MD1832Z - Method for presowing treatment of corn seeds - Google Patents

Abstract

The present invention proposes the use of nanotechnology and a low-intensity magnetic field for pre-sowing treatment of corn seeds, where the seed treatment is carried out with a colloidal solution of magnetite nanoparticles Fe3O4 stabilized with polyethylene glycol with a molecular weight of 6000 units directly in a magnetic field with an induction of 40-50 μT in the frequency range of 6-10 Hz for 20 minutes, while the concentration of magnetite is in the range of 5-12.5 mg/l.

Description

The invention relates to the use of nanotechnology in agriculture, in particular to seed treatment processes, using a magnetic field in the presence of magnetite nanoparticles stabilized with polyethylene glycol.

For decades, agricultural science has focused on intensification, that is, increasing yields without increasing area. Modern developments in nanotechnology are opening up another direction in agricultural intensification.

Thus, intensive research has recently been conducted on the pre-sowing treatment of seeds of various crops, using a suspension of Fe3O4 nanoparticles and their processing with a magnetic field.

A process of treating corn seeds with Fe3O4 nanoparticles with subsequent exposure to vibrations at a frequency of 10 Hz for 4 hours is known to accelerate corn seed development [1].

The disadvantage of this process is the long exposure time to vibrations, especially if it refers to the processing of large volumes of seed production. Also, this process uses sufficiently high concentrations of nanoparticles, of 0.3 g/L.

The closest solution is the corn seed tartarization process that uses the combined action of an alternating magnetic field with Fe3O4 nanoparticles, where sweet corn seeds were initially exposed to an alternating magnetic field with parameters f=50 Hz, B=1 mT for 1 hour and then treated with Fe3O4 nanoparticles with a concentration of 0.1 mg/mL (100 mg/L) [2].

The disadvantage of this method is a sufficiently high magnetic field induction and a high concentration of Fe3O4 nanoparticles.

Such parameters cause stress in the processed seeds.

Under the influence of stress, seed germination increases and their growth accelerates in the early stages of development.

Experiments using this procedure were carried out only under laboratory conditions, without field studies, that is, without sowing treated seeds in the soil and determining the size of the crop compared to the control group.

The applicant conducted field tests with seeds treated with this method and found that the yield was at the level of the control group, where the seeds were soaked in distilled water before planting.

The problem solved by the invention consists in increasing the efficiency of seed treatment before sowing in order to obtain increased yields, while respecting environmental safety.

This problem is solved by the process of treating corn seeds before sowing, which consists of treating the seeds with a colloidal solution of Fe3O4 magnetite nanoparticles, stabilized with polyethylene glycol with a molecular weight of 6000 units, with a concentration of 5-12.5 mg/L, in which the treatment is carried out in a magnetic field with an induction of 40-50 µT, with the frequency varying from 6 Hz to 10 Hz and back every 2 minutes, for 20 minutes.

It is known that in the cells of living organisms, along with biochemical processes, there are biophysical processes that surpass them in power and significance. Throughout the development of life on Earth, living organisms have evolved in an environment where low-intensity electromagnetic fields are present, for example, Schumann waves (7.8-8 Hz). All processes occurring in the cells of living organisms are associated with such natural fields.

The effectiveness of the effect on seeds was confirmed by a series of experiments conducted on seeds of a corn hybrid №265 from the Phytotechnical Institute "Porumbeni".

The experiments showed a significant advantage in germination and seedling uniformity compared to the control. In all examples, the seeds were irradiated for 20 minutes with a magnetic field with an induction of 40-50 µT in the frequency range from 6 Hz to 10 Hz and back every 2 minutes.

Since active signals have an extremely low intensity and frequency, inherent to all living organisms, this effect cannot cause mutations in cells, and the presence of magnetite nanoparticles (NpsFe3O4/PEG) - mimetics of the catalase enzyme - improves the germination energy and germination of hybrid corn seeds No. 265.

The advantage of the proposed process is the use of a low-frequency, low-intensity magnetic field generator, which has been confirmed by a series of experiments.

It has been shown that the magnetic field increases the permeability of the cell membrane - this is confirmed by the increase in germination energy and seed germination, as well as the morphological parameters of the seedlings and the root system of corn.

The improvement in germination energy is the result of the synergistic effect of simultaneous exposure of seeds to Fe3O4 magnetite nanoparticles and an alternating magnetic field.

Magnetite Fe3O4/polyethylene glycol nanoparticles (Fe3O4/PEG NPs) were obtained based on a modified co-precipitation method (T. Gutul, I. Rastemisina, O. Postolachi, A. Nicorici, D. Dvornikov, P. Petrenco. Synthesis and biological application of magnetite nanoparticles. Moldavian Journal of the Physical Sciences, 2015, v. 14, no. 3-4, p. 177-188), using aqueous solutions of iron(II) sulfate and iron(III) chloride with a Fe2+:Fe3+ concentration ratio of 1:2, in the presence of polyethylene glycol (Peg Ms=6000). The synthesis was carried out in a 250 mL reaction vessel, in which 50 mg of PEG powder was pre-dissolved in 200 mL of distilled water and 2.7 g of iron(II) sulfate (FeSO4·7H2O) was added to the polyethylene glycol solution. After the dissolution of the iron(II) sulfate salt, 5.4 g of iron(III) chloride (FeCl3·6H2O) was added, mixing was carried out until the salts were completely dissolved. Then 12.5% ammonium hydroxide (NH4OH) solution, in a volume of 44 mL, was added to the reaction vessel, the black powder of NpsFe3O4/PEG nanoparticles precipitated within 1 hour. The reaction took place at a temperature of 70°C in the presence of ultrasound, using the Elmasonic S100H device. The Fe3O4/PEG nanoparticles were separated from the reaction medium and washed with distilled water and then with ethanol to exclude the presence of chloride and sulfate ions, the powder was dried at 100°C.

Fe3O4/PEG magnetite nanoparticles were used to prepare the aqueous colloidal solution with an initial concentration of 50 mg/L, which was subsequently used to prepare solutions with concentrations of 5 mg/L, 12.5 mg/L and 20 mg/L.

The advantage of the proposed method is:

- reducing the processing time of corn seeds with a magnetic field to 20 min;

- use of a lower intensity magnetic field;

- reducing the concentration of magnetite nanoparticles stabilized with polyethylene glycol, and the use of nanoparticles coated with a stabilizer makes it possible to obtain a stable colloidal solution without sedimentation of the nanoparticles.

The invention is explained by the following figures:

- Fig. 1, results of experiment 1, where the concentration of NpsFe3O4/PEG was 5 mg/L;

- Fig. 2, results of experiment 2, where the concentration of NpsFe3O4/PEG was 12.5 mg/L;

- Fig. 3, results of experiment 3, where the concentration of NpsFe3O4/PEG was 20 mg/L.

Experiments were performed on the same number of seeds with different concentrations of NpsFe3O4 /PEG.

All experiments were performed in triplicate. The results were processed using Microsoft Excel software and presented as arithmetic means with standard deviation. The statistical significance of the differences between control and experiment was assessed by the Student's t-test. The differences were statistically significant at (p>0.90).

Corn seeds were calibrated in a quantity of 360 pieces for each experiment. In each experiment, the seeds were placed in 9 cups of 30 in each in three replicates.

Three control cups were filled with distilled water, and the other two with a colloidal solution of nanoparticles of different concentrations - 5 mg/L, 12.5 mg/L and 20 mg/L.

The volume of fluid in all cases was 25 mL.

Experience 1

Option 1: seeds + H2O (distilled water) (3 cups)

Variant 2: seeds + NpsFe3O4/PEG (5 mg/L) + H2O (3 cups)

Variant 3: seeds + magnetic field + H2O (3 cups)

Variant 4: seeds + NpsFe3O4/PEG (5 mg/L) + H2O (3 cups) + magnetic field.

The seeds soaked in variants 3 and 4 were treated with a magnetic field for 20 minutes. The seeds from all cups were placed in Petri dishes on a layer of filter paper on the same day and placed in a growth chamber at t=+22 C° and humidity of 82-85%, respectively. After 4 days the germination energy was tested, and on the 8th day the length of the cotyledon and the root of the seeds were measured.

The germination energy in the control case was 90%, and in the case of seeds treated with a magnetic field and NpsFe3O4/PEG at a concentration of 5 mg/L it was 98%. The results of the root and shoot length measurements are presented in Fig. 1.

Experience 2

Option 1: seeds + H2O (distilled water) (3 cups)

Variant 2: seeds + NpsFe3O4/PEG (12.5 mg/L) + H2O (3 cups)

Variant 3: seeds + magnetic field + H2O (3 cups)

Variant 4: seeds + NpsFe3O4/PEG (12.5 mg/L) + H2O (3 cups) + magnetic field.

The seeds soaked in variants 3 and 4 were treated with a magnetic field for 20 minutes. The seeds from all cups were placed in Petri dishes on a layer of filter paper on the same day and placed in a growth chamber at t=+22 C° and humidity of 82-85%, respectively. After 4 days the germination energy was tested, and on the 8th day the length of the shoot and root was measured.

The germination energy in the control was 90.4%, and in the seeds treated with magnetic field and NpsFe3O4/PEG at a concentration of 12.5 mg/L of approximately 96%. The results of the root and shoot length measurements are presented in Fig. 2.

Experience 3

Option 1: seeds + H2O (distilled water) (3 cups)

Variant 2: seeds + NpsFe3O4/PEG (20 mg/L) + H2O (3 cups)

Variant 3: seeds + magnetic field + H2O (3 cups)

Variant 4: seeds + NpsFe3O4/PEG (20 mg/L) + H2O (3 cups) + magnetic field.

The seeds soaked in variants 3 and 4 were treated with a magnetic field for 20 minutes. The seeds from all cups were placed in Petri dishes on a layer of filter paper on the same day and placed in a growth chamber at t=+22 C° and, respectively, humidity of 82-85%, respectively. After 4 days, the germination energy was tested, and on the 8th day the length of the shoot and root was measured.

The germination energy in the control case was 81.3%, and in the case of seeds treated with magnetic field and NpsFe3O4/PEG at a concentration of 20 mg/mL of approximately 89%. The results of the measurement of root and shoot length are presented in Fig. 3.

From the graphs in Figures 1, 2 and 3 it can be seen that at a concentration of NpsFe3O4/PEG equal to 20 mg/L the stem and root of the seedlings are smaller than the control sample.

Thus, it is obvious that the best result is obtained at a concentration of NpsFe3O4/PEG from 5mg/L to 12.5 mg/L.

Field tests at the experimental field (Leordoaia village, Călăraşi District) showed the following:

Type of seed treatment Control, Н2О NpsFe3O4 /PEG Magnetic field NpsFe3O4 /PEG + Magnetic field Yield, C/ha 68.0 78.0 81.3 89.0

Thus, it is obvious that treating seeds before sowing with a simultaneous combination of a low-frequency magnetic field with low concentrations of magnetite provides the best result not only in seed germination and their early development, but also the best result in yield, which ultimately interests agricultural producers.

1. Гелюх Т.М. The influence of Fe3O4 nanoparticles on the ontogenesis of sugar corn (Zea mays L.). Вестник СНО ДонНУ, 2021, no. 13, v. 1, p. 47-52

2. Kotyuk П.Ф., Kornienko В.О. Influence of the combined action of an alternating magnetic field with Fe3O4 nanoparticles (cit) on the ontogeny and morphometry of sugar corn. Actual issues of biological physics and chemistry, 2022, v. 7, no. 1, pp. 45-49

Claims (1)

Process for treating corn seeds before sowing, which consists of treating the seeds with a colloidal solution of Fe3O4 magnetite nanoparticles, stabilized with polyethylene glycol with a molecular weight of 6000 units, with a concentration of 5-12.5 mg/L, the treatment is carried out in a magnetic field with an induction of 40-50 µT, with the frequency varying from 6 Hz to 10 Hz and back every 2 minutes, for 20 minutes.