Batch bioethanol production via the biological and chemical saccharification of some Egyptian marine macroalgae

Soliman, Ramadan M.; Younis, Sherif A.; El‐Gendy, Nour Sh.; Mostafa, Salwa M.; El‐Temtamy, Seham A.; Hashim, A.I.

doi:10.1111/jam.13886

Cited by 42 publications

(12 citation statements)

References 54 publications

(86 reference statements)

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“…The maximum ethanol yield for Ethanol Red ® was 87.7% (9.95 g of ethanol/L), while PE2 and the laboratory strain CEN.PK 113-7D were near of 100% (11.65 and 11.32 g of ethanol/L, respectively). In only 8.5 h, ethanol yields between 87 and 95% are achieved, pretty much faster than with other macroalgae and/or pretreatments [35,36]. As example, after 8.5 h of SSF, the yields obtained with the different strains were 87.1% with Ethanol Red ® (instead maximum values of 87.7% at 23.6 h), 95.3% with PE2 and 94.4% with CEN.PK 113-7D (instead 100% after 28.6 h), that means 93e99% of maximum yield in only 8.5 h.…”

Section: Simultaneous Saccharification and Fermentation With Differenmentioning

confidence: 96%

Third generation bioethanol from invasive macroalgae Sargassum muticum using autohydrolysis pretreatment as first step of a biorefinery

Río

Domínguez

et al. 2019

Renewable Energy

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Sargassum muticum, an invasive macroalgae in Europe, was employed as material for third generation bioethanol production. As a first step, autohydrolysis was chosen as an eco-friendly pretreatment, seeking for a high enzymatic susceptibility of the solid phase and high content of hexoses as glucose, galactose and mannose, in both liquid and solid phases, which can be subsequently transformed in ethanol via fermentation. Besides, the search of a minimum consumption of energy in the pretreatment is also a key challenge in bioethanol production. At optimum conditions of autohydrolysis pretreatment, more than 90% of the glucan was recovered in the solid phase (while the other 10% appeared as glucooligosaccharides and glucose in the liquid phase). In the enzymatic hydrolysis carried out with the solid phases, glucan to glucose conversions of 94 and 89% were obtained, with the solid mixed with water and the whole slurry, respectively. Moreover, the whole slurry experiments, where all hexoses present in the raw material (glucose, galactose and mannose) from the solid and the liquid phases are fermented, allows to reach maximum ethanol yields of 80% (14.10 g of ethanol/L) referred to the theoretical yield, in a short time.

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Section: Simultaneous Saccharification and Fermentation With Differenmentioning

confidence: 96%

Third generation bioethanol from invasive macroalgae Sargassum muticum using autohydrolysis pretreatment as first step of a biorefinery

Río

Domínguez

et al. 2019

Renewable Energy

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“…Biochemical data for samples identified with this name were provided in several studies performed mainly by northern African investigators. These examined the content of chemical contaminants in environmental monitoring (Al-Masri et al, 2003;Abdallah and Abdallah, 2008;Olgunoglu and Polat, 2008;Hernández et al, 2011;Laib and Legouchi, 2012), biological activities of algal extracts (Abd-Elnaby, 2010; Khairy and El-Sheikh, 2015) and biochemical composition in relation to nutritional value Ozogul, 2009, 2013) or for biodiesel production (El Maghraby and Fakhry, 2015;Soliman et al, 2018).…”

Section: Biochemistry and Physiologymentioning

confidence: 99%

Coralline Algae in a Changing Mediterranean Sea: How Can We Predict Their Future, if We Do Not Know Their Present?

et al. 2019

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“…Tapia-Tussell et al, (2018) applied the Bm-2 strain of Trametes hirsuta, resulting in a degradation of fibers and the creation of gaps on the macroalgae surface. Although good results can be obtained, the use of biological pretreatments usually implies long-time pretreatments and/or its combination with other pretreatments, especially chemical pretreatments with dilute-acid or mild-alkali hydrolysis (Soliman et al, 2018;Thompson et al, 2019).…”

Section: Biological Pretreatmentmentioning

confidence: 99%

“…In this way, algae are the third generation feedstock and currently stand out as a potential biomass to obtain biofuels (Michalak, 2018) due to some advantages such as: i) ubiquity, ii) low rate of biomass fluctuation owing to overpopulation, iii) production of the majority of oxygen in the planet with a high absorption of annual CO 2 , iv) higher photosynthetic efficiency (6-8%) than terrestrial biomass (1.8-2.2%), v) low consumption of water, vi) no alteration of human food supply, vii) no competition for arable land, viii) capacity of growing in a wide range of territories like saline water or wastewater, ix) absence or low lignin content; x) potential to obtain high-added value products (cosmetics, drugs, pigments, biofertilizers, food additives…) and xi) ability to achieve larger production rates of biomass than land-based feedstock (in terms of land surface employed) (Rodríguez-Jasso et al, 2013;Ruiz et al, 2013;Sirajunnisa and Surendhiran, 2016). In a recent study, the US Energy Department has estimated (under specific conditions) that the biofuel productivity from seaweed is two and five-fold higher than ethanol productivity obtained from sugarcane and corn, respectively (Soliman et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

Recent trends on seaweed fractionation for liquid biofuels production

Río

Gomes-Dias

Rocha

et al. 2020

Bioresource Technology

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Concerns about fossil fuels depletion has led to seek for new sources of energy. The use of marine biomass (seaweed) to produce biofuels presents widely recognized advantages over terrestrial biomasses such as higher production ratio, higher photosynthetic efficiency or carbon-neutral emissions. In here, interesting seaweed sources as a whole or as a residue from seaweed processing industries for biofuel production were identified and their diverse composition and availability compiled. In addition, the pretreatments used for seaweed fractionation were thoroughly revised as this step is pivotal in a seaweed biorefinery for integral biomass valorization and for enabling biomass-to-biofuel economic feasibility processes. Traditional and emerging technologies were revised, with particular emphasis on green technologies, relating pretreatment not only with the type of biomass but also with the final target product(s) and yields. Current hurdles of marine biomass-to-biofuel processes were pinpointed and discussed and future perspectives on the development of these processes given.

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Batch bioethanol production via the biological and chemical saccharification of some Egyptian marine macroalgae

Abstract: The usage of marine macroalgae (i.e. seaweeds) as feedstock for bioethanol; an alternative and/or complimentary to petro-fuel, would act as triple fact solution; bioremediation process for ecosystem, renewable energy source and economy savings.

Cited by 42 publications

References 54 publications

Third generation bioethanol from invasive macroalgae Sargassum muticum using autohydrolysis pretreatment as first step of a biorefinery

Third generation bioethanol from invasive macroalgae Sargassum muticum using autohydrolysis pretreatment as first step of a biorefinery

Coralline Algae in a Changing Mediterranean Sea: How Can We Predict Their Future, if We Do Not Know Their Present?

Recent trends on seaweed fractionation for liquid biofuels production

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