High yield cultivation of marine macroalga Ulva lactuca in a multi-tubular airlift photobioreactor: A scalable model for quality feedstock

Conventional off-shore and on-shore cultivation methods for marine macroalgae are both inadequate to pitch macroalgae as scalable renewable feedstock that can be grown across all coastal locations. With on-shore cultivation likely to be sustainable and preferred over eco-damaging open seas cultivation, new reactor systems need to be developed for on-shore cultivation of seaweeds at scale. The present work is an attempt to use the indigenously designed vertical multi-tubular air-lift photobioreactor system to grow Ulva lactuca through the entire year under natural conditions. Optimized operation of the 1000 L photobioreactor assembly demonstrated a year-round averaged productivity of 0.87 kg m- 2.d- 1 (fresh weight) implying 1800 ton.ha- 1.y- 1 feedstock production. Carbon dioxide supplementation (5%), optimized circulation velocity (0.25-0.35 m/s), and managing nitrogen supply (17 ppm), under natural light intensities (500-1400 mu mol m- 2.s- 1) provided a year-round sustained and continuous production of Ulva lactuca biomass. The photobioreactor system designed as a modular, linearly scalable, and resilient system operates with low land and water footprints, and gives a multi-fold increase in renewable feedstock production compared to the conventional sea-based and other on-shore tank-based practices. For the video summary of this article, see the file in the supplemental data.

Automated summary

The study used a vertical multi-tubular air-lift photobioreactor system to cultivate Ulva lactuca throughout the year under natural conditions, achieving sustained and continuous production. This provides a new approach for large-scale cultivation of seaweed as a renewable feedstock.