Influence of Silicon and Nano-Silicon on Germination, Growth and Yield of Faba Bean (Vicia faba L.) Under Salt Stress Conditions

Qados, A. M. S. A.; Moftah, Ansary E.

doi:10.9734/ajea/2015/14109

Cited by 47 publications

(18 citation statements)

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“…These results may be because of the increasing amounts of pigments which led to increasing yield (Yang and Hong, 2006). These results respectively agree with those obtained by Abdul Qados and Moftah (2015). The stimulatory impacts on umbels number and seeds yield plant -1 and/fed.…”

Section: Yield Characteristicssupporting

confidence: 90%

Response of Pimpinella anisum L Plant For Graphite and Silica Nanoparticles

Menesy

Khalfallah

Rashed

et al. 2018

Journal of Sustainable Agricultural Sciences

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T HERE has been a rising demand for nanotechnology-based products in recent years, particularly in agriculture application. In this effort, the phytotoxicity and stimulatory effects of graphite and silica nanoparticles (NPs) on seed germination, yield characteristics, chemical conformation and root anatomical characteristics of (Pimpinella anisum L.) cv. anise were studied. Seeds were soaked in six concentrations of the two NPs (0, 20, 40, 60, 80 and 100 ppm) for 24 hr to investigate germination under laboratory conditions. The same concentrations were used for soaking and foliar application in the open field. The results displayed that silica NPs improved seed germination traits comparing with graphite NPs. Silica NPs at 20 and 40 ppm, showed the highest germination parameters for anise seeds. The increase in germination % reached 21.88%. Meanwhile, 80ppm silica NPs enhanced the seeds yield fed.-1 by 64.8%, Number of umbels by 50%, root diameter plant-1 , epidermis thickness and cortex thickness. Silica NPs (60ppm) increased biochemical characteristic. Otherwise, graphite NPs (80ppm) enhanced volatile oil% and root vascular cylinder thickness. In general, there was a considerable response by anise seeds to graphite and silica nano-sized presenting the possibility of a new methodology to overcome problems with seed germination and increasing the oil percent in some plant species, mostly medicinal plants.

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Section: Yield Characteristicssupporting

confidence: 90%

Response of Pimpinella anisum L Plant For Graphite and Silica Nanoparticles

Menesy

Khalfallah

Rashed

et al. 2018

Journal of Sustainable Agricultural Sciences

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“…The results showing the efficiency of SiO 2 in wheat growth and productivity and these results were the same observation detected for nano silica that increased plant growth as reported by (Yuvakkumar et al, 2011), and plant resistance to hydroponic conditions as reported by (Suriyaprabha et al, 2012), as well as increased root length in plants, as stated by (Haghighi et al, 2012) (Sabaghnia and Janmohammadi, 2015), and induced an improvement in photosynthesis as mentioned by (Liang et al, 2003). Additionally, observed the same trend as other studies which showed the effects of nano−SiO 2 with mineral fertilizers in many crop plants, such as maize as stated by (Suriyaprabha et al, 2012;Yuvakkumar et al, 2011;Ayman et al, 2016) a common bean as reported by (Alsaeedi et al, 2017), tall wheatgrass as described by (Azimi et al, 2014), tomato as outlined by (Lu et al, 2015), faba bean as mentioned by (Qados and Moftah, 2015), wheat as described by (Tahir et al, 2006), rice as disclosed by (Yeo et al, 1999), Glycine max as mentioned by ( Lu et al, 2002), and sweet pepper as displayed by (Tantawy et al, 2015). Also, others showed the effective role of nanomaterial fertilizers on plant growth and productivity.…”

Section: Influence Of Nano−sio 2 On Wheat Yield Components and N P supporting

confidence: 70%

“…Additionally, increasing the Siabsorption by nano− SiO 2 particles addition in saline soil, increase absorption of N, P, K, Si and reduce Na in plant, increase in plant antioxidants, Si helps wheat plant on tolerance of salt stress by reducing of Na uptake and set of turgor pressure inside the plant and increase the efficiency of the photosynthesis process. Many studies indicated to some or/and these reasons such as (Heckman, 2013;Qados and Moftah, 2015;Ayman et al, 2016;Pati et al, 2016;Tubana et al, 2016;Rastogi et al, 2019).…”

Section: Influence Of Nano−sio 2 On Wheat Yield Components and N P mentioning

confidence: 99%

Influence of Nano–silica on Wheat Plants Grown in Salt–affected Soil

Ayman

Metwally

Mancy

et al. 2020

Journal of Productivity and Development

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“…Therefore, nanotechnology such as using nanoscale fertilizer may offer new techniques to be used for crop management. The efficient use of nano-scale microelements was reported by many authors including titanium (Hasanpour et al 2015;Singh and Lee 2016;Tan et al 2017) silicon (Siddiqui et al 2014;Ashkavand et al 2015;Sabaghnia and Janmohammadi 2015;Qados and Moftah 2015;Liu et al 2015;Wang et al 2015;Mahdavi et al 2016) silver (Seghatoleslami et al 2015;Almutairi 2016) iron (Martínez-Fernández et al 2015;Pourjafar et al 2016) zinc (Seghatoleslami and Forutani 2015;Soliman et al 2015). The previous reports also described the role of nanomaterials in ameliorating biotic stress in plant habitat.…”

Section: Nanobiotechnology For Crop Productivitymentioning

confidence: 94%

Nanobiotechnology for Plants

Abdalla¹,

Ragab

Fári

et al. 2019

EBSS

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N ANOTECHNOLOGY has been revolutionized penetrating all sectors in our life through the nanoscience as an essential science for a wide range of technologies. Amazing achievements resulted from this nanotechnology including all agricultural fields such as plant nutrition and crop productivity, energy sector, food sector, and plant biotechnology. A conjugation between plant biotechnology and nanotechnology has been produced an important science called plant bio-nanotechnology. Several fields have been invaded through different nanobiotechnology applications in agriculture including (1) the nanotechnology of encapsulated agro-chemicals, (2) the monitoring of different environmental stresses and crop conditions using nanobiosensors, (3) the improvement of crop production and ameliorating plants against diseases and (4) solution several environmental problems. The crop productivity also could be improved using some new agro-chemicals (e.g., nanofertilizers and nanopesticides). These agro-chemicals are very effective in delivering encapsulating nanomaterials and then enhancement the productivity of crops as well as the suppress plant pests and diseases and protecting the environment from pollution. On the other hand, nanoparticles could enter the food chain via different nano-agrochemicals or nano-processed foods. Therefore, many approaches including uptake of nanoparticles by plants, entry and bio-distribution of nanoparticles into the food chain are needed before using of different bionanotechnological tools in agro-production sector. Further new regulations should be created or rebuilt for new approaches in plant bionanotechnology. Therefore, this review will focus on our needs and risks in the plant nanobiotechnology.

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Influence of Silicon and Nano-Silicon on Germination, Growth and Yield of Faba Bean (Vicia faba L.) Under Salt Stress Conditions

Cited by 47 publications

References 0 publications

Response of Pimpinella anisum L Plant For Graphite and Silica Nanoparticles

Response of Pimpinella anisum L Plant For Graphite and Silica Nanoparticles

Influence of Nano–silica on Wheat Plants Grown in Salt–affected Soil

Nanobiotechnology for Plants

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