Growth modeling to evaluate alternative cultivation strategies to enhance national microalgal biomass production

We present a model-based assessment of alternative cultivation strategies for open pond algal biomass production within the conterminous United States (CONUS). Our assessment focuses on two basic cultivation strategies: (1) seasonal rotation of three representative freshwater algal strains that are...

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Veröffentlicht in:	Algal research (Amsterdam) 2020-08, Vol.49 (C), p.101939, Article 101939
Hauptverfasser:	Sun, Ning, Skaggs, Richard L., Wigmosta, Mark S., Coleman, André M., Huesemann, Michael H., Edmundson, Scott J.
Format:	Artikel
Sprache:	eng
Schlagworte:	Biomass Assessment Tool (BAT) Cultivation strategies Microalgae biomass productivity modeling Microalgae growth model Open pond
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creator	Sun, Ning Skaggs, Richard L. Wigmosta, Mark S. Coleman, André M. Huesemann, Michael H. Edmundson, Scott J.
description	We present a model-based assessment of alternative cultivation strategies for open pond algal biomass production within the conterminous United States (CONUS). Our assessment focuses on two basic cultivation strategies: (1) seasonal rotation of three representative freshwater algal strains that are well suited for warm weather, cold weather, and all-season diverse weather conditions, respectively; and (2) variation between three pond water depths (15 cm, 20 cm, and 25 cm). The enhanced Biomass Assessment Tool (BAT) is applied on a site-specific, hourly basis at 5832 North American Land Data Assimilation System Phase 2 1/8° meteorological model grid cells over a 30-year period (1980–2009) to evaluate the operational strategies. Recognizing that resource management decisions may also consider scales beyond the individual site, we also conduct a regional assessment focused on seven representative climate zones in the CONUS. Results demonstrate that the spatial variability of algal productivity is largely affected by the strain-specific growth response to light and temperature that vary significantly by climate zone and latitude. With a limited set of alternative cultivation strategies, the BAT identified the best-performing combination of cultivation strategies on a site-specific basis that considerably enhances national annual biomass productivity. In particular, the appropriate choice of seasonal strain rotation can significantly dampen climate-driven seasonal and spatial variability in algal productivity over the CONUS. •Cultivation strategies are evaluated for national algal biomass productivity.•The best-performing cultivation strategies are identified for 5832 sites.•Biomass productivity can be greatly enhanced by seasonal strain rotations.•The optimum pond depth for biomass productivity is 15 cm for evaluated 5832 sites.
doi_str_mv	10.1016/j.algal.2020.101939
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subjects	Biomass Assessment Tool (BAT) Cultivation strategies Microalgae biomass productivity modeling Microalgae growth model Open pond
title	Growth modeling to evaluate alternative cultivation strategies to enhance national microalgal biomass production
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