Environmental Life Cycle Comparison of Algae to Other Bioenergy Feedstocks

Clarens, Andres F.; Resurreccion, Eleazer P.; White, Mark A.; Colosi, Lisa M.

doi:10.1021/es902838n

Cited by 959 publications

(643 citation statements)

References 40 publications

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“…Most nutrients consumed during growth are in the LEA and a portion of them is recovered during biogas production. Previous work showed that electricity production and nutrient recycling greatly affect energy and nutrient demands in the process (Campbell et al 2009;Clarens et al 2010Clarens et al , 2011Frank et al 2011aFrank et al , 2012Lardon et al 2009;Stephenson et al 2010).…”

Section: Context and Motivationmentioning

confidence: 99%

Life cycle comparison of hydrothermal liquefaction and lipid extraction pathways to renewable diesel from algae

Frank

Elgowainy

Han

et al. 2012

Mitig Adapt Strateg Glob Change

191

151

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Algae biomass is an attractive biofuel feedstock when grown with high productivity on marginal land. Hydrothermal liquefaction (HTL) produces more oil from algae than lipid extraction (LE) does because protein and carbohydrates are converted, in part, to oil. Since nitrogen in the algae biomass is incorporated into the HTL oil, and since lipid extracted algae for generating heat and electricity are not co-produced by HTL, there are questions regarding implications for emissions and energy use. We studied the HTL and LE pathways for renewable diesel (RD) production by modeling all essential operations from nutrient manufacturing through fuel use. Our objective was to identify the key relationships affecting HTL energy consumption and emissions. LE, with identical upstream growth model and consistent hydroprocessing model, served as reference. HTL used 1.8 fold less algae than did LE but required 5.2 times more ammonia when nitrogen incorporated in the HTL oil was treated as lost. HTL RD had life cycle emissions of 31,000 gCO 2 equivalent (gCO 2 e) compared to 21,500 gCO 2 e for LE based RD per million BTU of RD produced. Greenhouse gas (GHG) emissions increased when yields exceeded 0.4 g HTL oil/g algae because insufficient carbon was left for biogas generation. Key variables in the analysis were the HTL oil yield, the hydrogen demand during upgrading, and the nitrogen content of the HTL oil. Future work requires better data for upgrading renewable oils to RD and requires consideration of nitrogen recycling during upgrading.

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Section: Context and Motivationmentioning

confidence: 99%

Life cycle comparison of hydrothermal liquefaction and lipid extraction pathways to renewable diesel from algae

Frank

Elgowainy

Han

et al. 2012

Mitig Adapt Strateg Glob Change

191

151

View full text Add to dashboard Cite

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“…11,[13][14][15][16][17][18] In this study, we aimed to further assess the capability of these four green microalgae species in the simultaneous removal of various contaminants (nitrogen, phosphorus, metals, organic compounds) in real wastewater. Estrogenic EDCs such as nonylphenol possess the ability to disrupt the endocrine systems of higher organisms by interacting with the estrogen receptor.…”

Section: Introductionmentioning

confidence: 99%

Simultaneous removal of inorganic and organic compounds in wastewater by freshwater green microalgae

Zhou

Ying

Liu

et al. 2014

Environ. Sci.: Processes Impacts

140

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Batch experiments were carried out for 7 days to investigate the simultaneous removal of various organic and inorganic contaminants including total nitrogen (TN), total phosphorus (TP), metals, pharmaceuticals and personal care products (PPCPs), endocrine disrupting chemicals (EDCs), and estrogenic activity in wastewater by four freshwater green microalgae species, Chlamydomonas reinhardtii, Scenedesmus obliquus, Chlorella pyrenoidosa and Chlorella vulgaris. After treatment for 7 days, 76.7-92.3% of TN, and 67.5-82.2% of TP were removed by these four algae species. The removal of metals from wastewater by the four algae species varied among the metal species. These four algae species could remove most of the metals efficiently (>40% removal), but showed low efficiencies in removing Pb, Ni and Co. The four algae species were also found to be efficient in removing most of the selected organic compounds with >50% removal, and the estrogenic activity with removal efficiencies ranging from 46.2 to 81.1% from the wastewater. Therefore, algae could be harnessed to simultaneously remove various contaminants in wastewater. Environmental impactDomestic wastewater contains various inorganic and organic contaminants, which could pose risks to the environment and public health. To avoid these adverse effects, wastewater must be treated prior to its nal discharge into the receiving environment. Unfortunately, incomplete removals have oen been reported for these contaminants in wastewater by conventional wastewater treatment technologies. The use of microalgae in the treatment of wastewater has gained great interest over the past few years. However, previous studies on wastewater treatment by algae have been limited and most of them are focused on the removal of inorganic or organic pollutants in articial wastewaters. This study investigated the simultaneous removal capacity of inorganic (nitrogen, phosphorus and metals) and organic pollutants (PPCPs and EDCs) by four freshwater microalgae, and also evaluated the elimination of estrogenic activity in the wastewater by these algae species. The results demonstrated that simultaneous removal of various contaminants in wastewater was achieved, which showed potential application of these algae species in the wastewater treatment.

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“…Furthermore, prospective largescale microalgae production locations are often arid areas that exhibit high evaporative losses of between 20-40ML ha -1 annually, which limits the scope and scale of microalgae production in many regions (Chisti 2007;McHenry 2010). Nevertheless, microalgae appear to exhibit superior overall environmental credentials to terrestrial biofuels with smaller land use and water consumption per unit of output compared to agricultural crops (Sheehan et al 1998;Huntley and Redalje 2006;Chisti 2007;Gross 2007;Hankamer et al 2007;Cantrell et al 2008;Chisti 2008;Dinh et al 2009;Borowitzka and Moheimani 2010;Clarens et al 2010). This ability is essentially a factor of their potential to achieve a higher real photosynthetic efficiency than typical terrestrial crops (Sheehan et al 1998;Vasudevan and Briggs 2008;Amin 2009).…”

Section: How Thermal MD and Solution Mining Integrate With Microalgalmentioning

confidence: 99%

“…Whilst such diverse production options adds potential flexibility and diversity, it also necessitates robust culture pre-and-post-treatment and precise system control to avoid the many potential production problems (Schneider 2006;Wang et al 2008). As an example, if not managed effectively, industrial pond microalgae culture may create effluent waste water issues and become an unprofitable and energy intensive process (Wyman and Goodman 1993;Xiong et al 2008;Charcosset 2009;Borowitzka and Moheimani 2010;Clarens et al 2010). …”

Section: How Thermal MD and Solution Mining Integrate With Microalgalmentioning

confidence: 99%

Hybrid microalgal biofuel, desalination, and solution mining systems: increased industrial waste energy, carbon, and water use efficiencies

McHenry

2012

Mitig Adapt Strateg Glob Change

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McHenry, M.P. (2013) Hybrid microalgal biofuel, desalination AbstractThis work reviews retrofitting new waste energy, carbon and water intensive technologies into existing industrial facilities (including electricity generators) to increase net energy, carbon, and water use efficiencies. The three applications reviewed are microalgal ponds consuming flue gasses and providing thermal power station cooling services, thermally driven membrane distillation desalination, and hydrometallurgical solution mining processes to indirectly remove water contaminants, and additional power station cooling. The aim of this work is to explore the unique challenge of site-specificity of retrofitting any or all of the reviewed technologies within existing facilities for commercial operations. The theoretical basis behind higher aggregated efficiencies is essentially vertical integration of infrastructure, energy, and material flows, reducing total costs, net waste, and associated potential environmental contamination. Whilst solution mining and some thermal desalination technologies are not necessarily new in isolation, new technical developments enable these technologies to use waste heat and waste water by operating in parallel with industrial facilities, and effectively subsidise microalgae biofuel water pumping and dewatering. This research determines three fundamental developments are required to enable wide-scale industrial co-located vertical integration efficiencies: (1) fundamental engineering, (2) monitoring system innovation, and (3) technology/knowledge transfer.

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Environmental Life Cycle Comparison of Algae to Other Bioenergy Feedstocks

Cited by 959 publications

References 40 publications

Life cycle comparison of hydrothermal liquefaction and lipid extraction pathways to renewable diesel from algae

Life cycle comparison of hydrothermal liquefaction and lipid extraction pathways to renewable diesel from algae

Simultaneous removal of inorganic and organic compounds in wastewater by freshwater green microalgae

Hybrid microalgal biofuel, desalination, and solution mining systems: increased industrial waste energy, carbon, and water use efficiencies

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