MD565Z - Process for treatment of sugar beet seeds - Google Patents

Abstract

The invention relates to agriculture, in particular to the sugar beet cultivation technology and can be used for increasing sugar productivity and content.The process for treatment of sugar beet seeds, according to the invention, includes soaking of seeds before sowing for 5 hours in 0.5% aqueous solution of mixture, containing Fe, Cu, B, Mn, Zn, Mo and Co in the ratio of 1:1,16:0,63:0,58:0,39:0.008:0.002, at the same time the seeds and the aqueous solution are taken in the mass ratio of 1:2.

Description

The invention relates to agriculture, in particular to sugar beet cultivation technology and can be used to increase productivity and sugar content.

As the closest solution is known the process of treating sugar beet, which includes its extra-radicular treatment with an aqueous solution of microelements, containing Fe, Cu, B, Mn, Zn, Mo and Co, in the ratio of 1:1.16:0.63:0.58:0.39:0.008:0.002, correspondingly, the concentration of the solution being 0.3%. The treatment is carried out in the phase of joining the leaves in rows and in the phase of joining the leaves between rows, with a total consumption of 350...400 L/ha [1].

The disadvantage of the mentioned solution lies in the deficiencies of performing extra-radicular plant nutrition: unfavorable conditions for performing foliar treatment, strict compliance with the treatment phases, partial damage to the foliar apparatus following foliar nutrition.

The problem solved by the proposed invention consists in simplifying the technology of applying the 0.5% aqueous solution of the mixture, containing Fe, Cu, B, Mn, Zn, Mo and Co in the ratio of 1:1.16:0.63:0.58:0.39:0.008:0.002, (Microcom-T), optimally supplying plants with the necessary microelements (Fe, Cu, B, Mn, Zn, Mo and Co) during the vegetation period, increasing the rhizocarp harvest and their sugar content.

The problem is solved by the fact that the process for treating sugar beet seeds, according to the invention, includes soaking the seeds before sowing for 5 hours in a 0.5% aqueous solution of the mixture, containing Fe, Cu, B, Mn, Zn, Mo and Co in a ratio of 1:1.16:0.63:0.58:0.39:0.008:0.002, at the same time the seeds and the aqueous solution are taken in a mass ratio of 1:2.

The process can be used to treat sugar beet seeds to stimulate metabolic processes during germination, provide plants with more complete microelements and, as a result, increase rhizocarp productivity and sugar content.

The technical result consists in the more efficient use of Microcom-T in sugar beet cultivation technology, increasing the rhizocarp yield by 6.2…18.3% and the sugar content in them by up to 1.1% compared to control plants and maintaining plant productivity compared to the closest solution.

Technologically, the proposed process does not require additional expenses, because it is carried out simultaneously with the treatment of seeds with pesticides.

Seed treatment with Microcom-T leads to a balanced supply of plants with microelements, favoring more intensive development of rhizocarps and the root system in the rhizosphere area, which ensures a more significant resistance of plants to drought conditions. Therefore, the application of the fertilizer intensifies metabolic processes, and during vegetation - oxidation-reduction reactions and stimulation of the elimination of exudates from the root system.

These exudates mobilize nutrients from the soil. The increased accessibility of nutrients, including microelements for plants, is followed by the maintenance of higher levels of nitrogen metabolism in plants during the intensive growth phase and of carbohydrates during the intensive sugar accumulation phase.

Examples of embodiments of the invention

Example 1.

Effect under nutritionally directed conditions

The research was carried out in the conditions of the vegetation house of the Institute of Plant Genetics and Physiology. For the experiment, Mitcerlih pots with a capacity of 22…23 kg of carbonate chernozem soil were used. Sugar beet variety - Baracuda. Seed treatment with 0.5% aqueous solution of Microcom-T was carried out 5 hours before the experiment was set up. The ratio (by volume) of the application of the solution of microelements and seeds is 2:1. Foliar treatment of plants was carried out at the stage of their intensive growth with a 0.3% solution (the closest solution) and with water (control). During the vegetation of the plants, the activity of enzymes - nitrate reductase and peroxidase, the content of monosaccharides, disaccharides and microelements - Fe, Mn, Cu and Zn, and at the end of the vegetation - the mass of rhizocarps and the sugar content in them were determined.

From the data presented in Table 1, it is observed that seed treatment and foliar application of Microcom-T contributed to maintaining a higher level of nitrate reductase activity in leaves during vegetation. Towards the end of vegetation, nitrate reductase activity in leaves decreases significantly in all variants, but in variants with the application of microelements the primary process of nitrate reduction is maintained at a higher level. The effect of the preparation application is also manifested on the content of mono- and disaccharides in leaves, decreasing it insignificantly.

Table 1

Nitrate reductase activity (NRA, µg NO2 -/g fresh weight, 30 min) in leaves, rhizocarp weight and sugar content in dependence on Microcom-T application

Variant Development phase Rhizocarp mass, g Surplus, % Sugar content, % Intensive growth Intensive sugar accumulation End of vegetation Control 15.3±0.23 13.4±0.25 2.42±0.04 404.4±11.2 0 15.4 Closest solution 17.9±0.32 17.1±0.52 3.51±0.05 486.5±22.7 16.9 15.8 Proposed invention 18.7±0.41 16.9±0.34 3.53±0.06 519.8±21.3 22.1 15.9

When treating seeds, the rhizocarp mass increased by 22.1%, and when treating foliarly - by 16.9%. It should be noted that under greenhouse conditions, along with the significant increase in rhizocarp mass, the sugar content in them did not decrease: there is a tendency for the sugar content to increase when applying Microcom-T (0.5% - when treating seeds, 0.4% - when treating foliarly plants (tab. 1).

Example 2

The experiment was carried out in field conditions in 2010…2011 on small plots with an area of 15…20 m2 in 3 repetitions with randomized distribution of variants, soil - carbonate chernozem. Basic fertilizers administered - N 90 P 90 K 90. Seed treatment was carried out 5 hours before sowing, and foliar treatment of plants at the following phases: first - joining of leaves in rows; second - joining of leaves between rows.

From the experimental data it is observed that when treating seeds and applying the preparation to the rhizosphere area, the denitrification processes in the soil are reduced (insignificantly), and in the leaves of the plants the activity of nitrate reductase increases (tab. 2). The decrease in the primary denitrification process in the rhizosphere area can probably be conditioned by the influence of exudates eliminated from the roots under the influence of the applied microelements. At the same time, the content of monosaccharides and disaccharides in the leaves is reduced. The experimental data obtained provide the possibility to conclude that when treating seeds with Microcom-T, the processes of nitrogen assimilation and carbohydrate metabolism are intensified in plants (tab. 2).

Table 2

Nitrate reductase activity in soil (mg NO3-/10 g soil, 24 hours), leaves (µg NO2-/g fresh weight, 30 min), mono- and disaccharide content in dependence on seed and foliar treatment of sugar beet plants with Microcom-T

Variant ANR in soil ANR in leaves Monosaccharide content, % Disaccharides, % Control 6.26±0.28 5.95±0.03 0.611±0.017 0.079±0.003 Closest solution 5.57 ±0.19 6.73±0.37 0.559±0.018 0.069±0.006 Proposed invention 5.58±0.25 6.78±0.11 0.529±0.028 0.068±0.008

The decrease in peroxidase activity during seed treatment and foliar application of the preparation probably demonstrates the improvement of the supply of plants with microelements, since the activity of this enzyme increases under unfavorable growth conditions (Table 3). Therefore, the decrease in nitrate reductase activity in the soil, the intensification of enzyme activity in the leaves, the (insignificant) decrease in the content of monosaccharides in the leaves, the increase in the content of disaccharides in the rhizocarps and the decrease in peroxidase activity in the leaves when treating seeds with Microcom-T demonstrate the more complete supply of plants with microelements and the improvement of the nutritional status of plants in general under such conditions.

Table 3

Peroxidase activity (un.conv./min) in sugar beet leaves depending on Microcom-T application

Variant Intensive growth phase Sugar accumulation phase Control 342.1±19.81 536.25±6.64 Closest solution 312.4±3.38 454.21±16.13 Proposed invention 267.6±1.35 399.91±20.47

The content of microelements Fe, Mn, Zn and Cu (determined at AAS-1) is also in an interdependence with the application of Microcom-T (tab. 4). When treating both seeds and the foliar apparatus with the mentioned preparation, the content of Fe, Cu and Zn in leaves, of Mn in petioles and of Fe and Zn in rhizocarps increases.

Table 4

Fe, Mn, Cu and Zn content in leaves, petioles and rhizocarps depending on Microcom-T application. Phase - 12…14 leaves, mg/kg dry mass. Field experience 2010

Organ Variant Fe Mn Cu Zn Leaves Control 241.9 262.6 9.4 20.2 Closest solution 254.3 252.4 9.6 25.4 Proposed invention 248.5 247.4 9.2 23.9 Petioles Control 172.4 76.04 3.9 14.1 Closest solution 178.2 98.4 4.9 14.5 Proposed invention 148.9 98.84 4.8 12.4 Rhizocarps Control 33.8 51.9 3.7 5.8 Closest solution 34.2 50.2 3.5 6.4 Proposed invention 39.1 50.7 3.3 10.2

These changes in enzyme activity, carbohydrate and microelement content in sugar beet had a positive effect on the rhizocarp yield and sugar content in them. In 2010, against the background of an average rhizocarp yield of 272.2 q/ha, the yield increased by 18.3% with seed treatment and by 16.4% with foliar application of the preparation, respectively. This year, with a significant increase in the rhizocarp yield, the sugar content practically remained at the control level (18.6%).

In 2011, against the background of a more significant harvest (385.4 q/ha), the influence of microelement application was less pronounced: the yield increase with seed treatment was 6.2%, and with foliar application - 5.4%. This year, the sugar content increased by 1.1% with seed treatment and by 0.9% with foliar application of the preparation (Table 5).

Table 5

Rhizocarp yield and sugar content in dependence on Microcom-T application

Variant 2010 2011 q/ha Surplus, % Sugar content, % q/ha Surplus, % Sugar content, % Control 272.2±18.6 0 18.6 385.4±23.3 0 20.5 Closest solution 325.4±10.3 16.4 18.8 407.2±18.3 5.4 21.4 Proposed invention 333.3±12.6 18.3 18.5 410.8±19.2 6.2 21.6

Therefore, seeds treated according to the invention ensure an efficient supply of plants with microelements, reduce additional expenses related to omitting foliar nutrition of plants, increase sugar production per unit area by 12.3…21.7% compared to control plants and by 1.8% compared to plants treated according to the closest solution.

1. MD 3218 F1 2007.01.31

Claims (1)

Process for treating sugar beet seeds, which consists in soaking the seeds for 5 hours in a 0.5% aqueous solution of the mixture, containing Fe, Cu, B, Mn, Zn, Mo and Co in a ratio of 1:1.16:0.63:0.58:0.39:0.008:0.002, at the same time the seeds and the solution are taken in a mass ratio of 1:2.