Algal biomass valorization for biofuel production and carbon sequestration: a review

Sarwer, Asma; Hamed, Seham M.; Osman, Ahmed I.; Jamil, Farrukh; Al-Muhtaseb, Ala’a H.; Alhajeri, Nawaf S.; Rooney, David

doi:10.1007/s10311-022-01458-1

Cited by 166 publications

(44 citation statements)

References 222 publications

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“…In the USA, a model study confirmed that pure CO 2 from the corn ethanol production process could be used for algae cultivation in an open pond, thus reducing GHG emission and water stress and can avoid the energy-intensive carbon capturing process for CCU (68). A wide range of value-added products for industrial applications can also be produced from algae-based biomass, such as food, feed and cosmetics (69). It seems that algae have a promising future not only for removing atmospheric CO 2 but also can play an important role in producing food, feed and biofuels.…”

Section: Seaweed/algaementioning

confidence: 99%

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Prospects of carbon capture, utilization and storage for mitigating climate change

Roy

Mohanty

Misra

2023

Environ. Sci.: Adv.

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Section: Seaweed/algaementioning

confidence: 99%

“…68 A wide range of value-added products for industrial applications can also be produced from algae-based biomass, such as food, feed and cosmetics. 69 It seems that algae not only have a promising future for removing atmospheric CO 2 but also can play an important role in producing food, feed and biofuels.…”

Section: Seaweed/algaementioning

confidence: 99%

Prospects of carbon capture, utilization and storage for mitigating climate change

Roy

Mohanty

Misra

2023

Environ. Sci.: Adv.

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“…Such efficient sequestration of carbon by microalgae can theoretically generate ∼65 million tons of biofuel, costing around $8.52/gallon . On average, microalgal farming in an open/closed system can utilize ∼513 tons of CO 2 to generate ∼280 tons of dry biomass/hectare annually . Such carbon fixation efficacy of microalgal cells not only provides biomass/biofuels but also has greener prospects of remediating industrial flue gases that are rich in CO 2 .…”

Section: Microalgae As An Efficient Model For Capturing Carbon and Pr...mentioning

confidence: 99%

“…For example, with the aeration level of 10–20% CO 2 , Chaetoceros muelleri achieved high lipid productivity of 51 mg L –1 day –1 . Other marine strains, such as Nannochloropsis sp., Isochrysis sp., Chlorella salina, Pavlova salina, etc., having oil-rich biomass, have also been explored for their adaptability to varying amounts of CO 2 . Further, the species ability to fix CO 2 and produce bioenergy is primarily dependent upon the specificities of the microalgal physiology and the environmental conditions.…”

Section: Microalgae As An Efficient Model For Capturing Carbon and Pr...mentioning

confidence: 99%

Microalgal-Based Bioenergy: Strategies, Prospects, and Sustainability

2022

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The fuel crisis with the slumping reserves of fossil fuels and the exponential increase in the demand of energy necessitate a paradigm shift to a more sustainable and eco-friendly energy system. Microalgal biofuel has been recognized as one of the most prominent and versatile alternative renewable energy sources because it can be converted into a wide array of biofuels, such as biodiesel, bioethanol, bioelectricity and biogases such as syngas, methane, hydrogen, and hythane etc., with a lower carbon emission profile. To attain the economic viability of algal fuels, a collective biorefinery approach addressing both the operational and technical limitations is quintessential. The current review critically analyzes and categorizes energy aspects of microalgae through various direct and indirect approaches with the perspective of a circular economy. These approaches include complicated thermochemical and biochemical processes integrating the recovery of a wide range of value-added products apart from biofuels, thus defining a cascading approach for a multiproduct-based biorefinery model. A glimpse of recent technological advancements comprising hybrid cultivation systems, prospects of co-culturing, and the role of automated/modeling approaches in the industrial-scale production of "algal-based bioenergy" is also discussed in detail. Further, the review has also scrutinized and highlighted the developments and bottlenecks in genetic and molecular aspects of strain improvement for bioenergy production. Furthermore, the study also correlated the socioeconomic and environmental impacts of producing this green energy by evaluating the prospects and pitfalls to obtain a holistic picture on this alternative fuel for a bio-based sustainable economy.

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“…The use of biomass wastes as starting materials has sparked intense research interest due to their physiochemical stability, light weight, low cost, and environmental friendliness (Aslam et al 2021). Oil palm biomass is an efficient source of carbon for conversion to high-value products especially palm kernel shells (PKS) as activated carbon precursors (Norrrahim et al 2022;Sarwer et al 2022). The high carbon percentage in PKS is promising for the production of activated carbon (AC), as it contributes to a high product yield.…”

Section: Introductionmentioning

confidence: 99%

Activation temperature and particle size of palm kernel shell vs. the surface properties of activated carbon

Lee

Chin

H’ng

et al. 2023

BioRes

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Granular activated carbon (GAC) and powdered activated carbon (PAC) are the two most common forms of activated carbon with varying particle size range. The goal of this study was to analyze the key factors (particle size and activation temperature) affecting the surface characteristics of GAC and PAC derived from palm kernel shell (PKS). The surface morphology suggested that the pore network in PKS-PAC is more developed than that in PKS-GAC owing to the presence of a micropore structure when prepared at lower activation temperatures. This study also demonstrated that activation performed on different PKS particle size range influenced the mesopore domain of the activated carbon produced. The PKS-GAC was found to have more mesopores than PKS-PAC, which made it more reliable for dye adsorption in water treatment. Overall, this study demonstrated that applying different particle size range of PKS during the activation process can have a significant influence on the surface characteristics, thus having a direct impact on the application of activated carbon. An accurate particle size range will ensure that the most cost-effective activated carbon is selected to achieve the desired performance objectives.

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Algal biomass valorization for biofuel production and carbon sequestration: a review

Cited by 166 publications

References 222 publications

Prospects of carbon capture, utilization and storage for mitigating climate change

Prospects of carbon capture, utilization and storage for mitigating climate change

Microalgal-Based Bioenergy: Strategies, Prospects, and Sustainability

Activation temperature and particle size of palm kernel shell vs. the surface properties of activated carbon

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