Your search keyword '"Asmaa El-shahawy"' showing total 4 results

1. Enhancing Maize Yield and Soil Health through the Residual Impact of Nanomaterials in Contaminated Soils to Sustain Food

Author

Esawy Mahmoud, Asmaa El-shahawy, Mahmoud Ibrahim, Abd El-Halim A. Abd El-Halim, Atef Abo-Ogiala, Mohamed. S. Shokr, Elsayed Said Mohamed, Nazih Y. Rebouh, and Sahar Mohamed Ismail

Subjects

nanomaterials, contaminated soil, residual effects, soil fertility, biological activity, maize, Chemistry, QD1-999

Abstract

Studying the impact of residual soil nanomaterials is a promising challenge for sustainable agricultural development to improve soil health and crop productivity. The objective of this study is to assess the long-term impacts of 50, 100, and 250 mg kg−1 soil of nanobiochar (nB) and nano-water treatment residues (nWTR) on the fertility, biological activity, and yield of maize (Zea mays L.) growing in heavy metal-contaminated soils. The results showed that when nB and nWTR were added in larger quantities, the concentrations of lead (Pb), nickel (Ni), cadmium (Cd), and cobalt (Co) extracted with DTPA decreased. With the addition of nB or nWTR, it also showed a significant increase in exchangeable cations, cation exchange capacity (CEC), soil fertility, soil organic matter (OM), microbial biomass carbon (MBC), and a decrease in soil salinity and sodicity. Catalase and dehydrogenase activities rose as nB addition increased, while they decreased when nWTR addition increased. In comparison to the control, the addition of nB and nWTR greatly boosted maize yield by 54.5–61.4% and 61.9–71.4%, respectively. These findings suggest that the researched nanomaterials’ residual effect provides an eco-friendly farming method to enhance the qualities of damaged soils and boost maize production. Our research suggested that adding recycling waste in the form of nanoparticles could immobilize heavy metals, improve soil characteristics, and increase the soil’s capacity for productivity.

Published

2024

2. Properties of Recycled Nanomaterials and Their Effect on Biological Activity and Yield of Canola in Degraded Soils

Author

Hany Elsawy, Asmaa El-shahawy, Mahmoud Ibrahim, Abd El-Halim Abd El-Halim, Naser Talha, Azza Sedky, Manal Alfwuaires, Hebah Alabbad, Nawa Almeri, and Esawy Mahmoud

Subjects

soil amendments, nanobiochar, functional groups, surface area, zeta potential, Agriculture (General), S1-972

Abstract

Recycling waste, such as rice straw and water treatment residuals, is important to reduce harmful effects on the environment and to improve canola yield and soil quality in degraded soils. Nanotechnology for the production of nanomaterials from biochar and water treatment residues will be a future revolution for improving soil quality and increasing canola yield in degraded soil. Therefore, this study aims to identify the properties of some recycled nanomaterials, such as nanobiochar (nB) and nanowater treatment residue (nWTR), and their effect on the biological activity and productivity of canola in degraded soils. The results showed that the nWTR and nB contain many functional groups and minerals, and they also have high negative zeta potential. The addition of the studied soil amendments significantly improved microbial biomass carbon (MBC) and biological activity, which played a major role in increasing canola yield. The highest dehydrogenase (DHA) and catalase (CLA) activity was found in nWTR-treated soil at 50 mg kg−1, with increases of 32.8% and 566.7% compared to the control, respectively. The addition of nB greatly improved the growth of canola plants in the soil. This was evident from the increase in the weight of seeds, the weight of 1000 grains, the number of pods per plant, and the highest increase was for nB added at the rate of 250 mg per kg−1 soil. The addition of 50 mg kg−1 of nWTR gave the best results in seed yield by 150.64% compared to the control. These results indicate that recycled nWTR and nB are some of the best waste recycling treatments, in addition to good soil health, in increasing soil biology and canola yield in degraded soils. In the future, research on recycled nanomaterials should examine the residual effect they have on yield, soil quality, and soil fauna in the long term.

Published

2022

3. Existence of a bounded variation solution of a nonlinear integral equation in L1(R+)

Author

Wagdy El-Sayed, Ragab O. Abd El-Rahman, Sheren A. Abd El-Salam, and Asmaa El Shahawy

Subjects

Complementary and alternative medicine, Pharmaceutical Science, Pharmacology (medical)

Abstract

In this paper we study the existence of a unique solution of a nonlinear integral equation in the space of bounded variation on an unbounded interval by using measure of noncompactness and Darbo fixed point theorem.

Published

2022

4. Spectroscopic and chemical properties of biochar and water treatment residual nanoparticles and their effects on canola growth and biological activity

Author

Asmaa El-shahawy, Mahmoud Ibrahim, AbdEl-Halim AbdEl-Halim, Naser Talha, and Esawy Mahmoud

Abstract

Nanotechnology is a promising science in the development and improvement of soil, raising its production capacity and recycling waste in a hastily manner. This study aims to investigate the properties of some recycled nanomaterials and their effect on the biological activity and productivity of canola in degraded soils. Measuring the spectroscopic and chemical properties of nanomaterials such as biochar (nB) and water treatment residuals (nWTR) and adding them at different rates to the degraded soil. The results showed that the FTIR and XRD spectra of nWTR and nB contain many functional groups (such as C = O, OH, C = C, C-H, Si-O-Al, and Si-O-Si) and minerals. Zeta potential of the nB and nWTR was − 31.08 mV and − 65.25 mV, respectively. Addition of nB or nWTR at different rates significantly improved canola yield. Seed weight of canola plant increased with increasing nB rate by more than 64%, while it decreased with increasing nWTR rate. Microbial biomass carbon (MBC) and the activity of dehydrogenase (DHA) and catalase (CLA) increased significantly in the treated pots with the addition of nB and nWTR at different rates. Our results suggested the possibility of adding reused materials in the form of nanomaterials to the degraded soils, which would have the ability to improve their properties and increase their yield.

Published

2022