CN114467648A - Cultivation method for improving lodging resistance and seed yield of bromus fasciatus - Google Patents

Abstract

The invention discloses a cultivation method for improving lodging resistance and seed yield of bromus fasciatus, and belongs to the technical field of crop cultivation. The method comprises the step of spraying a lodging-resistant solution in the jointing stage and/or the booting stage of the bromus fasciatus, wherein the lodging-resistant solution comprises an lodging-resistant ester solution and a silicon fertilizer solution, and the spraying amount of the lodging-resistant solution is 700mL/15m². The cultivation method can obviously reduce the plant height of the plant, improve the breaking resistance of the plant, reduce the lodging area and obviously improve the seed yield of the plant while enhancing the growth vigor of the brome oblata, and compared with the brome oblata planting field which is lodging under the same condition, the yield of the brome oblata per hectare can be increased by 10.7 percent at mostAnd the economic benefit is increased by 8680.63 yuan per hectare, so that the method brings good economic benefit to the field of planting the brome fasciata and has wide market application prospect.

Description

Cultivation method for improving lodging resistance and seed yield of bromus fasciatus

Technical Field

The invention relates to the technical field of crop cultivation, in particular to a cultivation method for improving lodging resistance and seed yield of brome fasciata.

Background

The brome platyphylla is cold-season annual or short-term perennial high-quality pasture, the species is native to south America Panpaspalum pratense, germplasm resources of brome platyphylla in China are mainly distributed in southwest, China, North China and northwest China, and escaped resources exist in partial regions. The brome fasciata has late ear emergence and early green turning, can obtain higher fresh grass yield in the current year of sowing, and the stalks can still keep green after the seeds are mature, thereby still having higher nutritive value. It is suitable for planting artificial grassland under forest and fruit tree, and may be used in planting artificial grassland, planting grass in idle field in south China, raising farm animal and controlling water and soil loss. Under the humid and shady environment of Sichuan winter and spring, the brome platyphylla still can keep the green state, has good palatability, is eaten by various livestock, and is one of the best pastures for making up the shortage of green feed of livestock in winter and spring.

In the plateau area of Chengdu, the yield of the plant ears is 5-6 months in the 4 months of the next year in the filling period of the brome platoon, the weight of the plant ears is gradually increased in the period, the plant ears gradually enter rainy seasons, extreme weather such as strong wind is increased, and the plant lodging causes the phenomenon of yield reduction. After the brome platura is lodged, the photosynthesis is limited, and the transportation, storage and accumulation of organic substances are seriously influenced, so that the yield of the brome platura seed is reduced. If the brome oblata falls down in the middle and later periods and encounters continuous rainy weather, grains can mildew and germinate, and the quality of the grains is adversely affected. The yield is reduced and the quality is deteriorated after the brome oblata falls down, the harvest is influenced, the harvest difficulty is increased, and the loss rate of grains is increased. Researches show that the yield reduction amplitude of the brome fasciata caused by lodging is about 20-30 percent, and even the brome fasciata is out of production.

Therefore, the lodging-resistant cultivation technology of the bromus fasciatus is widely popularized, and the contradiction relationship between high yield and lodging resistance and between high quality and lodging resistance is coordinated in practical production, so that the yield of the bromus fasciatus seeds is further improved, and the bromus fasciatus has a positive influence on the promotion of the development of the grassland animal husbandry in China.

In the prior art, a study of spraying 500-1000 mg/L paclobutrazol to the heading stage and the flowering stage of bromus fasciatus is carried out, mainly aims at researching the influence of the paclobutrazol to the yield of bromus fasciatus seeds, and has no obvious effect of improving the lodging resistance of the bromus fasciatus.

Therefore, it is necessary to provide a method for improving the lodging resistance of bromus fasciatus and increasing the seed yield.

Disclosure of Invention

The invention aims to provide a cultivation method for improving lodging resistance and seed yield of bromus fasciatus, which aims to solve the problems in the prior art.

In order to achieve the purpose, the invention provides the following scheme:

the invention provides a cultivation method for improving lodging-resistant capability and seed yield of bromus oblata, which comprises the step of spraying a lodging-resistant solution on the bromus oblata in the jointing stage and/or the booting stage.

Further, the lodging-resistant solution comprises an trinexapac-ethyl solution and a silicon fertilizer solution.

Further, the concentration of the trinexapac-ethyl solution is 150-450g/hm²The concentration of the silicon fertilizer solution is 467-doped 1867g/hm²。

Further, the spraying amount of the lodging-resistant solution is 700mL/15m²。

Further, the method comprises the following steps:

(1) preparing land, namely selecting land blocks which are flat in terrain, medium and uniform in soil fertility, consistent in previous crops, free of weeds, free of soil-borne diseases, good in irrigation and drainage conditions and free of buildings or trees around, applying fertilizers to the selected land blocks, then carrying out plowing treatment, and irrigating water on the soil moisture of soles after plowing;

(2) seed treatment: after each kg of seeds are dressed with 3g of seed dressing agent, airing for 1-2 days, wherein the seed dressing agent is a mixture of thiram and carboxin, and the active ingredient contents of the thiram and the carboxin are both 200 g/L;

(3) sowing: selecting ten days of 10 months to 11 months, wherein the temperature is 20 to 25 ℃, and drilling the treated seeds with the seeding rate of 24kg/hm²The row spacing is 40cm, the sowing depth is 2-3cm, and the soil is attached to 1-2cm after sowing;

(4) field management: seedling searching, weed removing, irrigation, lodging-resistant management and topdressing;

(5) harvesting: and (4) harvesting when the moisture of the brome fasciata seeds is reduced to below 16% in the middle and later mature period.

Further, the fertilizer in the step (1) is farmyard manure, and the application amount is 15000-²The plowing treatment comprises applying 150kg/hm of urea during plowing²Diammonium 70kg/hm²100kg/hm of potassium chloride²And phoxim 4kg/667m²。

Further, the irrigation in the step (4) is specifically as follows: 1) proper watering is carried out when drought occurs in the seedling emergence period, so as to ensure seedling emergence; 2) irrigating by sprinkling irrigation in the water shortage period of the green turning period until the soil is not loosened by holding with hands; 3) adopting a spray irrigation mode when water is deficient in the tillering stage, wherein the irrigation depth is 5-6 cm; 4) during the jointing stage drought, the method is carried out in a spray irrigation or flood irrigation mode, and the irrigation depth is more than 10 cm; 5) irrigating by sprinkling irrigation when water is deficient in the booting stage until the soil is not loosened by holding with hands; 6) and in the mature period, if strong rainfall weather occurs, paying attention to timely drainage.

Further, the additional fertilizer in the step (4) is specifically as follows: 1) and (3) tillering fertilizer: after 50% of plants enter the tillering stage, applying 50kg/hm of urea²(ii) a 2) Ear fertilization: after 50% of plants enter the heading stage, 70kg/hm of urea is applied²。

The invention discloses the following technical effects:

trinexapac-ethyl can inhibit the later period of Gibberellin (GA) biosynthesis in plant, and mainly regulates the growth of plant by increasing the content of chlorophyll, cellulose, lignin, various enzymes and other substances in plant; the silicon fertilizer can improve the silicification degree of the brome platura and has an important effect on enhancing the lodging resistance of the stems of the brome platura.

According to experimental research, the invention discovers that the reasonably compounded trinexapac-ethyl solution and the silicon fertilizer solution are sprayed at the same time in the jointing stage and the booting stage of the bromus fasciatus, so that the bromus fasciatus growth is enhanced, the plant height of a plant is obviously reduced, the bending resistance of the plant is improved, the lodging area is reduced, the seed yield of the plant is obviously improved, the problems of large-area lodging, kernel mildew, low quality, high harvesting difficulty, serious kernel loss, unstable yield and the like easily occurring in the production of the bromus fasciatus seeds are solved, and the problem that two contradictions of high yield and lodging resistance, high quality and lodging resistance, which are commonly existing in the production of the bromus fasciatus seeds, are not adjustable is solved.

Meanwhile, the cultivation method provided by the invention is developed in Sichuan plain and low-altitude areas, large-area lodging of brome can be effectively prevented, the yield of brome per hectare can be increased by 10.7% to the maximum extent compared with the brome planting field which is lodging under the same condition, and the economic benefit per hectare can be increased by 8680.63 yuan. Therefore, the method brings good economic benefits to the field of planting the bromus fasciatus and has wide market application prospect.

Detailed Description

Reference will now be made in detail to various exemplary embodiments of the invention, the detailed description should not be construed as limiting the invention but as a more detailed description of certain aspects, features and embodiments of the invention.

It is to be understood that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. Further, for numerical ranges in this disclosure, it is understood that each intervening value, between the upper and lower limit of that range, is also specifically disclosed. Every smaller range between any stated value or intervening value in a stated range and any other stated or intervening value in a stated range is encompassed within the invention. The upper and lower limits of these smaller ranges may independently be included or excluded in the range.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Although only preferred methods and materials are described herein, any methods and materials similar or equivalent to those described herein can be used in the practice or testing of the present invention. All documents mentioned in this specification are incorporated by reference herein for the purpose of disclosing and describing the methods and/or materials associated with the documents. In case of conflict with any incorporated document, the present specification will control.

It will be apparent to those skilled in the art that various modifications and variations can be made in the specific embodiments of the present disclosure without departing from the scope or spirit of the disclosure. Other embodiments will be apparent to those skilled in the art from consideration of the specification. The description and examples are intended to be illustrative only.

As used herein, the terms "comprising," "including," "having," "containing," and the like are open-ended terms that mean including, but not limited to.

Example 1

A cultivation method for improving lodging resistance and seed yield of bromus fasciatus comprises the following steps:

(1) land preparation: selecting land parcels with smooth terrain, moderate and uniform soil fertility, consistent previous crops, no weeds, no soil-borne diseases, good irrigation and drainage conditions and no buildings or trees around; applying 15000kg/hm of farmyard manure per mu in the selected land blocks²Then ploughing, and applying 250kg/hm of urea in deep ploughing²120kg/hm of diammonium²150kg/hm potassium chloride². 5kg/667m phoxim is broadcast applied to each mu during plowing²And is used for preventing and controlling soil insects. Irrigating water in the soil moisture of the sole after plowing.

(2) Seed treatment:

1) seed dressing: the smut is prevented and treated by dressing 3g/kg of seed dressing agent, the seed dressing agent is a mixture of thiram and carboxin, wherein the content of active ingredients of the thiram is 200g/L, and the content of active ingredients of the carboxin is 200 g/L.

2) And (3) airing: sun-drying for 1 day, and turning over for 2 times per day.

(3) Sowing: sowing at the beginning of 10 months at an environment temperature of 20 ℃ and a sowing amount of 24kg/hm². Adopting ditching and drilling with the row spacing of 40 cm. The depth of ditching and sowing is 2cm, and the soil is attached to the sowed part for 1 cm.

(4) Managing after seed emergence:

1) seedling searching: after the seeds emerge for one week, the emergence situation in the field is checked, and if the lack of seedlings is more than 1m, the seeds should be sowed in time and reseeded.

(5) Managing weeds:

after emergence of seedlings, weeds appearing in large areas are prevented and removed in an artificial removal or chemical control mode.

The weed management method comprises the following specific steps:

a treatment of soil

1) The pesticide is applied to the wild oat to cause severe plots before sowing, and the 40% of the avenantha missible oil 175ml/667m can be used before land preparation and sowing²Adding water, uniformly spraying on the ground, harrowing the ground vertically and horizontally by using a wafer in time after the application, mixing the medicament into a 10cm soil layer, and then sowing. Has better control effect on the alopecurus as well as the bluegrass.

2) After sowing, the chemical herbicide is applied before seedling to seal soil, and the effect on the brome platysternon planting field after sowing can be more obvious. The medicaments used were: 25% chlortoluron wettable powder 200g/667m²Adding 50kg of water, spraying 2 days after sowing the sparassis spades, performing surface treatment, or using 75g/667m of 50% prometryn wettable powder²Or 100ml/667m of 50% of bentazon emulsifiable concentrate and 48% of inhaul emulsifiable concentrate respectively²After mixing, water is added to spray the mixture on the ground, and gramineous weeds and some broadleaf weeds can be effectively prevented and removed.

b weeding in later growth stage

1) The artificial weeding method is adopted, and weeds are transported out after the weeding.

2) When broad-leaved weeds are mainly used in the bromus platyphylla planting field in spring, DuPont giant star, methoxone, Maxi and the like can be selected for carrying out stem leaf treatment.

3) For the field planted with the sparassis oblata with wild oat and other monocotyledon weeds and broad-leaved weeds, the herbicide can be mixed with, for example, 75% of giant star and 6.9% of Biaoma, methoxone and bentazon, chlorfenapyr, prometryn or indian farmer, 2.4-D butyl ester and Biao tiger, etc., so that the weed control spectrum can be expanded, and the weeding effect can be effectively improved. The pesticide spraying time is generally from the wheat turning green to the initial stage of jointing, the pesticide spraying method is proper, and the severe weather such as strong wind, low temperature, dry and early season, cold tide and the like is avoided during pesticide spraying.

4) Pest control in later growth stage

And (3) preventing and controlling aphids in the ear stage, wherein the amount of the hundred aphids exceeds 500 heads in the early stage of poplar flower grouting, and the aphids are sprayed by adding water 15kg into 30ml of Baijia + 5g of Lei war or 30ml of Baijia + 15ml of nongxing, or 30ml of nongxing + 5g of Lei war.

5) Disease control in later growth stage

In the period from the late booting stage of the brome fasciata to the early heading stage, powdery mildew begins to occur, 8g of 30% kresoxim-methyl is applied, 15kg of beautiful/beautiful I is added with water, and 30-45kg of the powdery mildew is applied to each mu of land.

(6) Irrigation management:

1) and (3) seedling stage: and drought occurs after sowing, watering is carried out in time, the water content is not excessive, and seedling emergence is ensured.

2) And (3) a green turning period: when the soil is lack of water, irrigation is carried out in a sprinkling irrigation mode, and the soil is held by hands and is not loosened as an irrigation standard.

3) And (3) tillering stage: irrigate with the mode of sprinkling irrigation when the soil lacks water, will give the more moisture of ribbon-ear sparrow wheat this moment, satisfy its growth demand, irrigate the degree of depth and be 5 cm.

4) And (3) jointing stage: at the moment, the brome fasciata needs more water, when the soil is dry, a spray irrigation or flood irrigation mode is adopted, and the irrigation depth is more than 10 cm.

5) And (3) booting stage: when the soil is lack of water, irrigation is carried out in a sprinkling irrigation mode, and the soil is held by hands and is not loosened as an irrigation standard.

6) And (3) mature period: at the moment, the brome spades do not need too much water, and drainage is needed in time if heavy rainfall weather occurs.

(7) Lodging resistance chemical control management:

1) and spraying the lodging-resistant solution once in the jointing stage of the brome platura.

2) And (4) spraying the lodging-resistant solution once in the booting period of the bromus fasciatus.

3) And (3) spraying the lodging-resistant solution once in the jointing and booting period of the brome oblata.

The urea is applied in different growth periods of the brome oblata to meet the growth requirement of the brome oblata. The specific fertilization method comprises the following steps:

1) and (3) tillering fertilizer: after 50% of plants enter the tillering stage, applying 50kg/hm of urea²。

2) Ear fertilization: after 50% of plants enter the heading stage, 70kg/hm of urea is applied²。

(8) Harvesting the seeds of the brome platura: and harvesting the bromus oblata in the middle and later stages of the complete maturity of the bromus oblata until the moisture of the seeds is naturally reduced to below 16 percent.

Example 2

A cultivation method for improving lodging resistance and seed yield of bromus fasciatus comprises the following steps:

(1) land preparation: selecting land parcels with smooth terrain, medium and uniform soil fertility, consistent crops in the previous crops, no weeds, no soil-borne diseases, good irrigation and drainage conditions and no buildings or trees around; 22500kg/hm of farmyard manure is applied to each mu in a selected land block²Then ploughing, and applying 150kg/hm of urea in deep ploughing²Diammonium 70kg/hm²100kg/hm of potassium chloride². 4kg/667m phoxim is broadcast applied to each mu during plowing²And is used for preventing and controlling soil insects. Irrigating water in the soil moisture of the sole after plowing.

(2) Seed treatment:

1) seed dressing: the smut is prevented and treated by dressing 3g/kg of seed dressing agent, the seed dressing agent is a mixture of thiram and carboxin, wherein the content of active ingredients of the thiram is 200g/L, and the content of active ingredients of the carboxin is 200 g/L.

2) And (3) airing: sun-drying for 2 days, and turning over for 1 time every day.

(3) Sowing: sowing in 11-month last ten days at 25 deg.C and 24kg/hm². Adopting ditching and drilling with the row spacing of 40 cm. The depth of ditching and sowing is 3cm, and the soil is attached to the sowed soil by 2 cm.

(4) Managing after seed emergence:

1) seedling searching: after the seeds emerge for one week, the emergence situation in the field is checked, and if the lack of seedlings is more than 1m, the seeds should be sowed in time and reseeded.

(5) And (3) weed management:

after emergence of seedlings, weeds appearing in large areas are prevented and removed in an artificial removal or chemical control mode.

The weed management method comprises the following specific steps:

a treatment of soil

1) The pesticide is applied to the wild oat to cause severe land mass before sowing, and 40% of avenantha missible oil 200ml/667m can be used before land preparation and sowing²Adding water, uniformly spraying on the ground, harrowing the ground vertically and horizontally by using a wafer in time after the application, mixing the medicament into a 10cm soil layer, and then sowing. Has better control effect on the alopecurus as well as the bluegrass.

2) After sowing, the pesticide application before the seedling adopts chemical herbicide to seal the soil, and the method can play a remarkable effect on the bromus platanus planting field before the seedling after the sowing. The medicaments used were: 25% chlortoluron wettable powder 400g/667m²Adding 50kg of water, spraying 2 days after sowing bromus oblata, and performing surface treatment, or using 50% prometryn wettable powder 100g/667m²Or 100ml/667m of 50% of bentazon emulsifiable concentrate and 48% of inhaul emulsifiable concentrate respectively²After mixing, water is added to spray the mixture on the ground, and gramineous weeds and some broadleaf weeds can be effectively prevented and removed.

b weeding in later growth stage

1) The artificial weeding method is adopted, and weeds are transported out after the weeding.

2) When broad-leaved weeds are mainly used in the bromus platyphylla planting field in spring, DuPont giant star, methoxone, Maxi and the like can be selected for carrying out stem leaf treatment.

3) For the field planted with the sparassis oblata with wild oat and other monocotyledon weeds and broad-leaved weeds, the herbicide can be mixed with, for example, 75% of giant star and 6.9% of Biaoma, methoxone and bentazon, chlorfenapyr, prometryn or indian farmer, 2.4-D butyl ester and Biao tiger, etc., so that the weed control spectrum can be expanded, and the weeding effect can be effectively improved. The pesticide spraying time is generally from the wheat turning green to the initial stage of jointing, the pesticide spraying method is proper, and the severe weather such as strong wind, low temperature, dry and early season, cold tide and the like is avoided during pesticide spraying.

4) Pest control in later growth stage

And (3) preventing and controlling aphids in the ear stage, wherein the amount of the hundred aphids exceeds 500 heads in the early stage of poplar flower grouting, and the aphids are sprayed by adding water 15kg into 30ml of Baijia + 5g of Lei war or 30ml of Baijia + 15ml of nongxing, or 30ml of nongxing + 5g of Lei war.

5) Disease control in later growth stage

In the period from the late booting stage of the brome fasciata to the early heading stage, powdery mildew begins to occur, 8g of 30% kresoxim-methyl is applied, 15kg of beautiful/beautiful I is added with water, and 30-45kg of the powdery mildew is applied to each mu of land.

(6) Irrigation management:

1) and (3) seedling stage: and drought occurs after sowing, watering is carried out in time, the water content is not excessive, and seedling emergence is ensured.

2) And (3) a green turning period: when the soil is lack of water, irrigation is carried out in a sprinkling irrigation mode, and the soil is held by hands and is not loosened as an irrigation standard.

3) And (3) tillering stage: irrigate with the mode of sprinkling irrigation when the soil lacks water, will give the more moisture of ribbon-ear sparrow wheat this moment, satisfy its growth demand, irrigate the degree of depth and be 6 cm.

4) In the jointing stage: at the moment, the brome fasciata needs more water, when the soil is dry, a spray irrigation or flood irrigation mode is adopted, and the irrigation depth is more than 10 cm.

5) And (3) booting stage: when the soil is lack of water, irrigation is carried out in a sprinkling irrigation mode, and the soil is held by hands and is not loosened as an irrigation standard.

6) And (3) mature period: at the moment, the brome spades do not need too much water, and drainage is needed in time if heavy rainfall weather occurs.

(7) Lodging resistance chemical control management:

1) and spraying the lodging-resistant solution once in the jointing stage of the brome platura.

2) And (3) spraying the lodging-resistant solution once in the booting period of the bromus fasciatus.

3) And (3) spraying the lodging-resistant solution once in the jointing and booting period of the brome oblata.

The urea is applied in different growth periods of the brome oblata to meet the growth requirement of the brome oblata. The specific fertilizing method comprises the following steps:

1) and (3) tillering fertilizer: after 50% of plants enter the tillering stage, 70kg/hm of urea is applied²。

2) Ear fertilizer: after 50% of plants enter the heading stage, 180kg/hm of urea is applied²。

(8) Harvesting the seeds of the brome platura: harvesting the seeds at the middle and later stages of the complete maturity of the brome fasciata when the moisture of the seeds is naturally reduced to below 16 percent.

Test example 1

The inventor utilizes different concentrations of lodging-resistant solutions to explore the lodging-resistant capability and seed yield of the 'Chuanxi' bromus spades in different growth periods in the grassy test base of Sichuan agricultural university in Sichuan province in 2021.

1. Test materials

The material used in the test, named Chuanxi sparrow wheat, is a national examined variety and is provided by the grass subject group of the grassy system of Sichuan agricultural university; trinexapac-ethyl (AR grade) is provided by shanghai-sourced leaf biotechnology limited; the silicon fertilizer is sodium silicate (Na)₂SiO₃·9H₂O), provided by the national chemical group, ltd, class GR.

(1) Preparation method of trinexapac-ethyl solution

①150g/hm²Preparation method of trinexapac-ethyl

Because the trinexapac-ethyl solution is missible oil, the trinexapac-ethyl solution is dissolved in alcohol and then dissolved in water. Dissolving 182 μ L of trinexapac-ethyl solution in 10ml of alcohol, adding 690ml of water into spray tank during spraying, adding prepared trinexapac-ethyl solution, shaking, and spraying

②300g/hm²Preparation method of trinexapac-ethyl

Because the trinexapac-ethyl solution is missible oil, the trinexapac-ethyl solution is dissolved in alcohol and then dissolved in water. Dissolving 363 μ L of trinexapac-ethyl solution in 10ml of alcohol, adding 690ml of water into spray bucket during spraying, adding prepared trinexapac-ethyl solution, shaking up, and spraying

③450g/hm²Preparation method of trinexapac-ethyl

Because the trinexapac-ethyl solution is missible oil, the trinexapac-ethyl solution is dissolved in alcohol and then dissolved in water. Dissolving 454 μ L of trinexapac-ethyl solution in 10ml of alcohol, adding 690ml of water into spray tank during spraying, adding prepared trinexapac-ethyl solution, shaking, and spraying

(2) Preparation method of silicon fertilizer solution

①467g/hm²Preparation method of silicon fertilizer

0.7g of sodium silicate is weighed and dissolved in 0.7L of water, and the mixture is shaken up before being sprayed.

②1167g/hm²Preparation method of silicon fertilizer

1.75g of sodium silicate is weighed and dissolved in 0.7L of water and shaken up before spraying.

③1867g/hm²Preparation method of silicon fertilizer

2.8g of sodium silicate is weighed and dissolved in 0.7L of water, and the mixture is shaken up before being sprayed.

(3) Preparation method of trinexapac-ethyl and silicon fertilizer mixed solution

①150g/hm²Trinexapac-ethyl of +467g/hm²Silicon fertilizer

0.7g of sodium silicate is weighed and dissolved in 0.7L of water, 182 mu L of trinexapac-ethyl solution is dissolved in 10ml of alcohol, and the two solutions are fully and evenly mixed before spraying.

②300g/hm²Trinexapac-ethyl of +1167g/hm²Silicon fertilizer

Weighing 1.75g of sodium silicate, dissolving in 0.7L of water, dissolving 363 mu L of trinexapac-ethyl solution in 10ml of alcohol, and mixing the two solutions before spraying.

③450g/hm²Trinexapac-ethyl of +1867g/hm²Silicon fertilizer

2.8g of sodium silicate is weighed and dissolved in 0.7L of water, 454 mu L of trinexapac-ethyl solution is dissolved in 10ml of alcohol, and the two solutions are fully and evenly mixed before spraying.

2. General description of the test site

The experimental region is a grassy teaching and scientific research base of the Sichuan agriculture university of Oncorhynchus Chongzhou city of Sichuan province, which is located at 103 degrees 21 'of east longitude and 30 degrees 32' of north latitude, has an altitude of 512m, and is a continental tropical humid monsoon climate. The average temperature of the whole year is 15.6 ℃, the average temperature of the hottest month is 28.3 ℃, and the average temperature of the coldest month is 5.2 ℃. The average annual sunshine hours is 1172.3h, the average annual rainfall is 1021.3mm, and the soil pH is 6.2. Organic matter 35.9g/kg¹The effective phosphorus content of the soil is 9.6mg/kg¹Total nitrogen content 2.15g/kg¹The effective potassium content is 79mg/kg¹. The previous crop is sorghum.

3. Design of experiments

The experiment is completed in 2020-²(3 x 5m), the cell spacing is 0.5m, drill seeding is adopted, and the row spacing is 40 cm. The sowing depth is 2-3cm, the soil is attached to the sowing depth is 1-2cm, and the sowing quantity is 24kg/hm²Each treatment is repeated for 3 times, 1m protective rows are arranged on the periphery of the test field, 3g/kg of seed dressing agent is used for dressing seeds before sowing to prevent smut, and the cultivation and planting are carried out according to the method of the embodiment 1.

Selecting windless and sunny weather, respectively spraying lodging-resistant solution on leaf surfaces in the jointing stage, the booting stage, the jointing stage and the booting stage of the Aleurea oblata in 'Chuanxi', separating test cells by using barriers during spraying, spraying the test cells with the application dosage of 700ml, spraying tap water on a control group, spraying by using a spraying cylinder, and taking the condition that leaves on the upper part of a plant are moist and do not drip water as a standard. Harvesting in the wax ripeness stage of the seeds, and further measuring various physiological indexes of the seeds. The application concentrations are shown in table 1:

TABLE 1 application periods and concentrations of lodging-resistant solutions

Comparative example 1

The difference from test example 1 is that trinexapac-ethyl is replaced by paclobutrazol. The application is shown in table 2:

TABLE 2

Comparative example 2

The difference from test example 1 is that the lodging resistant solution includes only the trinexapac-ethyl solution. The application is shown in table 3:

TABLE 3

Comparative example 3

The difference from test example 1 is that the lodging-resistant solution includes only the silicon fertilizer solution. The application is shown in Table 4:

TABLE 4

Test example 2

The brome oblata was cultivated by the methods of test example 1 and comparative examples 1 to 3, and each index was examined by the following method:

1. measurement items and methods

1.1 agronomic traits

1.1.1 plant height

The height of the plant is measured by a metric ruler by randomly selecting 10 positions of reproductive branches (fixed by a label) in each test cell, and the data are averaged and carried out in the milk stage.

1.1.2 measurement of second and third Stem node Length, Stem thickness and wall thickness

The reproductive branches at 10 positions are randomly selected in each test cell, the lengths of the second section and the third section (the part close to the ground is the first section) are measured by using a ruler, the thickness of the outer diameter (the leaf sheath is peeled off) and the wall thickness are measured by using a vernier caliper, and the data are averaged and carried out in the milk stage.

1.1.3 ear root and ear Length

And randomly selecting 10 positions of reproductive branches in each test cell, measuring the lower ear nodes and the ear length of the reproductive branches by using a ruler, measuring the lower ear node thickness by using a vernier caliper, and averaging the data to perform in the milk stage.

1.1.4 reproductive shoot number and tiller number

Selecting 3 sampling rows with uniform growth and 0.2m in each test cell, measuring the number of reproductive branches and tillering, averaging the data, and performing in the milk stage.

1.1.5 spikelets and seeds

Randomly selecting 10 positions of reproductive branches in each test cell, and determining the spikelet number and the seed number of the reproductive branches, wherein the spikelet number is carried out in the full-bloom stage, and the spikelet number and the seed number are carried out in the milk stage

1.1.6 stalk breaking strength, lodging resistance index and stalk filling degree

In the determination of milk maturity of the \ "Chuanxi \" sparassia platyphylla, 10 reproductive branches were randomly selected. Taking back the stalks in the field, and keeping the leaf sheaths, the leaves and the ears. Placing the internode stem (with the leaf sheath reserved) to be measured on a measuring device, enabling the internode middle point to correspond to the middle point of the measuring device (the distance between the fulcrums is 5cm), hanging a spring scale at the middle point, pulling the spring scale downwards slowly until the stem is broken, recording the scale value of the spring scale at the moment, converting the scale value into mass, and multiplying the mass by the gravity acceleration to obtain the anti-bending force of the internode of the stem.

And (4) calculating the stalk lodging index, namely randomly taking 10 representative single stalks from each test cell in the milk stage, measuring the bending resistance of the second and third internodes of the stalks, the length from the base of the internode to the top of the ear and the fresh weight of the stalks, and calculating the bending moment and the lodging index of N3 and N4 according to the method of Rex ancient and Xiuguo.

Bending moment (m) internode base to ear tip length (cm) x fresh weight (g) from internode base to ear tip

Lodging index (bending moment/breaking resistance x 100)

Stalk filling degree, dry weight between stalk nodes (mg)/length between nodes (cm)

1.2 measurement of chlorophyll content

The method comprises the steps of measuring in the blooming period of 'Chuanxi' brome, cutting the middle part of the flag leaf of the brome, cleaning dirt on the surface of the leaf, then, sucking water on the surface of the leaf by using absorbent paper, cutting the leaf into pieces with the diameter of less than 2mm, uniformly mixing, accurately weighing 0.2g of the mixture, and placing the pieces into a test tube with the volume of more than 15 mL. And (3) fixing the volume of dimethyl sulfoxide (DMSO) to 10ml (keeping out of the sun), shaking once every 10min until the leaves are completely whitened, putting 3ml of DMSO chlorophyll leaching liquor into a cuvette, taking DMSO stock solution as a blank, measuring by using a spectrophotometer, reading optical density values of 645nm and 663nm, putting the extracted sample into a 65 ℃ oven to dry, and calculating the chlorophyll content according to a formula used by Anron.

Chl a content (mg/L) ═ 12.7 × OD₆₆₃+2.59×OD₆₄₅)×V/(W×1000)

Chl b content (mg/L) ═ 22.9 × OD₆₄₅+4.68×OD₆₆₃)×V/(W×1000)

Chl (a + b) content (mg/L) ═ 20.2 × OD₆₄₅+8.02×OD₆₆₃)×V/(W×1000)

In the formula, OD: measuring the optical density value at the wavelength; v: total volume (ml) of chlorophyll extract; w: sample dry weight (g).

1.3 determination of grain filling Rate

Grouting rate determination and calculation: and (3) selecting main scions with consistent initial flowering period, and sampling from the 7 th day after flowering, wherein the sampling is carried out for 1 time every 7d until the scions are mature. Randomly selecting 10 main stem ears in each test cell, respectively taking 10 seeds in the middle of each ear, taking 100 seeds in total, determining the fresh weight of the seeds, then drying for 30min at 105 ℃ for enzyme deactivation, then drying for 24h at 80 ℃ to constant weight, and weighing the seeds to thousand weight. Counting the grain number of the grains per spike, converting the grain weight into thousand grain weight, and calculating the grouting rate.

1.4 determination of cellulose Lignin

The milk ripeness stage of the spaghetti is measured. During the measurement, the 3 rd stem node cut by scissors is put into a 105 ℃ oven for deactivation of enzymes for 0.5h, and then is crushed at 65 ℃ for 8h, and the measurement is carried out by using cellulose and lignin.

The method for measuring cellulose and lignin comprises the following steps: the content of cellulose and lignin in the stem is measured by concentrated acid hydrolysis according to the method of Schruchuqin and the like.

1.5 determination of size and quantity of stalk vascular bundles

Taking the 3 rd internode at the base of the 'Chuanxi' bromus fasciatus as a sample, taking 5 representative disease-free and pest-free single stems in each test cell in the milk stage, cutting a section of 2-3cm in the middle of the internode, and fixing by using Carnot solution (ethanol: glacial acetic acid: 3: 1). Slices were cut by hand and transferred to petri dishes, examined by stereomicroscope, and sections of uniform thickness were picked for staining. Transferring to a glass bottle containing 1% safranin (prepared with distilled water, aging for more than 3 months), transferring to a culture dish containing distilled water after 1min, washing off the safranin, and transferring to a glass slide to obtain a temporary slide. The photographs were taken under an Olympus UTV0.5 × C3 microscope. Counting the number of large vascular bundles (inner ring vascular bundles), the number of small vascular bundles (outer ring vascular bundles) and the number of mechanical tissue layers. Vascular bundle size and mechanical tissue thickness were measured using Motic Images Advanced 3.2 Picture analysis software. The cross-sectional area of the vascular bundle is calculated according to an elliptical area formula S ═ pi ab/4 (a and b are the maximum diameters in the vertical and horizontal 2 directions).

1.6 root to crown ratio

In the milk stage measurement of the brome at the east of Chuanxi province, 3 line segments of 0.1m are randomly dug in each experimental plot, the stem and the root are separated, impurities on the root are wiped and cleaned, and data are measured.

Calculating the formula: root-crown ratio (root fresh weight/overground fresh weight)

1.7 Effect of the storage of the assimilates in the Pre-anthesis and the assimilation after the flower on the various vegetative organs

In the initial flowering period, each test cell selects spike brands which bloom on the same day for marking, 10 marked individual main stems are taken from each cell at 0, 7, 14, 21, 28 and 35DAA (Days after flowering), and the dry weight is weighed according to the three parts of spikes, leaves and stems.

A calculation formula of the dry matter accumulation and transport parameters of the nutritive organs is as follows:

transport amount of pre-anthesis nutritive organ storage assimilate (dry weight of nutritive organ in anthesis stage-dry weight of nutritive organ in maturation stage)

The operating rate of the pre-anthesis vegetative organ storage assimilate (flowering phase dry weight-mature phase dry weight)/flowering phase dry weight

The grain quantity of the stored assimilate of the postanthec nutritive organ is equal to the good grain dry weight in the mature period and the transport quantity of the assimilate stored in the pre-anthec nutritive organ busy

The contribution rate (%) of the nutritional organ storage isomorphism to the yield of the seeds is equal to the transport amount of the pre-flowering storage isomorphism (or the transport amount of the post-flowering dry matter)/the dry weight of the seeds in the mature period is multiplied by 100 percent

1.8 lodging Classification and determination of lodging Rate

Recording different lodging treatment periods before harvest of 'Chuanxi' brome, grading lodging conditions 3d before harvest of seeds, and classifying lodging degrees into 0-5 grades according to the included angle degrees of main stems and the ground by the method of Qiao Chun Gui and the like, wherein the 0 grade is 75-90 degrees, the 1 grade is 60-75 degrees, the 2 grade is 45-60 degrees, the 3 grade is 30-45 degrees, the 4 grade is 15-30 degrees, and the 5 grade is 0-15 degrees

1.9 seed yield

When the maturity of the seeds is 70% -80%, removing the sampling rows, harvesting each test cell twice according to different maturity of the seeds, and finally converting the yield into hectare yield.

1.10 determination of seed Germination Rate and Germination potential

After the seeds in each test plot were harvested, 100 random seeds were subjected to standard germination tests for 14 days, and germination was scored as when the length of the embryo reached 1/2 days or when the length of the radicle reached the length of the seed. And counting the germination vigor on the 7 th day and the germination rate on the 14 th day. On day 14, 20 seedlings were randomly selected from each replicate and their germ length, radicle length, determined.

Germination rate: the percentage of the number of normal germination seeds in the final germination period to the total number of test seeds is referred to.

Namely, the germination rate GR is (N0/N). times.100%. Wherein N0 is the total number of germinated seeds in the final germination period; n is the number of test seeds.

1.11 determination of soluble sugar and starch content

After the seeds are harvested, 100 seeds in each cell are randomly selected, and the measuring method refers to Yuanhua 'plant physiological and biochemical experiment'.

1.12 evaluation of production economics

And evaluating the production economic benefit generated by the yield increasing part of the seeds of the brome spades in the west China after the seeds are harvested, thereby evaluating the economic benefit generated by spraying silicon fertilizer to the yield increasing part.

2. Data analysis processing

Data organization was performed using Microsoft Excel 2010 and plotting was performed using GraphPad Prism 5. One-way AVOVA is used in SPSS 26.0 to carry out variance analysis on the plant height, the 2 nd and 3 rd internodes length and the outer diameter of the Aleurites communis treated by the silicon fertilizer in the spraying period with different concentrations, the stalk folding resistance, the lodging resistance index, the stalk fullness and the cellulose content. Multiple comparisons were made with the Duncan method when F values reached significant levels. And (4) after the measured morphological indexes, physical characteristics and chemical components are arranged, correlation analysis, grey correlation degree analysis, membership function comprehensive analysis and the like are carried out on the sorted measured morphological indexes, physical characteristics and chemical components and the seed yield.

3. Results

TABLE 5 Effect of different concentrations of lodging resistant solutions on agronomic performance

As can be seen from table 5, the plant heights of the 'chuanxi' brome plants are all significantly lower than those of the CK treatment by spraying different plant growth regulators at the jointing stage, wherein the effects are best under the TS2 and TS3 treatments, and are significantly reduced by 12.79% and 13.41% (P < 0.05) respectively compared with the CK treatment, and although the treatment effects of other types of plant growth regulators are significantly different from those of the CK treatment, the treatment effects are lower than those of trinexapac-ethyl + silicon fertilizer. The length of the lower ear of bromus fasciatus in Chuanxi' is shortened along with the increase of the concentration of the plant growth regulator under different treatments, the effect is best under the treatments of TS2 and TS3, and the lengths are respectively and obviously reduced by 16.3 percent and 19.86 percent compared with the CK treatment (P is less than 0.05); the CNa3 treatment effect is the best in the compound fertilizer treatment of the paclobutrazol and the silicon fertilizer, and is obviously reduced by 18.82 percent (P is less than 0.05) compared with the control treatment; although the length of the nodes under the spikes in the single application of trinexapac-ethyl treatment is obviously lower than that of the control treatment, the treatment effect is lower than that of the compound treatment. The sub-panicle node thickness increased with the increase of the concentration of the plant growth regulator, wherein the stem thickness was significantly higher when the concentration was the highest in the treatments of trinexapac-ethyl + silicon fertilizer, paclobutrazol + silicon fertilizer and single spray silicon fertilizer than in the CK treatment. The lodging rate is reduced along with the increase of the spraying concentration, wherein the performance effect of TS3 under the treatment of the trinexapac-ethyl and silicon fertilizer compound fertilizer is optimal, and is remarkably reduced by 19.05 percent compared with the control treatment, and is lower than that of each treatment.

When different types of plant growth regulators are sprayed in the booting stage, the plant height of the TS5 and the TS6 in the trinexapac-ethyl and silicon fertilizer compound fertilizer is lower than that of other plant growth regulators, and is obviously reduced by 10.35 percent and 11.45 percent (P is less than 0.05) compared with that of the control treatment, the plant height is reduced along with the increase of the spraying concentration of other types of plant growth regulators, but the reduction effect is lower than that of the trinexapac-ethyl and silicon fertilizer compound plant growth regulators. The expression effect of the spike length is consistent with that of the plant height, the spike length expression effect and the plant height expression effect are both shortened along with the increase of the concentration of the sprayed matter, and the treatment effect under high concentration is obviously higher than that of CK treatment. The length of the nodes under the spikes is reduced along with the increase of the concentration of the sprayed substances, and the treatment effect of the plant growth regulators with different concentrations is obviously higher than that of CK treatment, wherein the treatment effect of TS5 and TS6 in the treatment of the trinexapac-ethyl and silicon fertilizer compounded plant growth regulators is the best, and is obviously reduced by 10.35 percent and 11.45 percent (P is less than 0.05) compared with the CK treatment. The lodging rate is obviously lower than that of the control treatment under the treatment of the trinexapac-ethyl and the silicon fertilizer and the treatment of the paclobutrazol and silicon fertilizer compounded plant growth regulator. The effect of the treatment of the trinexapac-ethyl and silicon fertilizer compound plant growth regulator is better than that of the treatment of the paclobutrazol and silicon fertilizer compound plant growth regulator.

The treatment effect of spraying twice in the jointing stage and the booting stage is superior to that of single spraying in the jointing stage and the booting stage, and the treatment effect of each plant growth regulator is superior to that of CK treatment. The plant height is remarkably reduced by 19.96 percent (P is less than 0.05) compared with the control treatment under the treatment of TS9 in the treatment of the trinexapac-ethyl and silicon fertilizer compound; the length of the ear node is shortest under the TS8 treatment, and is reduced by 41 percent compared with the control treatment (P is less than 0.05); lower than each treatment of the different sprays. The under-ear knot coarseness increased significantly by 21.93% (P < 0.05) under the TS9 treatment compared to the control treatment, and increased with increasing concentrations of different sprays. Wherein the spraying effect of the trinexapac-ethyl and the silicon fertilizer compound is the best, and the spraying effect of the trinexapac-ethyl and the silicon fertilizer compound is the second one. The chlorophyll content showed a tendency to increase with increasing spray concentration, and the chlorophyll content of the plant leaves was significantly higher under different spray treatments than the CK treatment. Spray levels of different concentrations have different effects on the lodging rate of 'chuanxi' bromus platyphylla plants. The lodging rate of the TS9 treatment is lowest under the treatment of the trinexapac-ethyl and silicon fertilizer compound, and is remarkably reduced by 65.56 percent (P is less than 0.05) compared with the control treatment. The plant height shows a trend of reducing the lodging rate with the increase of spraying concentration under the treatment of other spraying materials. The treatment effect is as follows: the trinexapac-ethyl and the silicon fertilizer compound is more than the paclobutrazol and the silicon fertilizer compound is more than the trinexapac-ethyl single application is more than the silicon fertilizer single application.

TABLE 6 Effect of different concentrations of lodging resistant solutions on seed yield

As can be seen from table 6, the seed setting rate of the 'chuanxi' brome can be improved to different degrees by spraying the prepared substances with different concentrations in the jointing stage, and the effect when the compound spraying substance of trinexapac-ethyl and silicon fertilizer is sprayed is better than that of the paclobutrazol-silicon fertilizer, the trinexapac-ethyl by single application and the silicon fertilizer by single application. The setting rate under the TS1, TS2 and TS3 treatments were significantly improved by 3.03%, 5.27% and 8.54%, respectively, compared with the control treatment (P < 0.05). The dry weight of the spike shows a trend of increasing with the increase of the concentration of the sprayed substance, the dry weight of the spike is higher when the trinexapac-ethyl and silicon fertilizer compound sprayed substance is sprayed than other compound sprayed substance treatments, and the dry weight of the spike is remarkably increased by 7.75 percent (P is less than 0.05) compared with the control treatment under the TS3 treatment. The seed yield shows a trend of increasing first and then decreasing with increasing concentrations of different types of compound applications. Under the treatment of a compound spray of trinexapac-ethyl and a silicon fertilizer, the treatment of TS1, TS2 and TS3 are respectively and obviously increased by 3.69%, 8.08% and 6.47% (P is less than 0.05) compared with the control treatment; the treatment of CNa1, CNa2 and CNa3 under the treatment of the compound spray of paclobutrazol and silicon fertilizer is respectively increased by 2.59 percent, 6.41 percent and 4.73 percent compared with the treatment of CK; the CNb2 and CNb3 treatments increased 5.37% and 3.59% respectively under the single treatment of trinexapac-ethyl compared to the CK treatment; the CNc2 and CNc3 treatments increased by 4.5% and 2.73% respectively under the single silicon fertilizer application treatment compared with the CK treatment. The economic benefit when spraying the trinexapac-ethyl and silicon fertilizer compound spraying material is obviously higher than CK treatment and also obviously higher than the treatment of the compound spraying material of the comparative examples 1-3.

The setting rate of the compound spraying substance sprayed with trinexapac-ethyl and silicon fertilizer in the booting stage is higher than that of the compound spraying substance sprayed with other three types, and the setting rate of the compound spraying substance treated with TS4 is obviously improved by 5.72 percent (P is less than 0.05) compared with that of CK treatment. The dry weight of the spike is significantly higher than that of the control treatment at the highest concentration under the conditions of spraying the compound spray of paclobutrazol and silicon fertilizer and the treatment of trinexapac-ethyl. Seed yield and economic income increase with increasing concentrations of different types of formulated sprays. When the trinexapac-ethyl and silicon fertilizer compound spray is sprayed, the seed yield and the economic benefit of the TS5 and the TS6 are respectively and obviously increased by 6.41 percent and 5.1 percent (P is less than 0.05) compared with the CK treatment. When the compound spray of paclobutrazol and silicon fertilizer is sprayed, the seed yield and economic benefit of the CNa4, CNa5 and CNa6 treatment are respectively and obviously increased by 2.26%, 4.2% and 3.57% compared with CK treatment (P is less than 0.05). The seed yield and economic benefit of CNb5 and CNb6 treatment were both significantly increased by 3.6% and 2.63% when trinexapac-ethyl was sprayed (P < 0.05), respectively, compared to CK treatment. The seed yield and economic benefit of CNc5 and CNc6 treatment are respectively increased by 3.03% and 1.87% (P is less than 0.05) when the silicon fertilizer is sprayed.

The setting rate of the compound spraying agent of trinexapac-ethyl and silicon fertilizer sprayed in the jointing stage and the booting stage under each concentration treatment is obviously higher than that of CK treatment, and the setting rate is higher than that of other types of compound spraying agents. When the dry weight of the spike is sprayed with a compound spray of trinexapac-ethyl and a silicon fertilizer, TS7 and TS8 are obviously increased by 21 percent and 19.17 percent (P is less than 0.05) compared with CK treatment; when the compound spray of paclobutrazol and silicon fertilizer is sprayed, the CNa7 treatment is obviously increased by 13.75 percent compared with CK treatment (P is less than 0.05); when the trinexapac-ethyl is sprayed, the CNb7 and CNb8 are obviously increased by 10.25 percent and 4.08 percent (P is less than 0.05) compared with CK treatment; the CNc7 treatment increased significantly by 9.25% (P < 0.05) when the silicon fertilizer was sprayed.

When the trinexapac-ethyl and silicon fertilizer compound spray is sprayed, the seed yield and the economic benefit of the treatment of TS7, TS8 and TS9 are respectively and obviously increased by 10.7 percent, 8.68 percent and 5.04 percent (P is less than 0.05) compared with the treatment of CK. When the compound spray of paclobutrazol and silicon fertilizer is sprayed, the seed yield and economic benefit of the CNa7, CNa8 and CNa9 treatment are respectively and obviously increased by 7.96%, 7.1% and 3.78% (P is less than 0.05) compared with CK treatment. The seed yield and economic benefit of CNb7, CNb8 and CNb9 treatments were all significantly increased by 9.1%, 6.25% and 2.82% respectively (P < 0.05) when trinexapac-ethyl was sprayed. The seed yield and economic benefit of CNc7, CNc8 and CNc9 treatment are respectively and obviously increased by 8.53%, 4.62% and 2.03% (P is less than 0.05) compared with CK treatment when silicon fertilizer is sprayed.

As can be seen from Table 6, the invention can promote the yield increase of the brome per hectare by up to 10.7 percent, and the economic benefit increase per hectare by up to 8680.63 yuan, which is obviously better than that of the comparative examples 1-3.

The above-described embodiments are merely illustrative of the preferred embodiments of the present invention, and do not limit the scope of the present invention, and various modifications and improvements of the technical solutions of the present invention can be made by those skilled in the art without departing from the spirit of the present invention, and the technical solutions of the present invention are within the scope of the present invention defined by the claims.

Claims (8)

1. A cultivation method for improving lodging-resistant capability and seed yield of bromus fasciatus is characterized by comprising the step of spraying a lodging-resistant solution at the jointing stage and/or the booting stage of the bromus fasciatus.

2. The cultivation method according to claim 1, wherein the lodging resistant solution includes an trinexapac-ethyl solution and a silicon fertilizer solution.

3. The cultivation method as claimed in claim 2, wherein the concentration of the trinexapac-ethyl solution is 150-450g/hm²The concentration of the silicon fertilizer solution is 467-doped 1867g/hm²。

4. The cultivation method according to claim 1, wherein the spraying amount of the lodging resistant solution is 700mL/15m²。

5. The cultivation method as claimed in claim 1, comprising the steps of:

(1) preparing land, namely selecting land blocks which are flat in terrain, medium and uniform in soil fertility, consistent in previous crops, free of weeds, free of soil-borne diseases, good in irrigation and drainage conditions and free of buildings or trees around, applying fertilizers to the selected land blocks, then carrying out plowing treatment, and irrigating water on the soil moisture of soles after plowing;

(2) seed treatment: after each kg of seeds are dressed with 3g of seed dressing agent, airing for 1-2 days, wherein the seed dressing agent is a mixture of thiram and carboxin, and the active ingredient contents of the thiram and the carboxin are both 200 g/L;

(3) sowing: selecting ten days of 10 months to 11 months, wherein the temperature is 20 to 25 ℃, and drilling the treated seeds with the seeding rate of 24kg/hm²The row spacing is 40cm, the sowing depth is 2-3cm, and the soil is attached to 1-2cm after sowing;

(4) field management: seedling searching, weed removing, irrigation, lodging-resistant management and topdressing;

(5) harvesting: and (4) harvesting when the moisture of the brome fasciata seeds is reduced to below 16% in the middle and later mature period.

6. The cultivation method as claimed in claim 5, wherein the fertilizer in step (1) is farmyard manure and is applied in an amount of 15000-²The plowing treatment comprises applying while plowingAdding 150kg/hm of urea²Diammonium 70kg/hm²100kg/hm of potassium chloride²And phoxim 4kg/667m²。

7. The cultivation method according to claim 5, wherein the irrigation in the step (4) is specifically: 1) proper watering is carried out when drought occurs in the seedling emergence period, so as to ensure seedling emergence; 2) irrigating by sprinkling irrigation in the water shortage period of the green turning period until the soil is not loosened by holding with hands; 3) adopting a spray irrigation mode when water is deficient in the tillering stage, wherein the irrigation depth is 5-6 cm; 4) during the jointing stage drought, the method is carried out in a spray irrigation or flood irrigation mode, and the irrigation depth is more than 10 cm; 5) irrigating by sprinkling irrigation when water is deficient in the booting stage until the soil is not loosened by holding with hands; 6) and in the mature period, if strong rainfall weather occurs, paying attention to timely drainage.

8. The cultivation method according to claim 5, wherein the additional fertilizer of the step (4) is specifically: 1) and (3) tillering fertilizer: after 50% of plants enter the tillering stage, applying 50kg/hm of urea²(ii) a 2) Ear fertilization: after 50% of plants enter the heading stage, 70kg/hm of urea is applied²。