Electron transport and photosynthetic performance in Fragaria × ananassa Duch. acclimated to the solar spectrum modified by a spectrum conversion film

Kang, Jun Hyeun; Yoon, Hyo In; Kim, Jae Pil; Son, Jung Eek

doi:10.1007/s11120-021-00875-7

Cited by 16 publications

(7 citation statements)

References 96 publications

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“…In this experiment, the projection ratios of ultraviolet, violet, and green light are reduced and the projection ratios of blue, red-orange, and far-red light are induced in the solar greenhouse covered by RPO film. Different light conversion agents added into the film may cause different light spectrum ( Kang et al, 2022 ). Additionally, the study found that rare-earth conversion film improved light transmittance, consistent with the previous research ( Liu et al, 2022 ).…”

Section: Discussionmentioning

confidence: 99%

“…The rare-earth light conversion (RPO) film is practical, and cost-effective in solar greenhouse. The greenhouse film with a light transfer agent could considerably enhance tomato growth and fruit yield and quality by improving the light conditions in the solar greenhouse ( Kang et al, 2022 ). Meanwhile, that RPO covering upon the greenhouse improved the air temperature and light intensity inside greenhouses, enhancing the heat preservation and light transmission rates ( Garofalakis et al, 2006 ; Xin et al, 2019 ; Yu et al, 2019 ), and improved fruit quality and yield, such as tomato ( Lycopersicon esculentum Miller; Xiao et al, 2022 ).…”

Section: Introductionmentioning

confidence: 99%

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Effects of rare-earth light conversion film on the growth and fruit quality of sweet pepper in a solar greenhouse

Gao

Cai

et al. 2022

Front. Plant Sci.

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Light is an important environmental factor influencing plant growth and development. However, artificial light supplement is difficult to spread for its high energy consumption. In recent years, rare-earth light conversion film (RPO) covering is being focused on to be a new technology to study the mechanism of light affecting plant growth and development. Compared with the polyolefin film (PO), the RPO film advanced the temperature and light environment inside the greenhouse. Ultimately, improved growth and higher yield were detected because of a higher photosynthesis, Rubisco activity and Rubisco small subunit transcription. Compared with that in the greenhouse with polyolefin film, the plant height, stem diameter and internode length of sweet pepper treated with RPO increased by 11.05, 16.96 and 25.27%, respectively. In addition, Gibberellic acid 3 (GA3), Indole-3-acetic acid (IAA), Zeatin Riboside contents were increased by 11.95, 2.84 and 16.19%, respectively, compared with that with PO film. The fruit quality was improved, and the contents of ascorbic acid (Vc), soluble protein and soluble sugar were significantly higher than those of PO film, respectively, increased by 14.29, 47.10 and 67.69%. On the basis of improved fruit quality, the yield of RPO treatment increased by 20.34% compared with PO film. This study introduces an effective and low-energy method to study the mechanism and advancing plant growth in fruit vegetables production.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Effects of rare-earth light conversion film on the growth and fruit quality of sweet pepper in a solar greenhouse

Gao

Cai

et al. 2022

Front. Plant Sci.

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“…cv. Seolhyang) [ 87 ]. The spectral conversion polyethylene film led to higher photosynthetic activity over a long time, while it did not change the photosynthetic chlorophyll content or leaf optical properties.…”

Section: Spectral Conversion Materials In Agriculturementioning

confidence: 99%

“…3a). Due to its potential for augmenting biomass productivity of crops in the greenhouse, this technology is still receiving notable attention [83][84][85][86]. For example, Bergren et al demonstrated the benefits of quantum dots (QDs)-based luminescent film technology to improve spectral quality for plant growth [43].…”

Section: Spectral Conversion Greenhouse Claddingsmentioning

confidence: 99%

Solar spectral management for natural photosynthesis: from photonics designs to potential applications

Shen

Yin

2022

Nano Convergence

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Photosynthesis is the most important biological process on Earth that converts solar energy to chemical energy (biomass) using sunlight as the sole energy source. The yield of photosynthesis is highly sensitive to the intensity and spectral components of light received by the photosynthetic organisms. Therefore, photon engineering has the potential to increase photosynthesis. Spectral conversion materials have been proposed for solar spectral management and widely investigated for photosynthesis by modifying the quality of light reaching the organisms since the 1990s. Such spectral conversion materials manage the photon spectrum of light by a photoconversion process, and a primary challenge faced by these materials is increasing their efficiencies. This review focuses on emerging spectral conversion materials for augmenting the photosynthesis of plants and microalgae, with a special emphasis on their fundamental design and potential applications in both greenhouse settings and microalgae cultivation systems. Finally, a discussion about the future perspectives in this field is made to overcome the remaining challenges.

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“…More recently, many experimental studies have been conducted to investigate how crops (especially herbal crops such as lettuce, basil, soybean, etc.) react to different light treatments in laboratory controlled conditions (Ahmed et al., 2020; Chen et al., 2021; Clavijo‐Herrera et al., 2018; Danziger & Bernstein, 2021; Fang et al., 2021; Kang et al., 2021; Kim et al., 2004; Lim & Kim, 2021; Liu et al., 2017; Mochizuki et al., 2019; Muneer et al., 2014; Nguyen & Oh, 2021; Pennisi et al., 2019; Pennisi, Pistillo, Orsini, Cellini, et al., 2020; Pennisi, Pistillo, Orsini, Gianquinto, et al., 2020; Pundir et al., 2020; Samuolienė et al., 2020). The majority of these studies, although sometimes with contrasting results, suggest that some parts of the light spectrum are less efficient in terms of carbon assimilation and water use and could be more effectively used to produce solar energy.…”

Section: Introductionmentioning

confidence: 99%

Not All Light Spectra Were Created Equal: Can We Harvest Light for Optimum Food‐Energy Co‐Generation?

Camporese

Najm

2022

Earth's Future

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Humanity's growing appetites for food and energy are placing unprecedented yield targets on our lands. Chasing those ever‐expanding land intensification targets gave rise to monocultures and sharpened the divide between food and energy production groups. Here, we argue that this does not have to be a zero‐sum game if food and energy can be co‐generated in the same land. Co‐generation can lead to sustainable intensification but requires a paradigm shift in the way we manage our resources, particularly light. Using an extended model of plant photosynthesis and transpiration, we demonstrate how plants react to different incident light spectra and show that manipulating light could be effective for boosting land and water efficiencies, thus potentially improving soil health. This knowledge can possibly unlock the real potential of promising modern agricultural technologies that target optimization of light allocations such as agrivoltaics. This study suggests that the blue part of the light spectrum is less efficient in terms of carbon assimilation and water use and could be more effectively used to produce solar energy, while the red part could efficiently produce biomass. A sensitivity analysis to the most important crop and environmental variables (irradiance, air temperature, humidity, and CO2 concentration) shows that plant response to different light treatments is sensitive to environmental boundary conditions and is species‐specific. Therefore, further research is necessary to assess which crops and climates are more suitable to optimize the proposed food‐water‐energy nexus.

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Electron transport and photosynthetic performance in Fragaria × ananassa Duch. acclimated to the solar spectrum modified by a spectrum conversion film

Cited by 16 publications

References 96 publications

Effects of rare-earth light conversion film on the growth and fruit quality of sweet pepper in a solar greenhouse

Effects of rare-earth light conversion film on the growth and fruit quality of sweet pepper in a solar greenhouse

Solar spectral management for natural photosynthesis: from photonics designs to potential applications

Not All Light Spectra Were Created Equal: Can We Harvest Light for Optimum Food‐Energy Co‐Generation?

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