Optimization of lipid production for algal biodiesel in nitrogen stressed cells of <i>Dunaliella salina</i> using <scp>FTIR</scp> analysis

Liu, Junying; Mukherjee, Joy; Hawkes, Jeremy J.; Wilkinson, Stephen J.

doi:10.1002/jctb.4027

Cited by 59 publications

(42 citation statements)

References 19 publications

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“…S5b), which is characteristic for carotenoids. In addition, a hydroxyl band close to 3277 cm − 1 [39] is clearly visible originating from the presence of lutein and zeaxanthin. On the other hand, the band at 1740 cm − 1 characteristic for C_O has been diminished very much compared to the FTIR spectra of spray dried alga (Fig.…”

Section: Tablementioning

confidence: 95%

Algal products beyond lipids: Comprehensive characterization of different products in direct saponification of green alga Chlorella sp.

et al. 2015

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Section: Tablementioning

confidence: 95%

Algal products beyond lipids: Comprehensive characterization of different products in direct saponification of green alga Chlorella sp.

et al. 2015

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“…In parallel, intensive research is devoted to CO 2 utilization for producing fuel and products [54], and among them microalgae cultivation has gained significant research interest [55,56]. The diverse array of the algae research activities includes microalgae strain selection and lipid yield enhancement, [57][58] microalgae cultivation and dewatering [59], oil-extraction and different upgrading methods [60][61][62][63][64][65][66][67] With the aim of enhancing the overall biofuel yields and improving the environmental impacts, the present research proposes an integrated biorefinery comprising of biomass pyrolysis, in addition to solvent-based carbon capture and utilization through microalgae cultivation. The process integration is based on the synergies between the processing steps of these processes, as shown in Fig.…”

Section: H60322 O25828) Ismentioning

confidence: 99%

Integrated biorefineries: CO2 utilization for maximum biomass conversion

Sharifzadeh

Wang

Shah

2015

Renewable and Sustainable Energy Reviews

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Biomass-derived fuels can contribute to energy sustainability through diversifying energy supply and mitigating carbon emissions. However, the biomass chemistry p`oses an important challenge, i.e., the effective hydrogen to carbon ratio is significantly lower for biomass compared to petroleum, and biomass conversion technologies produce a large amount of carbon dioxide by-product. Therefore, CO2 capture and utilization will be an indispensable element of future biorefineries. The present research explores the economic feasibility and environmental performance of utilizing CO2 from biomass pyrolysis for biodiesel production via microalgae. The results suggest that it is possible to increase biomass to fuel conversion from 55% to 73%. In addition, if subsidies and fuel taxes are included in the economic analysis, the extra produced fuel can compensate the cost of CO2 utilization, and is competitive with petroleum-derived fuels. Finally, the proposed integrated refinery shows promise as CO2 in the flue gas is reduced from 45% of total input carbon to 6% with another 19% in biomass residue waste streams.

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“…Despite the higher lipid content , the actual lipid yield can be lower under nutrient stress than in nutrient replete conditions due to a much lower growth rate (Sheehan et al 1998;Liu et al 2013). Unfortunately not all microalgal lipids are suitable for conversion to biodiesel by trans-esterification (Chisti 2007).…”

Section: Biodiesel and Trans-esterificationmentioning

confidence: 99%