Sustainable design and synthesis of algae‐based biorefinery for simultaneous hydrocarbon biofuel production and carbon sequestration

Gebreslassie, Berhane H.; Waymire, Randall; You, Fengqi

doi:10.1002/aic.14075

Cited by 134 publications

(109 citation statements)

References 56 publications

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“…Gebreslassie et al proposed a detailed superstructure of an algal biorefinery for biofuel production. 15 Despite a large number of technology alternatives included, they focused primarily on the production of algal biofuels, and did not exploit the potential environmental and economic benefits from value-added bioproducts. In order to explore algal biorefinery processes with better economics, Gong et al optimized the performance of algal biorefinery processes for biological carbon sequestration and utilization.…”

Section: Introductionmentioning

confidence: 99%

Value-Added Chemicals from Microalgae: Greener, More Economical, or Both?

Gong

You

2014

ACS Sustainable Chem. Eng.

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110

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This paper addresses the sustainable design and synthesis of manufacturing processes for making algal bioproducts. We propose by far the most comprehensive superstructure capable of producing biodiesel, hydrogen, propylene glycol, glycerol-tert-butyl ether, and poly-3-hydroxybutyrate from microalgae. The major processing sections include cultivation, harvesting, lipid extraction, remnant treatment, biogas utilization, biofuel proneduction, and bioproduct manufacturing. Based on the superstructure, we integrate a cradle-to-gate life cycle analysis and techno-economic analysis with multiobjective optimization to simultaneously optimize the environmental and economic performance. We also apply a tailored global optimization algorithm to efficiently solve the problem in reasonable computation times. Results show that the most environmentally sustainable processes reduce life cycle greenhouse gas emissions per kilogram of the algal bioproducts by 5% to 63%, compared with petrochemical counterparts. In addition, the coproduction of value-added bioproducts in the algal glycerol process helps reduce the biodiesel production cost to as low as $2.79 per gasoline-gallon-equivalent. a complete superstructure which not only incorporates existing technologies for the conversion of algal biodiesel, but also takes advantage of the versatile glycerol and converts it on site to environmentally sustainable and value-added bioproducts. Process integration is an important method in sustainable process design to explore the possibilities of improving the overall process efficiency by utilizing waste streams and ultimately reduce the overall expenditure and environmental impacts of the entire process.Bioproduct manufacturing production has the potential for boosting the algal biodiesel performance by utilizing byproducts in transesterification and generating carbon dioxide feed for microalgae growth. The aim of the current work, therefore, is to explore the potential environmental and economic benefits for the production of both biodiesel and value-added bioproducts from microalgae.In order to bridge the research gap, we develop by far the most comprehensive superstructure, which is able to produce biodiesel and four types of bioproducts, including hydrogen, propylene glycol (PG), glycerol-tert-butyl ether (GE), and poly-3-hydroxybutyrate (PHB). In particular, the hydrogen can be produced by either steam reforming, autothermal reforming, or aqueous-phase reforming. The superstructure also includes a methanol synthesis process in the biogas utilization section. Additionally, we simulate the lipid extraction processes using hexane and n-butanol as extractants for data validation.Based on the proposed superstructure, a cradle-to-gate life cycle analysis (LCA) is performed to account for the life cycle greenhouse gas (GHG) emissions associated with three life cycle stages, namely feedstock acquisition, transportation, and algal biodiesel and bioproduct manufacturing. Following a life cycle optimization methodology, we further integrate the...

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Section: Introductionmentioning

confidence: 99%

Value-Added Chemicals from Microalgae: Greener, More Economical, or Both?

Gong

You

2014

ACS Sustainable Chem. Eng.

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110

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“…Silva et al (2014), Davis et al (2012), Martin and Grossmann (2012) and Lundquist et al (2010) assembled computational models of complete algae-to-biofuels ventures using different assumptions, methods, and processing cost. Beyond this, Bryant and Gebrelassie examined bioproducts and biorefineries (Bryant et al, 2012;Gebreslassie et al, 2013). These technoeconomic studies had differing assumptions and foci, leading to wide variability in costing and level of analysis.…”

Section: Technoeconomic Modelsmentioning

confidence: 97%

Modeling Sustainable Chemical Processes for Biofuels

Dunlop¹,

Coaldrake²,

Silva

et al. 2015

Computer Aided Chemical Engineering

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“…Rizwan et al (2013) proposed an optimization formulation for biodiesel production from microalgal biomass. Gebreslassie et al (2013) presented a superstructure optimization of algae-based hydrocarbon biorefinery with sequestration of CO 2 from power plants considering the net present value and the global warming potential. Ng et al (2013) synthesized a sustainable integrated biorefinery with maximum economic performance while causing minimum environmental impact.…”

Section: Introductionmentioning

confidence: 99%

Reduction of greenhouse gas emissions from steam power plants through optimal integration with algae and cogeneration systems

Lira-Barragán

Gutiérrez-Arriaga

Bamufleh

et al. 2015

Clean Techn Environ Policy

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This paper presents an optimization approach for mitigating CO 2 emissions in the electric power generation through integrated algae and cogeneration systems. A framework is proposed for the integration of biofixation of CO 2 through the cultivation of microalgae, conversion of microalgae to biodiesel, and a steam power plant with cogeneration that is thermally coupled with an industrial facility. A systematic multi-objective optimization approach is developed to integrate the considered units while simultaneously addressing technical, economic, and environmental objectives. The solution of the optimization problem is carried out via a hierarchical decomposition approach, a genetic algorithm, and the e-constraint method for solving the multi-objective optimization problem. A case study is considered to integrate an existing thermoelectric power station in Mexico with an algae-and-cogeneration system. The results show that important environmental, economic, and energy benefits can be achieved as a result of the proposed integration approach.Keywords Combined heat and power (cogeneration) Á GHG mitigation Á Biological capture of CO 2 Á Microalgae biodiesel production Á Steam power plants Á Sustainable energy systems

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Sustainable design and synthesis of algae‐based biorefinery for simultaneous hydrocarbon biofuel production and carbon sequestration

Cited by 134 publications

References 56 publications

Value-Added Chemicals from Microalgae: Greener, More Economical, or Both?

Value-Added Chemicals from Microalgae: Greener, More Economical, or Both?

Modeling Sustainable Chemical Processes for Biofuels

Reduction of greenhouse gas emissions from steam power plants through optimal integration with algae and cogeneration systems

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