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Only Extreme Fluctuations in Light Levels Reduce Lettuce Growth Under Sole Source Lighting

The cost of providing lighting in greenhouses and plant factories can be high. In the case of variable electricity prices, providing most of the light when electricity prices are low can reduce costs. However, it is not clear how plants respond to the resulting fluctuating light levels. We hypothesi...

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Detalles Bibliográficos
Autores principales: Bhuiyan, Ruqayah, van Iersel, Marc W.
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Frontiers Media S.A. 2021
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7875872/
https://www.ncbi.nlm.nih.gov/pubmed/33584773
http://dx.doi.org/10.3389/fpls.2021.619973
Descripción
Sumario:The cost of providing lighting in greenhouses and plant factories can be high. In the case of variable electricity prices, providing most of the light when electricity prices are low can reduce costs. However, it is not clear how plants respond to the resulting fluctuating light levels. We hypothesized that plants that receive a constant photosynthetic photon flux density (PPFD) will produce more biomass than those grown under fluctuating light levels. To understand potential growth reductions caused by fluctuating light levels, we quantified the effects of fluctuating PPFD on the photosynthetic physiology, morphology, and growth of ‘Little Gem’ and ‘Green Salad Bowl’ lettuce. Plants were grown in a growth chamber with dimmable white LED bars, alternating between high and low PPFDs every 15 min. The PPFDs were ∼400/0, 360/40, 320/80, 280/120, 240/160, and 200/200 μmol⋅m(−2)⋅s(–1), with a photoperiod of 16 h and a DLI of ∼11.5 mol⋅m(−2)⋅day(–1) in all treatments. CO(2) was ∼800 μmol⋅mol(–1). Plants in the 400/0 μmol⋅m(−2)⋅s(–1) treatment had ∼69% lower A(n),(30) (net assimilation averaged over 15 min at high and 15 min at low PPFD) than plants grown at a PPFD of 320/80 μmol⋅m(−2)⋅s(–1) (or treatments with smaller PPFD fluctuations). The low A(n),(30) in the 400/0, and to a lesser extent the 360/40 μmol⋅m(−2)⋅s(–1) treatment was caused by low net assimilation at 360 and 400 μmol⋅m(−2)⋅s(–1). Plants grown at 400/0 μmol⋅m(−2)⋅s(–1) also had fewer leaves and lower chlorophyll content compared to those in other treatments. The four treatments with the smallest PPFD fluctuations produced plants with similar numbers of leaves, chlorophyll content, specific leaf area (SLA), dry mass, and leaf area. Chlorophyll content, A(n),(30), and dry mass were positively correlated with each other. Our results show that lettuce tolerates a wide range of fluctuating PPFD without negative effects on growth and development. However, when fluctuations in PPFD are extreme (400/0 or 360/40 μmol⋅m(−2)⋅s(–1)), chlorophyll levels and A(n),(30) are low, which can explain the low poor growth in these treatments. The ability of lettuce to tolerate a wide range of fluctuating light levels suggests that PPFD can be adjusted in response to variable electricity pricing.