Nanotechnology in Plant Growth Promotion and Protection. Группа авторов

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Название Nanotechnology in Plant Growth Promotion and Protection
Автор произведения Группа авторов
Жанр Биология
Серия
Издательство Биология
Год выпуска 0
isbn 9781119745891



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barrier to the absorption of Zn from ZnO than from ZnSO4; therefore, ZnO show less toxicity. Raskar and Laware (2014) also reported for onion seeds Zn NPs treatment (less than 40 mg/L) substantially increased antioxidant enzymes, including guaiacol peroxidase (GPx), catalase (CAT), SOD, and glutathione reductase (GR). Besides, Sedghi et al. (2013) stated that Zn NPs could play a vital role in the biosynthesis of auxin and gibberellin, resulting in a higher germination rate. However, there is optimal concentration for Zn NPs application, concentration too high can reduce the activity of antioxidant or reducing enzymes. Israel García‐López et al. (2018) found that ZnO NPs (18 nm) applied during imbibition and incubated for 72 hours at 100–400 mg/L induced a significant increase in production of peroxidase and ascorbate peroxidase; however, at 500 mg/L these enzymes were reduced in Capsicum. Therefore, it is crucial to determine the optimal Zn NPs concentration and treatment duration for seed treatment.

      3.3.1 Application Methods

      Plants' leaves can absorb Zn through foliar application. There are several critical factors controlling the adsorption capacity of leaves, including the thickness of the waxy protective layer, the chemical composition and structure of the cuticle, the density of stoma and trichomes, and the physiological state of the plant (Schönherr 2006; Eichert and Goldbach 2008). Environmental factors such as humidity, temperature, and lightning also play important role in Zn adoption by plant leaves (Fernández and Eichert 2009).

      Due to the sorption capacity of both plant roots and leaves, Zn NPs can be supplied in different ways (Figure 3.2). Foliar spray application means spraying of NPs suspension over plant leaves, NPs suspension can be sprayed over crop at different intervals depending on crop spices. When Zn NPs are sprayed over leaves, Zn is absorbed by leaves and then distributed to lower parts through the phloem. The substrate mediated application includes the application of NPs to the root zone in soil culture and soilless culture. In soil culture, nano‐fertilizers are mixed with soil after broadcasting. In soilless culture or hydroponic system, Zn NPs are often supplied through mixing with nutrient solution. Zn applied in the root zoon is first adsorbed by roots then translocated to upper parts through xylem and phloem.

      3.3.2 Effects of Zn NPs on Plant Growth Promotion

      3.3.2.1 Effects of Zn NPs Via Foliar Application

Schematic illustration of translocation and major physiological and biochemical responses of Zn NPs in plants.
Size and coatings (nm) Crop Concentrations Mode of application Effects References
Root growth Shoot growth Yield
35.5 Maize 50–2000 mg/L Foliar spray, two times (tasseling and milking stage) + + + Subbaiah et al. (2016)
20 Sunflower 2000 mg/L Foliar spray, two times (6 leaf stage and 1 week later), under salt