the thermal energy storage unit. Charge tests are carried out at the constant temperature. Moreover, the effect of different inlet flow on storage unit performance is investigated. Data were analyzed using Design Expert software and regression analysis which indicated that the increase of charge inlet temperature and charge inlet flow leads to the increase of heat power, thermal performance of thermal energy storage unit, and output variables. In comparison to the heat storage system without phase change material, microcapsules phase change material can improve the heat power of the heat storage system. Also, based on the optimization process, the maximum thermal performance of 96.4% and the maximum heat power level of 1.7 kW can be achieved in the optimized condition of the charging inlet temperature of 75 °C, charging inlet flow of 1.8−4 m3/s, and discharging inlet temperature of 35 °C.

Published

2021

11. A critical review on the development and challenges of concentrated solar power technologies

Author

Shahabuddin, M., Alim, M.A., Alam, Tanvir, Mofijur, M., Ahmed, S.F., and Perkins, Greg

Abstract

Solar energy is considered to be one of the most promising renewable and sustainable energy sources. Two key technologies such as photovoltaic and concentrated solar power are mainly used to convert solar radiation, out of which photovoltaic directly converts solar radiation into electricity, while concentrated solar power technology converts solar radiation both into heat and electricity. The key advantages of concentrated solar power technology over photovoltaic is its capability of storing heat energy which can be utilised in the absence of sunlight, overcoming the limitation of the intermittent nature of solar power. Currently, the cost for the concentrated solar power with storage is about 9.0 ¢/kWh (same as commercial photovoltaic system), which is expected to drop at ~5.0 ¢/kWh by 2030. Besides four mainstream concentrated solar power technologies, this paper reviewed the application of concentrated solar power in thermolysis, thermochemical cycle, hydrocarbon cracking, reforming and solar gasification. Based on the literature review, this study has outlined the key challenges and prospects of concentrated solar power technologies. The main challenge in thermolysis is the requirement of very high temperature, while the thermochemical cycle is inefficient. Solar thermal cracking, reforming, and gasification integrate carbonaceous fuel to produce synthesis gas and hydrogen and therefore are not emission-free. The concentrated solar power technologies require further development and cost reductions before they can be scaled up to have a meaningful impact on renewable energy targets towards 2050.

Published

2021

12. Bioenergy recovery potential through the treatment of the meat processing industry waste in Australia

Author

Mofijur, M., Fattah, I.M. Rizwanul, Kumar, P. Senthil, Siddiki, Sk. Yasir Arafat, Rahman, S. M. Ashrafur, Ahmed, S.F., Ong, Hwai Chyuan, Lam, Su Shiung, Badruddin, Irfan Anjum, Khan, T.M. Yunus, and Mahlia, T.M.I.

Abstract

The farm animal and meat processing industry generate waste, including manure, fat, blood, sludge, bones, and wastewater, which create environmental problems worldwide. The effluents generated by this industry are rich in proteins, lipids, fibres, and carbohydrates. All these pollutants have the potential to be used as a resource for energy recovery. The organic matters obtained from the farm animal and meat processing industry are critical sources for biogas production via anaerobic digestion. This process leads to the production of energy-rich biogas, reducing greenhouse gas emissions. This study attempts to determine biogas amount and the energy value produced from the farm animal and meat processing industry in Australia. Australia's livestock population mainly consists of dairy cattle, meat cattle, sheep and lambs, pigs, layers, and meat chickens. Results show a potential biogas amount of 23,874,165 million m3(Mm3), 215,670 Mm3, 288,228 Mm3, 18,430 Mm3,and 392,284 Mm3can be obtained from cattle, lamb, sheep, pig, and poultry annually, respectively. The methane generated from slaughterhouse waste and wastewater is estimated to provide 4.52E+ 14 MJ/yr of heat energy with total electricity generation potential from livestock wastes of 4.4E+ 13 kWh/yr. About half of the electricity can be generated in Queensland State. Finally, the present study suggests farm animal and meat processing industry effluent as a potential sustainable energy source in Australia.

Published

2021

13. Theoretical calculation of biogas production and greenhouse gas emission reduction potential of livestock, poultry and slaughterhouse waste in Bangladesh

Author

Siddiki, Sk. Yasir Arafat, Uddin, M.N., Mofijur, M., Fattah, I.M.R., Ong, Hwai Chyuan, Lam, Su Shiung, Kumar, P. Senthil, and Ahmed, S.F.

Abstract

The utilisation of available renewable resources and mitigating their impact on the environment boosts sustainable development and helps to achieve the United Nations Sustainable Development Goals. Biogas is a renewable energy option produced through anaerobic digestion of wastes such as livestock excreta and slaughterhouse wastes. Biogas production is treated as one of the leading processes to combat climate change as well as a waste management strategy, especially for a developing country like Bangladesh. It is also vital in meeting future demand for energy utilising indigenous sources. Livestock farming is an important economic activity in rural areas of Bangladesh. Thus, the livestock waste production, estimated biogas generation capacity, electricity generation potential, greenhouse gas (GHG) reduction potential, and estimated biofertiliser generation capacity of Bangladesh were determined for the financial year 2018–2019 in this study. The results show that Bangladesh had 486.77 million tons per year of animal waste products to produce 27,923.72 million m3/year biogas in 2018–2019. This biogas potential corresponds to a theoretical potential to produce a 512 PJ/year heating value and electric power of 50 TW h/year. Besides, about 29.232 million tons per year of organic fertiliser can be produced with the residues of the biogas plants. The findings of this study will contribute to guiding policymakers and governments who will concentrate on the use of animal waste in biogas industries and livestock farming as a potential bioenergy source to meet national energy demand.

Published

2021

14. A systematic review on graphene-based nanofluids application in renewable energy systems: Preparation, characterization, and thermophysical properties

Author

Sandhya, Madderla, Ramasamy, D., Sudhakar, K., Kadirgama, K., Samykano, M., Harun, W.S.W., Najafi, G., Mofijur, M., and Mazlan, Mohamed

Published

2021

15. Impact of partial alteration of diesel fuel on the performance and regulated emission of a diesel engine

Author

Rahaman, Mizanur, Hasan, Md Ikramul, Mofijur, M., Rasul, M.G., Hassan, N.M.S., and Ong, Hwai Chyuan

Abstract

Biodiesel has become one of the promising solutions for the future energy crisis. This study aims to assess the effect of alteration of fuel (replacing diesel with biodiesel) on the performance and regulated emission in a diesel engine. Biodiesel blends (WCB20) was prepared by mixing 20% of waste cooking oil biodiesel with 80% diesel fuel using a homogeneous mixture. The performance and regulated emission of WCB20 have been evaluated in a multi-cylinder diesel engine at various speeds with a full load condition and compared with diesel fuel. The results indicated that WCB20 offers 6.52% less brake power and 9.01% lower brake thermal efficiency whereas, 36.15% and 32.16% higher BSFC and BSEC in comparison to diesel fuel, respectively. However, regulated emission results showed that WCB20 significantly decrease carbon monoxide, particulate matter, and hydrocarbon by 38.93%, 15.46%, and 21.20% respectively but slightly increase the NOxemission (13.79%). Finally, it can be concluded that partial alteration of conventional diesel fuel using 20% waste cooking oil biodiesel can indicatively reduce the harmful emission.

Published

2021