RU2477942C2 - Method of preplanting treatment of chick-pea seeds - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: invention relates to the field of plant growing. The method includes even moistening of seeds prior to sowing with water or milk whey. Then rizotorfin is applied in a solution of activated water with pH of 4.2 produced by means of electrolysis. Seeds are treated in vacuum medium at the pressure of 650-680 mm of mercury column and continuous mixing.

EFFECT: method makes it possible to increase crop capacity and to improve nitrogen supply.

8 tbl, 2 ex

Description

The invention relates to agriculture, and in particular to a method of increasing productivity and collecting protein during the cultivation of chickpeas.

The aim of the invention is the activation of the functions of chickpea plants through the use of inoculation (nitraginization) with strains of nodule bacteria of chickpea seeds by the rhizotorfin wet method at the rate of 200-250 g per hectare sowing rate in a solution of activated water with a pH of 4.2 (1 l of water per 1 c of seeds) obtained by electrolysis, and then processed in a vacuum environment at a pressure of 650-680 mm Hg with simultaneous stirring.

The widespread use of inoculation of chickpea seeds with rhizotorfin increases its productivity for cultivation zones by 10-30% and this mandatory technique has become part of the technology of chickpea cultivation [1, 2, 3].

However, the rhizobia culture requires maximum adherence to technological requirements, the non-observance of which is often one of the reasons for unsuccessful crops. Even if they are observed, the average value of nitrogen fixation with respect to potential productivity is only 19-38% [3].

It is known to use skim milk (whey) without dilution as an adhesive of rhizotorfin with a wet method of treating legume seeds [4].

One of the promising methods for activating seed germination is their treatment with electrochemically activated water (catholyte, anolyte) formed in the areas of the diaphragm electrolyzer, which have a biostimulating effect, which contributes to germination and increases productivity on average by 10-15% [5, 6 ].

However, the vacuum effect of electroactivated water in combination with rhizotorfin on seeds during the cultivation of chickpeas has not been studied and is not presented in publications.

Examples of specific performance

Example No. 1. In order to determine the most effective wet method for the pre-sowing treatment of chickpea seeds with rhizotorfin, laboratory (in germinators) and field studies to study the growth energy, germination rate and morphological parameters of plants according to the schemes presented in Tables 1 and 2 were carried out at the All-Russian Research Institute of Beef Cattle Breeding of the Russian Academy of Agricultural Sciences. 4-fold repetition.

Objects of research, chickpeas - variety Yubileiny; rizotorfin - a strain of Rhizobium produced by the All-Russian Research Institute of Microbiology, dose - 200-250 g per hectare seed rate; whey with pH 4, activated water with pH 4.2-5.0 and redox potential + 800 ... + 1200 mV and ordinary water - in quantities of 1.0-1.5 l per 1 kg of seeds, vacuum seed treatment at a pressure of 650-680 mm Hg within 9 min

According to the results of laboratory studies (Table 1), a significant increase in the germination energy of chickpea seeds was noted during the vacuum treatment with “serum + rhizotorfin” and “activated water + rhizotorfin”, which is explained by an increase in the permeability of the shell of chickpea seeds and accelerated activation of growth processes. The greatest influence in the early days of seed germination was exerted by vacuum treatment with activated water in combination with rhizotorfin, as can be seen from the germination energy, it amounted to 86%. The lowest laboratory germination differed in seeds treated with ordinary water (control) - 69%. The studied treatments increased this indicator by 11-19%.

The greatest increase in sprout length, relative to the control, was noted in 5 and 6 variants, respectively, by 1.1 and 0.63 cm. The greatest root length was noted in the same variants, the biomass of 100 roots was the largest and amounted to 0.69 and 0.64 g. respectively.

Based on the results of laboratory studies and their analysis in options 5 and 6, as the most effective in all respects, the field experience was laid in comparison with the control - option 1.

Field experience

Example No. 2. The technique of laying the field experiment was carried out according to the method of B.A. Dospekhov (7), the repetition was fourfold. The total area of the plot - 34 m ^2, discount - 10 m ^2, placement options - systematic. Seeding rate - 0.9 million pcs. germinating seeds per hectare.

Experience outline

1. Risotorfin + plain water (control),

2. Risotorfin + serum + vacuum,

3. Risotorfin + activated water + vacuum.

Seed treatment with rhizotorfin (250 g per hectare sowing rate), according to options, was carried out on the day of sowing. The flow rate of the working solution is 1.5 l per 1 kg of seeds. Agrotechnics - generally accepted for the zone. The preceding crop rotation is spring wheat. Sowing was carried out on May 7, 2010.

The 2010 experiment was the driest in the last century. During the growing season, only 9 mm of precipitation fell, while the average annual indicator for the zone was 111.0 mm. Low field germination of 45.6-53.9% was due to hot weather during sowing and after sowing. Nevertheless, with respect to control, it was higher by 3.8-8.3% (Table 2). The period of intensive growth, flowering, and seed formation also took place under conditions of elevated average temperatures - 26.4-27.9 ° C in the absence of precipitation, which had an impact on the productivity of chickpea crops.

Plant survival, as well as field germination, largely depended on the weather conditions of the growing season.

The lowest survival of plants for harvesting was noted in the control - 37.2%, and the highest in the 3rd variant - 46.1%.

Analyzing the results of the experiment, it should be noted that chickpea plants, the seeds of which were processed according to the 3rd option, were distinguished by more intensive growth. Differences in height were noticeable already from the branching phase. The maximum height of the chickpea plant reached the ripening phase - 26.6-29.5 cm. The plants of the 3rd variant were higher than the control plants by 2.9 cm, of the 2nd variant - 1.7 cm (Table 3).

The number of active nodules on the roots is one of the indicators of the nitrogen-fixing ability of plants, so we evaluated the effect of bacterial fertilizer in combination with various seed treatments before sowing on the nodule-forming ability of chickpeas. The largest number of nodules was in the version of 2-9.8 pcs. from one plant and in the variant 3-10.3 pcs. from one plant, which is respectively higher than the control by 38 and 45% (Table 4).

The nodules on the plants were small, had a pale pink color. This is due to the huge deficit of available moisture in the soil due to the lack of rain, and the high temperatures of 2010 negatively affected the vital activity of nodule bacteria, their reproduction and preservation.

The photosynthetic activity of crops is determined mainly by leaf area, photosynthetic potential, the net productivity of photosynthesis and the growth of dry plant biomass. Leaves of plants are the main organs of plants that create organic matter. The leaf surface area of annual plants depends on the species, development phase and environmental conditions [8, 9, 10].

The dynamics of the formation of the assimilation apparatus of chickpea plants in our experiment had its own peculiarities; an increase in the leaf area up to the budding-flowering phase was noted. So, in the phase of chickpea branching during processing in option 2 and 3, the leaf area increased compared to the control by 56.5 and 73.2%, respectively (Table 5).

The maximum values of leaf surface area were noted in the budding-flowering phase and the highest values in the variant of 3-19.73 thousand m ² / ha (Table 5).

A tendency toward an increase in the accumulation of absolutely dry mass during the branching phase in 2 and 3 variants was noted, respectively, of 0.57 and 0.63 tons per hectare (Table 6).

If the increase in the area of the photosynthetic leaf surface proceeded to the budding-flowering phase (Table 5), then the accumulation of dry matter - until the seeds fully ripened (Table 6). The studied seed treatments contributed to an increase in dry matter, the excess over the control was 19.5-39.1%.

The power of the photosynthetic apparatus is characterized not only by the area of leaves, but also by the indicator of photosynthetic potential, which is determined by the sum of the daily values of the area of photosynthetic organs for the entire growing season, which varied from 476.6 to 813.22 * days / ha according to options (Table 7). The best indicators were still in the 3rd version - 813.22 thousand m ² * days / ha.

The net productivity of photosynthesis according to the experimental variants varied from 2.79 to 2.27 g / m ² per day, which allowed chickpea crops to form grain crops in 2 and 3 variants, respectively, 3.6 and 4.5 c / ha or 44 and 80% above control.

Thus, the research results show that the treatment of chickpea seeds before sowing milk whey and activated water under vacuum against inoculation with rhizotorfin activates the growth and development of plants through the formation of physiologically active substances, provides the emergence of more friendly seedlings, increases the resistance of plants to adverse effects and stress have a positive effect on photosynthetic activity and productivity of chickpea crops, and also improves nitrogen nutrition.

The most highly effective in all experimental parameters was the wet method of inoculating chickpea seeds with risotorfin (200-250 g per hectare sowing rate) in a solution of activated water, pH 4.2 (1.0-1.5 L per 1 cc of seeds) and treated in a vacuum environment (650-680 mm Hg) with constant stirring.

The application of the proposed method of inoculation of chickpea seed contributed to a significant improvement in the quality of chickpea grain and its protein content (Table 8).

Our studies have shown that seed treatment before sowing according to option 3 contributes not only to increased yields, but also to the active accumulation of air nitrogen by chickpea plants, and improves the quality of the crop. The protein content in the chickpea grain in the control variant was 20.13%, and the treatment according to the 3rd variant contributed to an increase in protein content to 23.51%. Analysis of the data in Table 8 shows that the feed content has also increased. Units in 1 kg of grain from 1.25 - in the control to 1.46 in the 3rd embodiment.

Information sources

1. Agafonov EV The increase in yield and protein collection during the cultivation of chickpeas in the Rostov region / E.V. Agafonov, K.I. Pimonov, E.I. Pugach // Feed production, No. 6, 2010. - P.25-28 (prototype).

2. Pimonov K.I. Recommendations for the cultivation of chickpeas in the Don / K.I. Pimonov, E.V. Agafonov, E.I. Putach. - Pos. Persianovsky: Don GAU, 2010 .-- 40 p.

3. Kozhemyakov A.P. The use of inoculants of legumes and complex biological products in agriculture / A.P. Kozhemyakov, I.A. Tikhonovich // Reports of the Russian Academy of Agricultural Sciences, No. 6, 1998. - P.7-10.

4. Biological products / The use of bacterial fertilizers in the cultivation of crops // Advertising leaflet. - Kuznetsk, Penza region: LLC Biofabrika, 2009. - P. 4.

5. Dzhurabov M. Application of electroactivated water in agriculture / M. Dzhurabov // Mechanization and electrification of agriculture. No. 11, 1986. - S. 51-53.

6. RF patent No. 2371901 C2 A01C 1/06 of 11/10/2009. The method of presowing seed treatment.

7. Armor B.A. Methods of field experience / B.A. Dospekhov. - M .: Agropromizdat, 1985 .-- 351 p.

8. Shatilov I.S. Photosynthetic activity of plants in field crop rotation / I.S. Shatilov, A.G. Zamaraeva, G.V. Chapovskaya // Report of TSHA, - M. - 1975. - Issue 214. - S. 5-9.

9. Vasin V.G. Photosynthetic activity of spring wheat, depending on predecessors and the level of use of arable land / V.G. Vasin, V.A. Korchagin, B.Zh.Dzhangabaev // Achievements of technology in agronomy at the turn of the century. - Samara, 2002 .-- P.34-36.

10. Tooming H.G. Solar radiation and crop formation. / H.G. Tooming. - L .: Gidrometeoizdat, 1997 .-- 200 p.

Table 1 Germination energy, germination and morphological indicators of chickpea seedlings depending on seed treatment Experienced group Type of seed treatment Germination energy,% Lab
germination,% Length cm Absolutely dry biomass, g sprouts rootlets 100 sprouts 100 roots one Risotorfin + water (control) 59 61 4.41 5.74 0.40 0.30 2 Risotorfin + Serum 74 76 4.29 4.29 0.62 0.33 3 Risotorfin + Activated Water 78 82 6.25 8.64 0.67 0.62 four Risotorfin + water + vacuum 66 68 5.50 7.80 0.59 0.51 5 Risotorfin + serum + vacuum 83 86 6.96 9.74 0.70 0.69 6 Risotorfin + activated water + vacuum 86 88 6.49 9.59 0.75 0.64

table 2 Field germination, safety and survival of chickpea plants with various seed treatment before sowing Experienced group Experience Options The number of plants, pcs / m ² Field germination,% Preservation,% Survival rate,% at full germination before cleaning one Risotorfin + water (control) 41.0 33.5 45.6 81.7 37,2 2 Risotorfin + serum + vacuum 44.5 36.5 49.4 82.0 40.5 3 Risotorfin + activated water + vacuum 48.5 41.5 53.9 85.6 46.1

Table 3 The dynamics of the height of chickpea plants depending on the pre-sowing treatment of seeds, cm Experienced group Experience Options Phases of plant vegetation branching flower budding bean formation maturation one Risotorfin + water (control) 14.8 19.7 24.2 26.6 2 Risotorfin + serum + vacuum 16.7 22.6 25.7 27.8 3 Risotorfin + activated water + vacuum 16.8 24.3 27.0 29.5

Table 4 The effect of presowing treatment of chickpea seeds on the number and weight of nodules in the flowering phase Experienced group Experience Options The number of nodules from the 1st plant The mass of nodules from the 1st plant, g one Risotorfin + water (control) 7.1 0,100 2 Risotorfin + serum + vacuum 9.8 0.116 3 Risotorfin + activated water + vacuum 10.3 0,120

Table 5 The area of the leaf surface of the phases of vegetation of chickpea plants with various seed treatment before sowing, thousand m ² / ha Experienced group Experience Options Phases of plant vegetation branching flower budding bean formation one Risotorfin + water (control) 5.38 11.48 10.84 2 Risotorfin + serum + vacuum 8.42 14.24 13.51 3 Risotorfin + activated water + vacuum 9.32 19.73 17.98

Table 6 Absolutely dry biomass of chickpea plants by vegetation phases with various seed treatment before sowing, t from 1 ha Experienced group Experience Options Phases of plant vegetation branching flower budding bean formation maturation one Risotorfin + water (control) 0.50 1.09 1.24 1.33 2 Risotorfin + serum + vacuum 0.57 1.28 1.49 1,58 3 Risotorfin + activated water + vacuum 0.63 1,58 1.70 1.85

Table 7 The main photosynthetic indicators of chickpea plants, depending on the seed treatment before sowing Experience Options Maximum leaf area, thousand m ² / ha

Photosynthetic
cue potential

Net photosynthesis productivity, g / m ² per day Yields of absolutely dry biomass,
c / ha Chickpea grain productivity, kg / ha Risotorfin + water (control) 11.48 476.60 2.79 13.3 2,5 Risotorfin + serum + vacuum 14.24 637.36 2.49 15.9 3.6 Risotorfin + activated water + vacuum 19.73 813.22 2.27 18.5 4,5

Table 8 The effect of presowing treatment on the chemical composition of chickpea grain Option Fat% Phosphorus,% Calcium% Protein,% Feed. units The control 4.35 0.35 0.26 20,13 1.25 Risotorfin + activated water + vacuum 4.36 0.38 0.26 23.51 1.46

Claims (1)

A method of inoculating chickpea seeds with rhizotorfin, comprising even moistening with water or whey, characterized in that rhizotorfin is applied in a solution of activated water with a pH of 4.2 obtained by electrolysis, and the seeds are treated in a vacuum medium at a pressure of 650-680 mm Hg and constant stirring.