Smart Glass Film Reduced Ascorbic Acid in Red and Orange Capsicum Fruit Cultivars without Impacting Shelf Life

He, Xin; Chavan, Sachin G.; Hamoui, Ziad; Maier, Chelsea; Ghannoum, Oula; Chen, Zhong‐Hua; Tissue, David T.; Cazzonelli, Christopher I

doi:10.3390/plants11070985

Cited by 9 publications

(5 citation statements)

References 64 publications

(107 reference statements)

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“…It is well known that the intensity and its absorption by plants affect the growth of agricultural crops. − However, the influence of green-light wavelength-selective OSC films on plant growth remains unclear. Thus, using gas exchange experiments, the photosynthetic rate of strawberry leaves (as representative plants for greenhouse cultivation) was evaluated under sunlight that was irradiated through the prepared OSC devices.…”

Section: Resultsmentioning

confidence: 99%

Green-Light Wavelength-Selective Organic Solar Cells Based on Poly(3-hexylthiophene) and Naphthobisthiadiazole-Containing Acceptors toward Agrivoltaics

Jinnai

Seo

et al. 2023

ACS Sustainable Chem. Eng.

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The complemental absorption behavior of donors and acceptors in organic solar cells (OSCs) results in the broad absorption of solar light, contributing to the realization of high-performance OSCs. However, the development of OSCs with narrow absorption ranges, i.e., wavelength-selective OSCs, has made slow progress owing to their limited applications. Here, green-light wavelength-selective OSCs, whose transmitted blue and red light can be effectively used to promote plant growth, are proposed. For the preparation of green-light wavelength-selective OSCs, a practical polymer of poly(3-hexylthiophene) (P3HT) is employed as the donor and naphthobisthiadiazole-based compounds (SNTz-RD and ONTz-RD) are newly designed as the acceptors. The electronic absorption measurements of SNTz-RD and ONTz-RD show strong absorption bands in the green-light region. In addition, SNTz-RD and ONTz-RD possess appropriate frontier orbital energy levels as acceptors. OSCs based on P3HT and these acceptors show typical photovoltaic responses with good green-light wavelength-selective factors and good power conversion efficiencies in the green-light region. Furthermore, the P3HT:SNTz-RD blend films exhibit an improved photosynthetic rate in the strawberry leaves compared to the conventional P3HT:[6,6]-phenyl-C61-butyric acid methyl ester (PC61BM) film. These results demonstrate that the combination of P3HT and green-light wavelength-selective acceptors can produce green-light wavelength-selective OSCs for application in new greenhouse agrivoltaics.

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Section: Resultsmentioning

confidence: 99%

Green-Light Wavelength-Selective Organic Solar Cells Based on Poly(3-hexylthiophene) and Naphthobisthiadiazole-Containing Acceptors toward Agrivoltaics

Jinnai

Seo

et al. 2023

ACS Sustainable Chem. Eng.

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“…Two weeks after transplantation, two stems from each plant were selected and trellised onto plastic strings supported by a high-wire system. Plants were grown according to commercial practices of hydroponic production of vegetables in greenhouses under non-limiting water and nutrient (EC: 2.5 dS m −1 –3.0 dS m −1 , pH: 5.0–5.5) conditions at [CO 2 ] (489.6 μl l −1 and 476.6 μl l −1 daytime average), temperature (25.3/19.3 and 25.2/19.3°C day/night average), RH (74.2/72.9% and 74.2/77.5%, day/night average) and natural light for AE and SE, respectively ( He et al., 2022 ). The environmental variables, including temperature, relative humidity, and CO 2 concentration at canopy level, were monitored in all glasshouse compartments at 5-minute intervals.…”

Section: Methodsmentioning

confidence: 99%

Light blocking film in a glasshouse impacts Capsicum annuum L. yield differentially across planting season

Maier,

Chavan,

Klause

et al. 2023

Front. Plant Sci.

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High energy costs are a barrier to producing high-quality produce at protected cropping facilities. A potential solution to mitigate high energy costs is film technology, which blocks heat-producing radiation; however, the alteration of the light environment by these films may impact crop yield and quality. Previous studies have assessed the impact of ULR 80 [i.e., light-blocking film (LBF)] on crop yield and photosynthetically active radiation (PAR); however, an assessment of the spectral environment over different seasons is important to understand potential crop impacts through different developmental phases. In this study, two varieties (red and orange) of Capsicum annuum were grown across two crop cycles: one cycle with primary crop growth in the autumn (i.e., autumn experiment [AE]) and the other with primary crop growth in the summer (i.e., summer experiment [SE]). LBF reduced PAR (roof level: 26%–30%, plant canopy level: 8%–25%) and net radiation (36%–66%). LBF also reduced total diffuse PAR (AE: 8%, SE: 15%), but the diffuse fraction of PAR increased by 7% and 9% for AE and SE, respectively, potentially resulting in differential light penetration throughout the canopy across treatments. LBF reduced near-infrared radiation (700 nm–2,500 nm), including far-red (700 nm–780 nm) at mid- and lower-canopy levels. LBF significantly altered light quantity and quality, which determined the amount of time that the crop grew under light-limited (<12 mol m−2 d−1) versus sufficient light conditions. In AE, crops were established and grown under light-limited conditions for 57% of the growing season, whereas in SE, crops were established and grown under sufficient light conditions for 66% of the growing season. Overall, LBF significantly reduced the yield in SE for both varieties (red: 29%; orange: 16%), but not in AE. The light changes in different seasons in response to LBF suggest that planting time is crucial for maximizing fruit yield when grown under a film that reduces light quantity. LBF may be unsuitable for year-round production of capsicum, and additional development of LBF is required for the film to be beneficial for saving energy during production and sustaining good crop yields in protected cropping.

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“…In contrast, low humidity increases vapour pressure deficit in leaves that will reduce stomatal opening and photosynthesis (Ahmed et al, 2019). Low light and high light affect greenhouse crop yield that is partial related to the reduced accumulation of K in plant (Babla et al, 2023; He et al, 2022). High and low temperatures influence stomatal movement, which in turn influences growth, transpiration, photosynthesis and yield (Babla et al, 2023; Rabbi et al, 2019).…”

Section: Potassium Fertigation Management For Greenhouse Cropsmentioning

confidence: 99%

“…High and low temperatures influence stomatal movement, which in turn influences growth, transpiration, photosynthesis and yield (Babla et al, 2023; Rabbi et al, 2019). Some modern glasshouse facilities incorporate specialized glass technologies and efficient cooling systems, which have the potential to reduce power use (He et al, 2022). Therefore, these developments can facilitate the protected cropping sector in shifting to a sustainable and cost‐effective level of energy efficiency thereby maintaining crop quality, nutritional content and reducing adverse environmental impacts (Figure 1).…”

Section: Potassium Fertigation Management For Greenhouse Cropsmentioning

confidence: 99%

Potassium transport and use efficiency for sustainable fertigation in protected cropping

Bhardwaj

Huda

Jayasena

et al. 2023

J of Sust Agri & Env

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The increasing demand for high‐quality horticultural produces in global markets has driven the growing crop production under protected cropping, which are usually more efficient in fertilizer use compared to field cultivation. As one of the key macronutrients, available potassium (K+) resources have decreased due to the expansion of intensive agriculture and excessive use of K fertilizers. Currently, limited strategies have been adopted to improve crop quality in protected cropping with sustainable use of K+ fertigation and its comprehensive understanding at physiological and molecular levels. Therefore, we highlight the importance of optimal use of K+ in fertigation in protected cultivation that may also enhance crop quality characteristics. We review different K+ channels and transporters from various protein families responsible for K+ absorption and distribution across different plant tissues. An analysis of the literature on transcriptome, ionome, proteome and metabolome profiles of crops suggests the crucial roles of K+ in maintaining ion homoeostasis and modulating stress responses. It reveals that optimal K+ fertigation levels in protected cropping not only aids in maintaining the overall crop growth and production but also participates in maintaining the fruit quality. This review can potentially guide crop production and resource use efficiency in protected cropping, contributing to global food security and a better sustainable agricultural and environmental future.

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Smart Glass Film Reduced Ascorbic Acid in Red and Orange Capsicum Fruit Cultivars without Impacting Shelf Life

Cited by 9 publications

References 64 publications

Green-Light Wavelength-Selective Organic Solar Cells Based on Poly(3-hexylthiophene) and Naphthobisthiadiazole-Containing Acceptors toward Agrivoltaics

Green-Light Wavelength-Selective Organic Solar Cells Based on Poly(3-hexylthiophene) and Naphthobisthiadiazole-Containing Acceptors toward Agrivoltaics

Light blocking film in a glasshouse impacts Capsicum annuum L. yield differentially across planting season

Potassium transport and use efficiency for sustainable fertigation in protected cropping

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