Conceptual design of LED-based hydroponic photobioreactor for high-density plant cultivation

Conceptual design of LED-based hydroponic photobioreactor for high-density plant cultivation

A novel hydroponic photobioreactor is proposed for high‐density cultivation of plants. This cultivation can be achieved by growing plants on a floatable platform, allowing the roots to directly contact a continuously aerated nutrient solution. Plant growth of Mentha × piperita (peppermint) can be sh...

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Bibliographic Details
Published in:Biotechnology progress Vol. 15; no. 6; pp. 1058 - 1064
Main Authors: Shotipruk, A, Kaufman, P.B, Wang, H.Y
Format: Journal Article
Language:English
Published: USA American Chemical Society 01-11-1999
American Institute of Chemical Engineers
Subjects:
Biological and medical sciences
Bioreactors
Biotechnology
Cultivation
Density (specific gravity)
electrical equipment
Fundamental and applied biological sciences. Psychology
hydroponics
in vitro culture
Light emitting diodes
Light extinction
Mathematical models
Mentha piperita
Methods. Procedures. Technologies
Plants (botany)
Various methods and equipments
Light effect
Growth
High density
Essential oil plant
Environmental factor
Light emitting diode
Luminous intensity
Mentha piperita
Bioreactor
Labiatae
Dicotyledones
Hydroponic cultivation
Photobioreactor
Angiospermae
Spermatophyta
Mathematical model
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Summary:A novel hydroponic photobioreactor is proposed for high‐density cultivation of plants. This cultivation can be achieved by growing plants on a floatable platform, allowing the roots to directly contact a continuously aerated nutrient solution. Plant growth of Mentha × piperita (peppermint) can be shown to strongly correlate with the light intensity at incident light intensities between 0 and 650 μmol m−2 s−1. For a constant incident light intensity (I0 = 420 μmol m−2 s−1), the overall specific growth rates of these plants are found to be strongly dependent on the plant density. They range from 0.023 to 0.075 d−1 for plants grown at a density range from 16 to 256 plants m−2. A simple mathematical model is presented that allows one to predict these effects of light intensity and plant density on peppermint growth. Light delivery is derived from the modification of Beer−Lambert's law. From this, the relationship between the light extinction coefficient and plant density can be experimentally determined. The light transport can then be coupled with plant growth kinetics under light‐limiting conditions. The predicted growth results agree reasonably well with most experimental results from a growth period of 17–20 days. On the basis of these simulation results, we suggest that a more efficient way of delivering light to this photobioreactor can be attained by supplying light from both the top and the bottom of the plant shoots. The proposed design takes advantage of the small size and low weight of light emitting diodes, which allow them to be mounted on platforms for delivering light closer to the plants.
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ISSN:8756-7938
1520-6033
DOI:10.1021/bp990114i