FR3093615A1 - PROCESS FOR PLANTING PEANUTS ON A SALINE SOIL WITH ALKALIS AND SPECIAL FERTILIZER APPLIED IN THIS PROCEDURE - Google Patents

Abstract

The present invention relates to a method of planting a crop on saline alkali soil comprising the following steps: producing a crop after fertilization, with a width of 70 to 110 cm; form a small furrow 8 to 12 cm wide and deep in the middle of a seedling area; form raises with a height of 10 to 20 cm and a lower width of 15 to 25 cm on the side edges; provide a spacing between rows of 35 to 55 cm; mulch the full width for planting, but leave 3-10 cm unmulched on two side edges of the width; dig holes in a base layer in the small furrow at 3-8 cm intervals, and then cover the holes with soil.

Description

METHOD FOR PLANTING PEANUTS ON SALINE SOIL WITH ALKALIS AND SPECIAL FERTILIZER APPLIED IN SAID METHOD

The present invention relates to the field of growing plants on saline alkali soil, and in particular, a method of planting peanuts on saline alkali soil and a special fertilizer for peanuts applied in the method.

Technical problem

In recent years, the self-sufficiency rate for domestic vegetable oil in China has been less than 35 percent, which is considerably below the strategic national grain and oil security alert threshold (i.e. a self-sufficiency rate of 60 percent). Since groundnut is an important oilseed cash crop in China, expanding groundnut planting area and increasing total groundnut production is critical to adhering to the national grain and vegetable security strategy. 'oil. Based on incomplete statistics, the alkali saline land in China covers an area of about 1 x 10 ⁷ hm ² , which accounts for 6.2 percent of the cultivated area. The expansion of the alkali saline area cultivated for groundnuts is important to alleviate the incompatibility between the pressure for the supply of edible oil in China and the land for the production of cereals and oils. The Yellow River Delta region is one of the major coastal alkali saline lands in China, and about 2,000 km ² (3 million Mu; 1 Mu = 666.67 square meters) of land can be developed and utilized. Its use for the production of oil plants would greatly increase the rate of self-supply of edible vegetable oil in China.

Groundnut is a calcareous crop, and lack of exchangeable calcium in the soil greatly affects groundnut pod development, resulting in yield loss. Low-solubility or insoluble calcium compounds form readily in a saline-alkali environment, resulting in a dramatic decrease in exchangeable calcium content. According to data from this research group, the average exchangeable calcium content of groundnut planting land in Kenli District of Dongying City is 5g/kg, while the average exchangeable calcium content of general high yield fields in Shandong Province is 14g/kg. On the other hand, calcium, as an essential substance of a calcium signal transduction pathway, plays an important role in regulating the response of plants to stress related to adverse conditions. Thus, improving a nutritional environment in terms of calcium is one of the important technical measures for obtaining a high yield of groundnuts in saline alkali land.

However, groundnut cultivation on saline alkali land is, to date, non-existent, and it is generally believed that groundnuts should not be grown on saline alkali land. Therefore, the inventor has long undertaken research on the improvement and utilization of coastal alkali saline land, and found that it is possible to obtain a high yield of peanuts on alkali saline land. through salinity reduction measures by removing salt with water, pH reduction by additionally applying acidic organic fertilizer, prevention of future fertilizer shortage by increasing the fertilizer share slow-release, preventing empty hulls and leaf loss by additionally applying calcium-rich fertilizer and iron-rich fertilizer, ensuring emergence rate by increasing seeding rate, and the like. Years of experimentation and demonstration prove that it is feasible to plant peanuts under moderate saline to alkali conditions. The inventor cultivated peanuts in a large area at 300 g/m ² (200 kg/Mu) on the alkali saline land of Kenli district of Dongying city for several successive years. Cultivation techniques are gradually improved.

Upon further research, it was discovered that it was impossible to meet the soil requirements of high-yielding fields even with the application of enough fertilizer to the saline alkali soil. The cultivation of groundnuts on alkali saline land is mainly to find a way to remove salt and then find a method of planting groundnuts on alkali saline land and prepare a special fertilizer for groundnuts on alkali land. alkali saline according to the characteristics of alkali saline earth and peanuts.

In order to solve the problems of the existing technique, on the basis of long-term improvement of cultivation measures and improvement and utilization studies of coastal alkali saline soils, the inventor carried out studies on the subtraction of salt and the addition of microbial preparations in a saline alkali soil, with the aim of reducing the salt content of the soil in a planting area and improving the microbial environment and increasing the rhizospheric microbial populations and their number, thereby improving the development of groundnut root systems; and a special groundnut fertilizer applied in an improved planting method is prepared in combination with conventional fertilization, and plays a great role in increasing the production of oil crops, such as groundnut, on alkali saline land .

The technical model of the present invention is as follows.

A method of planting peanuts on saline alkali soil includes the following steps: making a crop of the shape shown in Fig. 2 after fertilization, with a width of 70 to 110 cm; form a small furrow with a width and a depth of 8 to 12 cm in the middle of a sowing area; form elevations with a height of 10 to 20 cm and a lower width of 15 to 25 cm on the side edges; provide a spacing between rows of 35 to 55 cm; mulch the entire width for planting purposes, but leave 3-10cm unmulched on two side edges of the width; dig holes in a bottom layer in the minor furrow at intervals of 3 to 8 cm, and then cover the holes with soil.

The specific steps are as follows, when the crop is groundnut:
(1) apply special peanut fertilizer;
(2) carry out a ridging: carry out a culture of form represented in FIG. 2, with a width of 90 cm, form a small furrow with a width and a depth of 10 cm in the middle of a sowing area, and form elevations with a height of 15 cm and a lower width of 20 cm on the side edges;
(3) provide a spacing between rows of peanuts of 40 cm, and provide a horizontal distance of 20 cm from the spacing between rows of peanuts to the center line of the minor furrow;
(4) mulch the entire width for planting purposes, but providing 5cm unmulched on two side edges of the width, dig holes in a layer of mulch at the bottom of the minor furrow at 5cm intervals, and then cover the holes with 2 cm of soil.

The special fertilizers for peanuts applied into the planting method is prepared from the following raw materials in parts by weight: 0.2 to 25 parts of Trichoderma aureoviride, 40 to 60 parts of wheat bran, 10 to 30 parts sulfur coated urea and controlled release resin, 20-40 parts calcium ammonium nitrate, 30-50 parts calcium superphosphate, 10-30 parts potassium sulfate, 1-3 parts sulfate of iron and 10 to 30 parts of humic acid.

Preferably the specialty fertilizer for peanuts applied into the planting method is prepared from the following raw materials in parts by weight: 1.5 parts of Trichoderma aureoviride, 50 parts of wheat bran, 20 parts of urea coated with sulfur and controlled release resin, 30 parts calcium ammonium nitrate, 40 parts calcium superphosphate, 20 parts potassium sulphate, 2 parts iron sulphate and 20 parts humic acid.

The controlled release resin and sulfur coated urea is a mixture of controlled release resin and sulfur coated urea with various release periods of 30 to 90 days, having a grain size of 1 to 2 mm, and supplied by Stanley Agriculture Group Co., Ltd.

A method of preparing humic acid includes the following steps: adding 1 part natural sapropel raw material with 92 percent water content, 2 parts potassium pyrophosphate and 8 parts hot water at 80°C in a plastic bucket while shaking, continue shaking for 4 hours, allow to stand for 10 hours, and then collect the supernatant for later use.

A process for the preparation of the special groundnut fertilizer comprises the following steps:
1) adding Trichoderma aureoviride to wheat bran while stirring, continue stirring for 10 min, then spraying a total of about 70 per cent humic acid with stirring, compressing and granulating the mixture after stirred the mixture until it is in a uniform wet state in order to obtain hard particles having a diameter of 1.5 ± 0.2 mm and a density of approximately 1.2 g/cm ³ , and then drying the hard particles until the water content is less than or equal to 10 percent by weight;
2) Add calcium superphosphate powder to a stirring device, add iron sulfate powder while stirring, continue stirring for 10 min, then spray remaining humic acid while stirring, granulate the mixture after uniformly stirring the mixture to obtain particles having a diameter of 1 to 2 mm, and drying the particles until the water content is less than or equal to 10 percent by weight;
3) Mix the particles obtained in steps 1) and 2) with the remaining raw materials, stir for 4-5 mins until the materials are mixed completely and evenly, thereby obtaining the special fertilizer for groundnuts on saline alkali soil.

The holes are dug at the bottom of the small furrow according to the planting method of the present invention, so that rainwater can be conveniently collected and easily penetrate into the soil. Besides evaporation, the water moves to the high elevations on two sides from the bottom of the furrow and in doing so, the salt moves with the water, so that the salt content of the seeding area d peanuts is reduced, and a salt subtraction effect can be obtained.

The present invention provides the new special fertilizer for peanuts on saline alkali soil and a preparation method according to the unique biological characteristics of peanuts and the properties of saline alkali soil in the Yellow River Delta. Calcium superphosphate and iron sulfate are mixed, wrapped and prepared under the condition of taking Trichoderma aureoviride as the main raw material and combining the existing raw materials such as wheat bran, sulfur and resin coated urea ( granular), calcium ammonium nitrate (granular), calcium superphosphate (powder), potassium sulphate (granular), iron sulphate (granular) and humic acid (liquid), which resolves the problems of insufficient fertilizer for peanuts on saline alkali land, calcium deficiency and iron deficiency, reducing the influence of salt and alkali on peanuts, promoting growth and development, increasing fertilizer utilization rate, reducing fertilizer pollution, improving soil environment, improving soil fertility, promoting development and growth systems es roots of groundnuts and reduction of the negative effect of salt and alkalis on groundnuts.

The present invention has the following advantages:

1. The planting process improves the salt content of the alkali saline soil.

According to the planting method of the present invention, holes are dug at the bottom of the minor furrow in the crop of the form shown in FIG. 2, so that rainwater can be collected and soaked into the ground. Besides evaporation, the water moves to the high elevations on two sides from the bottom of the furrow, and the salt moves following the water, so the salt content of the sowing area of the peanuts is reduced, and that a salt subtraction effect can be obtained.

2. The combination of biological bacteria and slow-release fertilizer obviously improves the growth environment of peanuts on the alkali saline land and stimulates growth and development.

In the fertilizer formula of the present invention, the characteristics of high salinity, salt accumulation tendency, low fertility, iron deficiency, hardening tendency and the like of the soil of the alkali saline land are fully taken into account. The added biological bacteria enhance the activity of beneficial microorganisms and further reduce the influence of salt on the underground parts of peanuts; resin coated urea with various slow release periods effectively reduce nitrogen loss; and in cooperation with phosphorus, potassium, calcium and iron fertilizers, resin-coated urea can satisfy the nutritional requirements over the whole growing period of peanuts and promote healthy plant growth.

The yield-enhancing effect is excellent.

The yield-increasing effect of peanuts is remarkable when adopting the planting method of the present invention, the growing conditions of peanuts and the special fertilizer for peanuts applied in the method.

Fig. 1

is a flow diagram illustrating a method of planting crops on alkali saline soil.

Fig. 2

is a diagram of the shape of the culture.

The present invention is further described below in combination with specific embodiments. Various substitutions or modifications made according to ordinary skill in the art and conventional measures of the prior art without departing from the above technical concept of the present invention shall all fall within the scope of the present invention.

Embodiment 1

A method of planting groundnuts on saline alkali soil includes the following steps:
(1) a special peanut fertilizer was applied;
(2) ridging was carried out: a culture of the form represented in FIG. 2 was made, with a width of 90 cm, a small furrow with a width and a depth of 10 cm was formed in the middle of a sowing area, and elevations with a height of 15 cm and a lower width of 20 cm has been formed on the side edges;
(3) a groundnut row spacing of 40 cm was planned, and a horizontal distance of 20 cm from the groundnut row spacing to the center line of the minor furrow was planned;
(4) the whole width was mulched for planting purpose, but 5cm unmulched on two side edges of the width was planned, holes were dug in a layer of mulch at the bottom of the minor furrow at intervals of 5 cm, and then covered with 2 cm of soil.

The special fertilizers for peanuts applied in the process was prepared from the following raw materials in parts by weight: 1.5 parts of Trichoderma aureoviride at a concentration of 500 million CFU / g, 50 parts of sound shredded wheat, 4 parts sulfur resin coated urea controlled release with a 30 day release period, 8 parts sulfur resin coated urea controlled release with a 60 day release period, 8 parts sulfur and resin coated urea controlled release with a release period of 90 days, 30 parts calcium ammonium nitrate, 40 parts calcium superphosphate, 20 parts potassium sulfate, 2 parts iron sulphate and 20 parts of humic acid.

A process for the preparation of the special groundnut fertilizer comprises the following steps:
1) Trichoderma aureoviride was added to the wheat bran with stirring, the stirring was continued for 10 min, then a total of about 70 percent of the humic acid was sprayed with stirring, the mixture was compressed and granulated after stirring the mixture until it was in a uniform wet state to obtain hard particles with a diameter of 1.5 ± 0.2 mm and a density of approximately 1.2 g/cm ³ , and then the hard particles were dried until the water content was less than or equal to 10 weight percent;
2) Calcium superphosphate powder was added in a stirring apparatus, iron sulfate powder was added while stirring, stirring was maintained for 10 min, then the remaining humic acid was was pulverized while stirring, the mixture was granulated after uniformly stirring the mixture to obtain particles having a diameter of 1 to 2 mm, and the particles were dried until the water content was less than or equal to 10 percent by weight;
3) the particles obtained in steps 1) and 2) were mixed with the remaining raw materials and then stirred for 4 to 5 minutes until the materials were mixed completely and uniformly, so as to obtain the special fertilizer for peanuts on saline alkali soil.

The special fertilizer was applied at 75 g/m ² (50 kg/Mu).

Comparative example 1

A method of planting groundnuts on saline alkali soil includes the following steps:
(1) an ordinary chemical fertilizer was applied;
(2) ridging was carried out: a culture of the form represented in FIG. 2 was made, with a width of 90 cm, a small furrow with a width and a depth of 10 cm was formed in the middle of a sowing area, and elevations with a height of 15 cm and a lower width of 20 cm has been formed on the side edges;
(3) a groundnut row spacing of 40 cm was planned, and a horizontal distance of 20 cm from the groundnut row spacing to the center line of the minor furrow was planned;
(4) the whole width was mulched for planting purpose, but 5cm unmulched on two side edges of the width was planned, holes were dug in a layer of mulch at the bottom of the minor furrow at intervals of 5 cm, and then covered with 2 cm of soil.

Ordinary chemical fertilizer was adopted, namely nitrogen-phosphorus-potassium (15-15-15) compound fertilizer was applied at 75 g/m ² (50 kg/Mu).

Comparative Example 2

A special fertilizer for peanuts on a saline alkali land was prepared from the following raw materials in parts by weight: 1.5 parts of Trichoderma aureoviride at a concentration of 500 million CFU / g, 50 parts shredded wheat bran, 4 parts sulfur-resin coated urea controlled release with a 30-day release period, 8 parts sulfur-resin coated urea controlled release with a 60-day release period , 8 parts sulfur-resin coated urea controlled release with a release period of 90 days, 30 parts calcium ammonium nitrate, 40 parts calcium superphosphate, 20 parts potassium sulfate, 2 parts iron sulphate and 20 parts humic acid.

The preparation method and application rate of the special fertilizer were the same as in Embodiment 1. The only difference was that a conventional method was adopted for planting: the width of the area of sowing was 90 cm, the height of the elevations was 10 cm, the width of the surfaces of the elevations was 65 to 70 cm, the spacing between rows of groundnuts was 35 cm, the surfaces of the elevations were mulched, and the rays were not mulched.

Embodiment 2

A method of planting soybeans on saline alkali soil includes the following steps: a crop of the form shown in Fig. 2 was made, with a width of 70 cm; a small furrow with a width and a depth of 8 cm was formed in the middle of a sowing area and elevations with a height of 10 cm and a lower width of 15 cm were formed on the side edges ; a spacing between rows of 35 cm has been planned; the entire width has been mulched for planting purposes, but 5cm unmulched has been provided on two side edges of the width; holes were dug at the bottom of the small furrow at 8 cm intervals, and were covered with soil; and conventional fertilization was carried out.

Embodiment 3

A method of planting cotton on a saline alkali soil comprises the following steps: after application of a fertilizer, a crop of the form shown in Fig. 2 was made, with a width of 110 cm; a small furrow with a width and a depth of 12 cm was formed in the middle of a sowing area and elevations with a height of 20 cm and a lower width of 25 cm were formed on the side edges ; a spacing between rows of 55 cm has been planned; the entire width has been mulched for planting purposes, but 10cm unmulched has been provided on two side edges of the width; holes were dug in a bottom layer of the minor furrow at 3 cm intervals, and covered with soil.

Example of application effects

I. Comparison of Effects of Embodiment 1 and Comparative Examples 1 and 2

An alkali saline test land in Kenli District of Dongying City had a salinity of 0.25 percent; and Huayu 25 test groundnuts were sown in spring at a density of 10,000 holes, 2 kernels in each hole (included below). Conventional fertilization and ridging were taken for comparison (width of the sowing area: 90 cm, height of the ridges: 10 cm, width of the ridges: 65 to 70 cm, spacing between groundnut rows: 35 cm, mulching on the ridge surfaces, and no mulching on furrows). The experimental results of planting peanuts according to the methods of Embodiments 1 to 3 were as follows: with independent use of the planting method and the special fertilizer of the present invention, the emergence rate of peanuts, the amount of full pods per plant, full pod weight and 100-seed weight were all higher than values obtained with conventional fertilization and ridging, and yield was obviously higher; and with a combined use of the planting method and the special fertilizer of the present invention, the effect was more marked and the yield was increased by 26.9 percent, compared to the comparative examples. This indicates that the effect of salt subtraction and the effect of special fertilizer are obvious.

Table 1: Composition of groundnut production (average value in 2015-2016)

Note: the agronomic character of a plant is obtained by determining an average for representative plants (3 plants), and the yield per Mu is converted on the basis of the yield per section (6.67 m ² ).

II. Comparison of Effects of Embodiment 2

Qihuang 34 soybeans were selected and sown at 22.5 million seeds per km ² (15,000 seeds per Mu). Planting was carried out according to Embodiment 2, in comparison with a conventional soybean planting method; seed beds were made by tilling the soil using rotary tools; a spacing between rows of 40 cm has been planned. Table 2 shows that the emergence rate and yield of the soybeans of Embodiment 2 are considerably higher than those of the Comparative Example. This indicates that the planting method of the present invention is also suitable for soybeans and has a satisfactory salt-abstracting effect.

Table 2: Emergence rate and yield of soybean (average value in 2015-2016)

III. Comparison of Effects of Embodiment 3

Lumianyan 37 cotton was selected and sown at 6.75 million plants per km ² (4,500 plants per Mu). Planting was carried out according to Embodiment 3, in comparison with a conventional soybean planting method; seed beds were made by tilling the soil using rotary tools; a spacing between rows of 76 cm has been planned. Table 3 shows that the emergence rate and lint cotton yield of Embodiment 3 were considerably higher than those of Comparative Example. This indicates that the planting method of the present invention is also suitable for cotton and has a satisfactory salt-abstracting effect.

Table 3: Emergence rate and yield of cotton (average value in 2015-2016)

IV. Comparison of application effects of different biological bacteria

The following fertilizers were applied simultaneously according to the method of Embodiment 1, and the other management measures were the same.

In fertilizers, biological bacteria were, respectively, Trichoderma aureoviride, nitrogen fixing bacteria, bacteria solubilizing the phosphate solubilizing bacteria potassium, bacilli, methane oxidizing bacteria and nodule bacteria. Other components and preparation methods were the same as those of Embodiment 1.

Table 4: Influences on the physical characteristics of the soil and on the yield of a groundnut field in spring sowing

Table 4 shows that among the bacteria tested, Trichoderma aureoviride is the one that gave the best results on all tests with the lowest soil bulk density, the higher porosity, weight pods 100 and the weight of 100 seeds higher and the highest yield of up to 302.7 g / m ² (201.8 kg / Mu). This indicates that should be used Trichoderma aureoviride herein.

Claims (7)

A method of planting a crop on a saline alkali soil, comprising the following steps: making a crop after fertilization, with a width of 70 to 110 cm; form a small furrow with a width and a depth of 8 to 12 cm in the middle of a sowing area; form elevations 10 to 20 cm high and 15 to 25 cm less wide on the side edges, with a spacing between rows of 35 to 55 cm; mulch the entire width for planting purposes, but leave 3-10cm unmulched on two side edges of the width; dig holes in a bottom layer in the minor furrow at intervals of 3 to 8 cm, and then cover the holes with soil. A method according to claim 1, wherein the specific steps are as follows, when the crop is groundnut:
(1) apply special peanut fertilizer;
(2) make a ridging: make a crop with a width of 90 cm, form a small furrow with a width and a depth of 10 cm in the middle of a sowing area, and form elevations with a height of 15 cm and a width less than 20 cm on the side edges;
(3) provide a spacing between rows of peanuts of 40 cm, and provide a horizontal distance of 20 cm from the spacing between rows of peanuts to the center line of the minor furrow;
(4) mulch the entire width for planting purposes, but providing 5cm unmulched on two side edges of the width, dig holes in a layer of mulch at the bottom of the minor furrow at 5cm intervals, and then cover the holes with 2 cm of soil. A method according to claim 2, wherein the fertilizer special for peanuts mentioned in step (1) is prepared from the following raw materials in parts by weight: 0.2 to 25 parts of Trichoderma aureoviride, 40-60 parts wheat bran, 10-30 parts sulfur-coated urea and controlled-release resin, 20-40 parts calcium ammonium nitrate, 30-50 parts calcium superphosphate, 10-30 parts potassium sulfate, 1-3 parts iron sulfate and 10-30 parts humic acid. A method according to claim 3, wherein the fertilizer special for peanuts mentioned in step (1) is prepared from the following raw materials in parts by weight: 1.5 parts of Trichoderma aureoviride, 50 parts of sound wheat, 20 parts sulfur-coated urea and controlled-release resin, 30 parts calcium ammonium nitrate, 40 parts calcium superphosphate, 20 parts potassium sulfate, 2 parts iron sulfate, and 20 parts of humic acid. A process according to claim 3 or 4, wherein the sulfur-coated urea and controlled-release resin is a mixture of sulfur-coated urea and controlled-release resin exhibiting various release periods of 30 to 90 days, having a grain size from 1 to 2 mm. Process according to claim 3 or 4, wherein the process for the preparation of humic acid comprises the following steps: adding 1 part of raw material of natural sapropel with a water content of 92 percent, 2 parts of potassium pyrophosphate and 8 parts hot water at 80°C in a plastic bucket while stirring, continue stirring for 4 hours, allow to stand for 10 hours, and then collect the supernatant liquid for later use. Process according to claim 3, wherein the process for preparing the special peanut fertilizer comprises the following steps:
1) adding Trichoderma aureoviride to wheat bran while stirring, continue stirring for 10 min, then spraying a total of about 70 per cent humic acid with stirring, compressing and granulating the mixture after stirred the mixture until it is in a uniform wet state in order to obtain hard particles having a diameter of 1.5 ± 0.2 mm and a density of approximately 1.2 g/cm ³ , and then drying the hard particles until the water content is less than or equal to 10 percent by weight;
2) Add calcium superphosphate powder into a stirring device, add iron sulfate powder while stirring, continue stirring for 10min, and then spray the remaining humic acid while stirring, granulate the mixing after uniformly stirring the mixture to obtain particles having a diameter of 1 to 2 mm, and drying the particles until the water content is less than or equal to 10 percent by weight;
3) Mix the particles obtained in steps 1) and 2) with the remaining raw materials, stir for 4-5 mins until the materials are mixed completely and evenly, thereby obtaining the special fertilizer for groundnuts on saline alkali soil.