JP2013532173A - Rooting agent for tray raising seedling for mechanical transplantation of paddy rice and method of use thereof - Google Patents

Abstract

Rooting agent for tray raising seedling for mechanical transplantation of paddy rice and method of use thereof. This rooting agent contains a plant growth regulator of auxins and dichloroisocyanuric acid, and the concentration of the plant growth regulator of auxins is 1 to 10 ppm and the concentration of sodium dichloroisocyanurate is 50 to 200 ppm. This rooting agent significantly promotes revegetation and growth of mechanically transplanted seedlings, accelerates the occurrence of tillers, significantly increases effective ears, and significantly increases rice production. This rooting agent employs two methods of use, i.e. immersion seeding and spraying, and is easy to use and convenient to work.
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Description

  The present invention belongs to the technical field of rooting agents for young seedlings of crops, and specifically relates to a rooting agent for tray raising seedlings for mechanical transplantation of paddy rice and a method for using the same.

  For transplanting by paddy rice machine, seedlings are raised using plastic trays. The specifications of a regular plastic tray are 58 cm long, 28 cm wide, and 2 cm high. Ordinary hybrid rice is sown with 80 to 100 g of sprout per tray, and normal rice is sown with 120 to 150 g. The root system of paddy rice grows in a state of being wound around the bottom of the seedling tray, and many roots are entangled with each other to form a white root carpet at the bottom of the seedling tray. These roots are entangled in the soil of a seedling tray with a thickness of only 2 to 2.5 cm, the rhizosphere is very crowded and the number of root hairs decreases, so Quality deteriorates. When mechanically transplanted, the root system is pulled and cut and damaged, and the survival and revegetation after mechanical transplantation of seedlings are delayed, rooting and tilling are delayed, and for rice production and quality, In particular, it has a great influence on the Tohoku region in Tohoku and the Wased region in the south.

  The damage to the root system of mechanically transplanted seedlings is mainly improved by the following method. 1) The use of various fertilization methods and root growth promoters in the production is expected to promote the growth of the rice root system and reduce the damage to the roots caused by mechanical transplantation. Many root systems in the tray, on the contrary, cause even greater damage to the seedlings during mechanical transplantation. 2) Some rice farmers cut off the excess root system at the bottom of the seedling tray before mechanical transplanting, so that the sampler pulls many root systems at the bottom during mechanical transplanting. Although reducing damage, this method can only be applied to small farms and is labor intensive and time consuming. 3) Remodeling of the seedling tray is another method, for example, a pot-shaped carpet-shaped seedling tray is modified by rearranging the seedling tray structure of the pot-shaped carpet-shaped seedling tray, and the top is a carpet and the bottom is a pot-raising method. As well as improving the technology of mechanical transplantation, seedlings can be sown more precisely, and there is a certain effect especially on the cultivation and breeding of mechanical transplanted seedlings of hybrid rice. However, pot-shaped carpet-shaped trays increase the cost of raising seedling trays, and pot-shaped carpet-shaped seedlings have high technical requirements for mechanical transplantation.For example, if a sampler cannot accurately take a nursery pot, It is difficult to spread this technology over a large area in Japan, especially in the southern rice region.

  In order to solve the above-mentioned problems of the prior art, the object of the present invention is to provide a technical proposal of a method for using a rooting agent for tray raising seedlings for mechanical transplantation of paddy rice containing a plant growth regulator of auxins and sodium dichloroisocyanurate. However, it is intended to remarkably promote the revegetation and growth of mechanically transplanted seedlings, to accelerate the occurrence of tillers, to significantly increase the effective ears, and finally to significantly increase the production of paddy rice.

  The rooting agent for tray raising seedlings for mechanical transplantation of paddy rice contains a plant growth regulator of auxins and dichloroisocyanuric acid, the concentration of the plant growth regulator of auxins is 1 to 10 ppm, and sodium dichloroisocyanurate The density | concentration of is characterized by being 50-200 ppm.

  The above-mentioned rooting agent for tray raising seedlings for mechanical transplantation of paddy rice is such that the plant growth regulator of auxins is naphthalene acetic acid, sodium naphthalene acetate, indolepropionic acid, indolebutyric acid, naphthyloxyacetic acid, or 4-iodophenylacetic acid Or a mixture of one or more of these.

  The rooting agent for tray raising seedlings for mechanical transplantation of paddy rice is characterized in that the concentration of the plant growth regulator of the auxins is 2 to 8 ppm, preferably 4 to 6 ppm.

  The rooting agent for tray raising seedlings for mechanical transplantation of paddy rice is characterized in that the concentration of sodium dichloroisocyanurate is 100 to 180 ppm, preferably 120 to 170 ppm.

  The method of using the rooting agent for tray raising seedling of the above-mentioned mechanical transplanting of paddy rice is such that the concentration of the plant growth regulator of auxins used in indica rice is 1 to 3 ppm when soaking using a rooting agent. Yes, the concentration of plant growth regulator of auxin used for japonica rice is 2-5ppm, the concentration of sodium dichloroisocyanurate is 50-200ppm, so that the solution soaks into the seed, soaking time is indica It is 40 to 50 hours for rice, and 70 to 80 hours for japonica rice, and is characterized by sprouting and seeding in a normal manner without washing after completion of soaking.

  The method of using the rooting agent for tray raising seedlings in the mechanical transplantation of paddy rice described above is that the concentration of the plant growth regulator of auxins used for indica rice is 1.5-2 ppm, and the plant growth of auxins used for japonica rice The concentration of the modifier is 3 to 4 ppm, the concentration of sodium dichloroisocyanurate is 100 to 180 ppm, preferably 150 to 170 ppm, and the soaking time is 42 to 45 hours for Indica rice, and 72 to 45 for Japonica rice. 75 hours.

  The method of using the rooting agent for tray raising seedlings for mechanical transplantation of the rice plant described above is that when the rooting agent is sprayed, the concentration of the plant growth regulator of auxins used in indica rice is 4 to 8 ppm. Yes, the concentration of plant growth regulator of auxin used for japonica rice is 5-10 ppm, the concentration of sodium dichloroisocyanurate is 50-200 ppm, sowing before spraying after seeding on seedling tray The amount of the solution sprayed to each standard mechanical transplantation tray is 10 to 20 ml until one leaf and one core of the seedling grow.

  The method of using the rooting agent for tray raising seedling of the above-mentioned mechanical transplanting of paddy rice is such that the concentration of plant growth regulator of auxins used for indica rice is 5-6 ppm, and plant growth regulator of auxins used for japonica rice The concentration of is 9 to 9 ppm, and the concentration of sodium dichloroisocyanurate is 100 to 180 ppm, preferably 150 to 170 ppm.

  Sodium naphthalene acetate (1-Naphthylacetic Acid, NAA-Na) is a substance of auxins and a broad and effective plant growth regulator. Sodium naphthalene acetate can be replaced with plant growth regulators of auxins such as naphthalene acetic acid, sodium naphthalene acetate, indolepropionic acid, indolebutyric acid, naphthyloxyacetic acid, 4-iodophenylacetic acid. Sodium naphthalene acetate has the effective properties and bioactivity of the endogenous auxin indole acetic acid, for example, promotes cell division and expansion, induces the formation of adventitious roots, increases fruit set, prevents fruit loss, Change the ratio of male and female pupae. Within the concentration range of 0.001 to 0.01 ppm, it promotes the growth of rice roots and is advantageous for the development of adventitious roots. However, when it exceeds 10 mg / L, the growth of roots is remarkably suppressed. If it is within the range of 10 ppm, there is little influence on the growth of rice buds. Many applications of sodium naphthalene acetate apply crop root systems at low concentrations and physiological effects that promote seedling growth. Crop root systems at high sodium naphthalene acetate concentrations (1-2 ppm) There are few studies on regulatory control of Up to now, using high concentration of sodium naphthalene acetate, the root system of the tray raising seedlings to which the rice is mechanically transplanted is regulated and controlled to reduce damage to the root system of the mechanically transplanted seedlings, or to re-greening and dividing. There has been no report on applications to be accelerated.

  Sodium dichloroisocyanurate is a high-efficiency, wide-ranging and effective in-house absorptive fungicide, has a strong biocidal effect, and slowly releases hypochlorous acid when seeding paddy rice. Changes the permeability of the membrane, inhibits the physiology and vitalization of the enzyme system, affects processes such as DNA synthesis, and immediately kills pathogenic bacteria. If it is 50 ppm or more, the bactericidal rate exceeds 90%, and various bacteria, algae, fungi, and pathogens can be killed. Sodium dichloroisocyanurate is stable in chemical properties, and when stored under dry conditions, the fall rate of effective chlorine for half a year is 1% or less, so it is convenient for storage and transportation, and can be used safely and conveniently. The amount used is small and the retention time of medicinal properties is long.

  The above-mentioned rooting agent for tray raising seedlings for mechanical transplantation of paddy rice utilizes the physiological characteristics of sodium naphthalene acetate that suppresses the growth of root system of paddy rice at high concentration and promotes root growth at low concentration. In the nursery tray, a high concentration sodium naphthalene acetate environment was created in the nursery tray to combine the seedling root system and seedling growth in the nursery tray. By controlling the growth and spread of the above-ground part, the damage of the root system of the seedling and the above-ground part of the seedling when transplanted mechanically is reduced, and after transplanting, the concentration of sodium naphthalene acetate around the root system of the seedling decreases and the root system Promote growth and growth of seedlings above ground. The use of sodium dichloroisocyanurate as a fungicide not only effectively prevents various diseases in trays grown by mechanical transplantation, but at the same time promotes the development of white roots in seedlings and restores the root system after mechanical transplantation. Is advantageous to growth, promotes the survival and revegetation of the whole seedling. The sodium naphthalene acetate used is very easy to dissolve in water and the preparation of the solution is convenient and fast. The sodium naphthalene acetate and sodium dichloroisocyanurate used are convenient reagents, and are therefore readily available and inexpensive. This rooting agent is applied to mechanically transplanted paddy rice, which significantly promotes replanting and growth of mechanically transplanted seedlings, accelerates the occurrence of tillers, significantly increases effective ears, and significantly increases paddy rice production. Can be increased. This rooting agent employs two methods of use, i.e. immersion seeding and spraying, and is easy to use and convenient to work.

  Percentages stated herein represent weight percentages unless otherwise specified.

Hereinafter, the present invention will be described in more detail with specific examples.
Formulation 1: Sodium naphthalene acetate 1 ppm, Sodium dichloroisocyanurate concentration 50 ppm
Formulation 2: Naphthalene sodium acetate 2 ppm, sodium dichloroisocyanurate concentration 200 ppm
Formulation 3: Sodium naphthalene acetate 5 ppm, Sodium dichloroisocyanurate concentration 150 ppm
Formulation 4: Sodium naphthalene acetate 8 ppm, Sodium dichloroisocyanurate concentration 200 ppm
Formula 5: Sodium naphthalene acetate 10 ppm, Sodium dichloroisocyanurate concentration 120 ppm

  The sodium naphthalene acetate can be replaced with one of naphthalene acetic acid, sodium naphthalene acetate, indolepropionic acid, indolebutyric acid, naphthyloxyacetic acid, 4-iodophenylacetic acid, or a mixture thereof.

  The above-mentioned method of using the rooting agent for tray raising seedlings for mechanical transplantation includes two methods, i.e., dip seed use and spray use.

  When soaking using rooting agent: the concentration of plant growth regulator of auxins used for indica rice is 2 ppm, the concentration of plant growth regulator of auxins used for japonica rice is 3 ppm, dichloroisocyanuric acid The concentration of sodium is 200 ppm. The solution is soaked in the seed, soaking time is 42 hours for indica rice and 72 hours for japonica rice, and after soaking, it is directly washed at 35 ° C. without washing. Moisturize and germinate in the environment, and thereafter germinate and sow in the usual way. The concentration of the plant growth regulator of auxins used in this method of use is 1 ppm and 3 ppm. The concentrations of plant growth regulators of auxins used for Japonica rice are 2 ppm, 4 ppm, and 5 ppm, and the concentrations of sodium dichloroisocyanurate are 50 ppm, 100 ppm, 150 ppm, and 180 ppm. The soaking time is 40 hours, 45 hours and 50 hours in the case of Indica rice, and 70 hours, 75 hours and 80 hours in the case of Japonica rice. The beneficial effect is obtained.

  When spraying a rooting agent: the concentration of plant growth regulator of auxins used for indica rice is 5 ppm, the plant growth regulator of auxins used for japonica rice is 8 ppm, and sodium dichloroisocyanurate The concentration is 200 ppm, and the spraying time is from before depositing after seeding on the seedling tray until from one seed to one core growing after seeding, the amount of solution sprayed to each standard mechanical transplant tray is 15 ml is there. The concentration of plant growth regulator for auxins used in this method of use is 4 ppm, 6 ppm, 7 ppm, 8 ppm, and the concentration of plant growth regulator for auxins used in japonica rice is 5 ppm, 6 ppm, 7 ppm, 9 ppm, 10 ppm. The concentration of sodium dichloroisocyanurate is 50 ppm, 100 ppm, 150 ppm, 180 ppm, and the amount used is 10 ml, 12 ml, 18 ml, 20 ml. Other methods are the same as described above, and an equivalent beneficial effect is obtained.

  The management of other liquid fertilizers and pest damage in tray raising seedlings is the same as the local traditional method.

  In order to explain the beneficial effects of the present invention in more detail, the following corresponding experiment will be described.

  Agricultural land treatment method: When adopting the soaking method, the rooting agent is soaked in the usual way, and after soaking, the seed is not washed. In the case of adopting the method by spraying, the raising and irrigation of the seedling tray is carried out by the tray raising method of normal mechanical transplantation. The experiment was conducted in 2009 and 2010 at the standard test field of the experimental farm (Zhejiang Fuyang, Emperor Paddy Field) of the China Rice Research Institute. The application effect of tray seedling of early-ripening indica rice and mechanical transplantation of late-ripening indica rice with a single crop is tested, and the experiment adopts the comparison method of Oku, and the area of Oku is 15m x 20m. Investigate the disease of the seedlings before transplanting, investigate the nature of the seedlings by sampling, investigate the status of replanting and revegetation after transplanting, and conduct seed tests and yield tests at the time of rice harvest. As a result of experiments, the rooting agent can accelerate the time for survival and revegetation of mechanical transplanted seedlings to 2 to 3 days after transplanting, improve the production of sticky rice by 10 to 20%, and the application effect is remarkable. It was.

  Table 1 shows the properties of tray seedlings that have been soaked or sprayed with rooting agents. Expression of experimental results: The root length and root system dry weight of the seedlings treated with the rooting agent are much smaller than the control seedlings, with an average reduction of 50% or more. Changes in leaf age and stem width are less noticeable. Changes in leaf area and dry weight of above-ground parts are conspicuous. When comprehensively analyzed, soaking or spraying with a rooting agent can remarkably control the growth of the root system of tray-grown seedlings and does not affect the growth and development of the seedlings. When observing the experimental seedling tray, the winding of the root system at the bottom of the seedling tray treated with the rooting agent was significantly reduced, but it did not affect the raising of the seedling. Even if the same experiment is performed in Example 1, Example 3, and Example 5, the above-described beneficial effect can be obtained.

  Expression of experimental results: Treatment with rooting agents can significantly reduce the occurrence of diseases in tray seedlings. As can be seen from the comparison of data, soaking and spraying treatments with rooting agents are effective in preventing disease of tray seedlings. Is almost the same. Even if the same experiment is performed in Example 1, Example 3, and Example 5, the above-described beneficial effect can be obtained.

  Water discharge from the core leaves after transplanting rice is the overall behavior of seedling survival, revegetation and growth, and is the most important and remarkable observation index of survival, revegetation and growth. As can be seen from Table 3, the treatment with the rooting agent can remarkably shorten the water discharge time of the core leaf, and in the Nakakahaya 32 seedling soaked at 2 ppm, the water discharge time of the core leaf after mechanical transplantation is the control. The seedlings shortened by 7.3 days from the seedlings, and the seedlings sprayed at 8 ppm are shortened by 8.9 days, and the time reduction rates are 51.4% and 62.7%. In Shusui 09, the time was reduced by 3.2 days and 3.6 days, respectively, and the time reduction rates were 46.4% and 49.3%. When observing in paddy fields, not only the core leaves but also the water discharge time of each of the other leaves is all accelerated, the seedlings are upright, the whole shows the characteristics of survival and growth, and the rooting agent is the seedling after transplanting The growth is remarkably enhanced and re-greening is accelerated. Even if the same experiment is performed in Example 1, Example 3, and Example 5, the above-described beneficial effect can be obtained.

  Table 4 shows the growth of mechanically transplanted seedlings after treatment with rooting agents. As can be seen from the table, the total number of roots per plant, the number of white roots per plant, and the number of pods per plant of the seedlings treated with rooting agents on the 12th day after transplanting are all from the control Doubled, the average leaf age and the average height of the stock increase significantly. Analysis shows that seedlings that have been soaked or sprayed with a rooting agent are significantly faster to plant, re-green, and grow after transplanting than the control seedlings, with the root system growing and the occurrence of tilling being particularly prominent after transplanting. Even if the same experiment is performed in Example 1, Example 3, and Example 5, the above-described beneficial effect can be obtained.

  Table 5 shows the actual production amount and components of production amount of Nakakahaya 32 and Shusui 09 treated with rooting agents. As can be seen in Table 4, the actual production ratio of Nakakahaya 32 treated with seeding or spraying with a rooting agent increased by 10.47% and 12.14%, respectively, compared with the control. Increased 16.92% and 12.47%. Analyzing the elements of production, rooting treatment significantly increased the number of effective spikes mainly in paddy fields, but the effect on the total number and seed set rate of each spike is not noticeable. Even if the same experiment is performed in Example 1, Example 3, and Example 5, the above-described beneficial effect can be obtained.

Claims (8)

  A rice plant machine comprising a plant growth regulator of auxins and dichloroisocyanuric acid, wherein the concentration of plant growth regulator of auxins is 1 to 10 ppm and the concentration of sodium dichloroisocyanurate is 50 to 200 ppm Rooting agent for tray raising seedlings for transplantation.   The plant growth regulator of the auxins is one of naphthalene acetic acid, sodium naphthalene acetate, indolepropionic acid, indolebutyric acid, naphthyloxyacetic acid, 4-iodophenylacetic acid, or a mixture of one or more thereof. A rooting agent for tray raising seedlings for mechanical transplantation of paddy rice according to claim 1.   The rooting agent for tray raising seedlings for mechanical transplantation of paddy rice according to claim 1, wherein the concentration of the plant growth regulator of auxins is 2 to 8 ppm, preferably 4 to 6 ppm.   The rooting agent for tray raising seedlings for mechanical transplantation of paddy rice according to claim 1, wherein the concentration of sodium dichloroisocyanurate is 100 to 180 ppm, preferably 120 to 170 ppm.   When soaking using a rooting agent, the concentration of plant growth regulator of auxins used for indica rice is 1-3 ppm, and the concentration of plant growth regulator of auxins used for japonica rice is 2-5 ppm. The concentration of sodium dichloroisocyanurate is 50-200 ppm, so that the solution soaks into the seeds, soaking time is 40-50 hours for Indica rice, 70-80 hours for Japonica rice, The method for using a rooting agent for tray raising seedlings for mechanical transplantation of paddy rice according to claim 1, wherein the seedlings are sown and sown in a usual manner without washing after completion.   The concentration of plant growth regulator of auxins used for indica rice is 1.5-2 ppm, the concentration of plant growth regulator of auxins used for japonica rice is 3-4 ppm, and the concentration of sodium dichloroisocyanurate is 100 It is -180ppm, Preferably it is 150-170ppm, The time of soaking is 42-45 hours in Indica rice, and 72-75 hours in Japonica rice, The mechanical of the paddy rice of Claim 5 characterized by the above-mentioned How to use rooting agent for transplanting seedlings for transplantation.   When spraying the rooting agent, the concentration of the plant growth regulator of auxins used for indica rice is 4-8 ppm, and the concentration of the plant growth regulator of auxins used for japonica rice is 5-10 ppm. The concentration of sodium dichloroisocyanurate is 50 to 200 ppm, and the spraying period is from before depositing seedlings on seedling raising trays until seeds and one core of seedlings grow after seeding. The method of using a rooting agent for tray raising seedlings for mechanical transplantation of paddy rice according to claim 5, wherein the amount of the solution sprayed onto the tray is 10 to 20 ml.   The concentration of plant growth regulator of auxins used for indica rice is 5-6 ppm, the concentration of plant growth regulator of auxins used for japonica rice is 7-9 ppm, and the concentration of sodium dichloroisocyanurate is 100-180 ppm. The method for using a rooting agent for tray raising seedlings for mechanical transplantation of paddy rice according to claim 7, which is preferably 150 to 170 ppm.