JP4037936B2 - Plant disease control agent and plant disease control method using ferrite suspension - Google Patents

Description

表１（ｂ）は、拮抗性細菌Ａ１１の成長速度についての比較を示したものである。この実験ではＭＹ１０寒天培地（ｐＨ＝７）にＭｎフェライトを１％添加したプレートを作成し、これに拮抗性細菌Ａ１１をエーゼで塗布し、９℃で２４時間培養後、目視によってその成育状態を「−，＋，＋＋」の３段階で評価した。なお、この実験はそれぞれ２回ずつ反復して行った。
【００２３】
この表に示してあるように、土壌中にＭｎフェライトを散布すると、黒色小粒菌核病原菌の一日当りの菌糸の伸長速度（ｍｍ／ｄａｙ）が、培地のみの場合では１．６２であるのに対して、Ｍｎフェライトを添加すると１．０３となり、約６３％も伸長速度を抑制することがわかる。この抑制効果は、前述したように電磁界の作用によるもので、この効果により病原菌による植物の腐食等を減少させるということができる。
【００２４】
表１（ｃ）は、Ｍｎフェライトと病原菌を抑える枯抗菌微生物を混ぜ、拮抗菌から産出される拮抗性物質を増やす効果について検討した結果を示してある。
【００２５】
この実験では、予めＭＹ１０寒天培地にて雪腐病菌を培養し、伸長した菌糸の先端部をコルクボーラー（内径７mm）で打ち抜き、ＭＹ１０寒天培地（ｐＨ＝７）にＭｎフェライトを１％添加したプレートの中央部に静置し、９℃で１７日間培養し、菌叢直径を測定することにより１日当りの菌糸伸長速度を計算した。
【００２６】
これについてはほとんどみられるべき効果が表れなかったので、黒色小粒菌核病原菌による雪腐病防除に対しては、むしろ室内実験からＭｎフェライト単独の散布のみで十分に効果が得られることを知ることができる。
【００２７】
この結果を現場試験で検討するために、ゴルフ場での現場試験を実施し、このゴルフ場における雪腐病対策について検討した。表２に、目的、場所、供給資材、散布量、散布日、調査日とその結果を示す。
【００２８】
【表２】

上記した目的から知ることができるように本発明は、いかにして農薬の使用量を減らすことができるか、また公害がない（人畜無害）資材による雪腐病防除ができるかがテーマである。
【００２９】
この目的にできるだけ近づけるための具体例を示したのが図５〜９に参考図として示した写真である。これらの各写真で緑色（濃い灰色）に写っている部分は芝草が生育している領域であり、この領域の大きさをＡとする。薄い灰色に写っている部分は病原菌により芝草が枯れている領域であり、この領域の大きさをＢとする。そしてこれらの各面積の測定値より全体の面積に対する芝草が枯れている面積の割合（Ｂ／（Ａ＋Ｂ））を計算して罹病率を算出した。
【００３０】
表２の結果の欄において、（１）の無処理区の結果と図５の写真のＡとＢとを参照してみると、病原菌による芝草の罹病率は９０〜９５％と大きくなっている。これはほとんどの芝草が罹病しており、病原菌による被害が大きくなってなっていることを示すものである。
【００３１】
同じく表２の結果の欄において、（２）の微生物（病原菌に拮抗性を有するもの）区の結果と図６に示す微生物区の写真のＡとＢを比較してみると、無処理区に比べて病原菌に対する抑制効果はあるが、それでも罹病率は３２〜７８％と高くなっている。
【００３２】
同じく、（３）の食品添加物（防腐効果のあるもの）区について図６に示す写真のＡとＢを比較してみると、罹病率は３４％〜４４％と微生物に比べて罹病率の範囲は狭くなっているが、抑制効果となるとほとんど変わっていない。
【００３３】
同じく、（４）のＭｎフェライト区は罹病率は２４％となっており、微生物区、食品添加物区に比べて、病原菌に対する抑制効果が良好であることを示している。なお、農薬区での罹病率は２％であった。
【００３４】
この表における供試資材（２）〜（４）はいづれも（５）の農薬区の罹病率２％には及ばないが、無処理区に比べて病害発生の抑制効果は認められた。この供試資材２〜４の中で、特にＭｎフェライトが最も抑制効果が優れていた。
【００３５】
そこで、このＭｎフェライトの抑制作用について以下の検討を行なった。Ｍｎフェライトの懸濁液を散布した土壌できゅうりと芝を生育させたとき、きゅうり及び芝の根からＭｎフェライトが水分と一緒に吸収されるかについて実験し、その結果を表３に示す。
【００３６】
【表３】

この実験では、きゅうり（四葉）の種子３０粒及び芝（ペントグラス）の種子１．０ｇ（約２００００粒）を、バーミキュライトを厚さ１０mmに敷きつめたポット（１０×２５×８cm）に播種した。これを温室内で１０日間培養し、きゅうりは双葉が展開した状態で、芝は発芽し始めた段階で各ポットにＭｎフェライト２ｇを均一に散布した区と散布しない区とを設定した。その後、温室内で２０日間成育させ、地上部をすべて採取し、８０℃で２４時間乾燥処理を行い、これを粉砕処理して硫酸により分解後、原子吸光光度計で含有鉄量を測定した。この結果からＭｎフェライトは水分と一緒に吸収されていないことがわかった。
【００３７】
図１０に示す写真は、上記した実験に用いたサンプルを示すものであり、左側に写っている２つのポットはＭｎフェライトを添加したものである。この図において、左外側のポットは芝、左内側のポットはきゅうり、右側に写っている２つのポットはＭｎフェライトが無添加のもので、右内側のポットは芝、右外側のポットはきゅうりである。
【００３８】
これらの写真を比較してみると、きゅうり及び芝の生育過程におけるＭｎフェライトの添加の有無によって生育に差が生じていることがわかる。これはＭｎフェライトが病原菌の動きを抑制する効果によるものであるといえる。この結果は、また表４及び図５〜９に示す写真の結果と対応している。
【００３９】
表３の結果は供試資材は単独であったが、他の資材と併用したときの効果について以下の検討を行った。
【００４０】
表４は、微生物、農薬（グランサー）、各種フェライトの単体及び微生物と各種フェライトの併用、農薬と各種フェライトの併用による効果について、現場（ゴルフ場）試験で検討した結果を示すものである。なお、この表における罹病度の測定は、表２で行った罹病面積率の測定と実質的に同じ要領で行ったものである。
【００４１】
【表４】

表４で○印のついた結果について調べてみると、No. ２３，２４のグランサー１ｇ／ｍ² ，０．５ｇ／ｍ² は平均の罹病率が６と３であるのに対して、No. ３２，３４のＭｎフェライト１ｇ／ｍ² ＋グランサー０．５ｇ／ｍ² とマグネタイト１ｇ／ｍ² ＋グランサー０．５ｇ／ｍ² の平均罹病率は１と０というように、農薬の使用量は０．５ｇ／ｍ² と半分であるにもかかわらず、フェライトとこれらとを併用すると、農薬１ｇ／ｍ² とした場合よりも罹病率は低下している。これはNo. ３０，３１のＭｎフェライト，マグネタイトを単独で用いたときの平均の罹病率はNo. １９及びNo. １１に比べると、No. ２３，２４の農薬と併用しているものに対して、その効果に相当の差が表われていることを示している。したがってフェライトを単体で用いるよりもNo. ３２，３４のごとく農薬と併用することにより、農薬の使用量を減少させることができるという点でフェライトの特性を生かすことができるといえる。
【００４２】
この結果から各種フェライトの懸濁液は単体で用いるよりも、農薬と併用して使用するとその効果が増加していることがわかる。したがってこれに伴って農薬の使用量を減少できることとなるが、これは環境汚染の危険性を改善できることからも重要なことである。
【００４３】
また本発明者らは本発明の実験と並行して２つの試験場において、拮抗性培養菌の培養液、ＭＹＰＧ倍地及び農薬（グランサー）及びこれにアルギン酸ナトリウムを併用した場合の罹病度とコストについての実験を行い、その結果について表５にまとめた。
【００４４】
表５は、北海道内の２つの実験場で行った各種の培養液の散布による罹病度を測定するとともに、各コストを示したものである（なお、Ｍｎフェライトの罹病度については表３，４を参照）。
【００４５】
上記したように、フェライトは微生物等と併用すると、フェライト単体よりも効果が得られるが、表５に示してあるようにコストの面で難点がある。
【００４６】
【表５】

【００４７】
【発明の効果】
本発明によれば、フェライト懸濁液からなる病害防除剤を散布することにより、土壌中に生じる磁気作用によって土壌中の病原菌の成長を抑制し、あるいは病原菌が植物中への侵入を防止するので、公害発生の源となる農薬の散布によることなく植物の病害の発生を防止可能となる。
【００４８】
また本発明の防除剤に市販の農薬を通常の使用量の半分以下を併用すれば、植物の病気発生を確実に防止できるので、農薬による土壌汚染及びこれによって生じる河川の汚染を著しく減少させることができる。
【図面の簡単な説明】
【図１】Ｍｎフェライトの磁化の状態を示す線図である。
【図２】マグネタイトの磁化の状態を示す線図である。
【図３】植物が生えている土壌中にフェライト懸濁液を散布したときのフェライト塊の分布状態を示す説明図である。
【図４】土壌中におけるフェライト塊による磁場による電流発生の機構を示すもので、（ａ）は磁場の形成状態を示す説明図，（ｂ）は磁場による電流の発生状態を示す説明図である。
【図５】病害の発生領域と発生してない領域との割合を撮影した写真を複写した参考図である。
【図６】病害の発生領域と発生してない領域との割合を撮影した写真を複写した参考図である。
【図７】病害の発生領域と発生してない領域との割合を撮影した写真を複写した参考図である。
【図８】病害の発生領域と発生してない領域との割合を撮影した写真を複写した参考図である。
【図９】病害の発生領域と発生してない領域との割合を撮影した写真を複写した参考図である。
【図１０】きゅうりと芝の育成状態の比較を撮影した写真を複写した参考図である。
【符号の説明】
１ 土壌
２ 植物
２ａ 毛根
３ フェライト
４ 磁力線
５ 病原菌
６ 電流
７ 水分[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a plant disease control agent and a plant disease control method using a ferrite suspension, which are used for preventing plants such as crops and lawns from being corroded or withered by diseases.
[0002]
[Prior art]
As is well known, crops and lawns are repeatedly harvested due to death or corrosion due to the occurrence of pests and insects, and the use function is reduced.
[0003]
Plant diseases caused by pathogenic bacteria that inhabit the soil among the diseases addressed by the present invention are generally controlled by spraying chemically produced agricultural chemicals (hereinafter referred to as “pesticides”). is the current situation. It is well known that the above-mentioned spraying of agricultural chemicals causes soil pollution and, consequently, river and marine pollution.
[0004]
In view of the current situation of soil contamination by such agricultural chemicals, so-called pollution-free agricultural chemicals have been actively developed. For example, biological control that biologically eliminates pathogenic bacteria using antagonistic microorganisms has been proposed.
[0005]
[Problems to be solved by the invention]
The above-mentioned control of diseases caused by pesticides causes the occurrence of pollution problems, and therefore the use of pesticides is not used or the amount used is desired to be suppressed. In particular, golf courses use large amounts of pesticides, and golf course turfgrass has been planted on land that has traditionally been a forest. It is in the present situation that has caused social problems due to pollution.
[0006]
In order to suppress the use of such harmful agrochemicals, the biological disease control method mentioned above has been spotlighted as a trump card for pollution prevention. However, this is still at the laboratory level and there are few successful examples in nature-friendly farms and golf courses. In addition, since this method is disadvantageous in terms of cost, there is a problem that this method is quite difficult to realize.
[0007]
Therefore, an object of the present invention is to reduce the amount of agricultural chemicals that are the source of pollution generation by using a pollution-free and low-cost ferrite suspension, and to prevent soil pollution and river pollution on the extension. This is to contribute to the improvement of the natural environment.
[0008]
[Means for Solving the Problems]
In order to achieve the above object, the present invention employs a ferrite suspension that does not cause environmental pollution as a plant disease control agent. That is, the ferrite suspension is obtained by stirring ultrafine ferrite magnetic powder having a particle size of 200 to 300 angstroms in water, and is applied to the soil to be controlled for diseases. When the dispersed ferrite suspension penetrates into the soil, it forms a magnetic field much stronger than the geomagnetism in the soil. On the other hand, the moisture around the hair root of the plant in the soil is sucked up into the plant by capillary action from the hair root, and a current is generated in the soil because the movement of water at this time cuts the magnetic field lines of the magnetic field described above. This current controls diseases by suppressing the action and growth of pathogenic bacteria that inhabit the hair roots. In addition, the ultrafine ferrite magnetic powder adheres to the soil grains in the soil, and also adheres to the plant pathogens in the soil. When pathogenic bacteria with ultra-fine ferrite magnetic powder adhere to the soil or move into plants by absorption of nutrients by plant hair roots, these pathogenic bacteria and nutrients cross the magnetic field, causing magnetic lines of force generated by electromagnetic induction. And the current flows. For this reason, the electric current which generate | occur | produces in soil by the synergistic effect of both generation | occurrence | production of the electric current by movement of a water | moisture content and nutrients, and the electric current generation by movement of a pathogenic microbe becomes strong. This current also flows to the pathogen, and is thought to suppress the action of the pathogen or prevent its growth.
[0009]
However, since ferrite suspensions do not kill pathogenic bacteria like chemically produced agricultural chemicals, it is difficult to completely control plant diseases. So is the next best, when spraying ferrite suspension by the pesticide to a 併, by pathogenic bacteria is prevented from entering into the plant, or to Annihilator pathogens that are prevented growth, We will make every effort to prevent disease.
[0010]
Even if ferrite magnetic powder flows out of the soil and flows into the river, it is scientifically stable and the amount used is extremely small, so it does not cause pollution of the river and the ocean, so it does not cause pollution problems. In addition, when using agricultural chemicals in combination, the amount of use can be remarkably small, so that the degree of river pollution can be made much less than in the past.
[0011]
DETAILED DESCRIPTION OF THE INVENTION
First, the magnetization strength of ferrite will be described. FIG. 1 shows a magnetization measurement diagram of Mn ferrite, and FIG. 2 shows a magnetization measurement diagram of magnetite. In both figures, the values of the magnetization intensity in the saturation magnetization curve (shown as 1) are 62 emu / g and 78 emu / g, respectively. When this is expressed by Gauss, which is a general value of magnetization strength, it is about 4300 Gauss and 5400 Gauss, respectively. Therefore, 1 g of each of this ultrafine Mn ferrite and ultrafine magnetite is put into 1 liter of water and stirred to make a ferrite suspension. When this is applied to 1 m ² of soil, the strength of magnetization per 1 m ² Are 0.43 Wb / m ² and 0.54 Wb / m ² , respectively.
[0012]
At this time, since the concentration of the ultrafine ferrite per 1 m ² is 0.1%, the influence of the ferrite on the soil hardly occurs. On the other hand, the value of the magnetization of the soil is usually 0.3 gauss, although there are some differences depending on the location. When this is converted into a value of 1 m ² per ^{Wb, 0.3 × 10 -4 Wb /} m 2 , and the approximately 1.2 × 10 ⁴ times towards the Mn ferrite or magnetite per 1 m ² and 1.8 × 10 The value of magnetization is ⁴ times larger.
[0013]
When Mn ferrite or magnetite having such a large magnetization value is dispersed in the soil, a large magnetic field is formed in the soil. When the pathogenic bacteria approach the plant roots and try to absorb the nutrients, an electric current flows through the pathogenic bacteria due to the action of the electromagnetic field, thereby suppressing the movement of the pathogenic bacteria and reducing the corrosion of the plant.
[0014]
Next, a control mechanism using ferrite magnetic powder will be described.
FIG. 3 schematically shows a state in which turfgrass 2 grows on the soil 1 and a lump of ultrafine ferrite (ferrite lump) 3 is scattered in the soil at a substantially constant interval.
[0015]
Soil 1 is an electrolyte, water is ionized, and contains inorganic ions such as Ca ²⁺ , K ⁺ , Mg ²⁺ , Na ⁺ , NO ₃ ⁻ , PO ₄ ³⁻ , NH ₄ ^+, etc. It is sucked up from the root 2a together with moisture 7 as a nutrient of the plant.
[0016]
Ferrite suspension is obtained by stirring ultrafine ferrite with a particle size (particle size) of 200-300 angstroms in water, but even if this suspension is sprayed, the magnetic powder in the suspension is completely dispersed. Instead, it is usually dispersed in an agglomerated state, that is, in a state where the ferrite mass 3 is formed. The particle size of the ferrite mass 3 is about 50 μm, and the interval between the ferrite masses 3 and 3 is about 200 μm.
[0017]
FIG. 4 (a) is an enlarged view of the space between the ferrite masses 3 and 3. The ferrite mass is an ultrafine particle, but since it is considered to be a magnet having N and S poles, one ferrite mass is shown. The magnetic field lines 4 are generated from the N pole 3a toward the S pole of the other ferrite mass. At this time, when the pathogen 5 moves toward the root 2a of the plant, the pathogen 5 cuts the magnetic field lines 4, and the current 6 induced by the electromagnetic induction action flows to the pathogen 5 as shown in FIG. The movement of the pathogenic bacteria toward the root 2a is suppressed. As a result, the pathogenic bacteria are prevented from entering the plant, and the rate at which turfgrass (plants) wither or corrode is reduced.
[0018]
When the plant 2 absorbs moisture, the moisture is sucked up from the hair root at a certain speed by capillary action. At this time, the moisture 7 cuts the magnetic field lines 4, so that the current 6 flows also in the water and surroundings by electromagnetic induction.
[0019]
As a result, the effect of further suppressing the movement of pathogenic bacteria is accompanied. In addition, since the ferrite is also attached to the pathogen itself, an electric current also flows in order to act to cut the magnetic lines of force between the surrounding ferrite by the movement of the pathogen. These synergistic effects suppress the movement of pathogenic bacteria and prevent plant morbidity by preventing entry into plants.
[0020]
【Example】
Examples of indoor and field tests are shown below as examples.
First, the growth investigation of snow rot fungus and anti-bacterial bacteria on the medium containing Mn ferrite and the laboratory experiment of anti-cultivation were conducted. The results are shown in Table 1.
[0021]
Table 1 (a) shows a comparison of changes in soil pH caused by Mn ferrite. In this experiment, the pH of Mn ferrite was measured using 100 ml of MY10 medium + 1 g (1 ml) of Mn ferrite. As shown in this table, there was no change in the pH value in the culture medium even when Mn ferrite was sprayed.
[0022]
[Table 1]

Table 1 (b) shows a comparison of the growth rate of the antagonistic bacterium A11. In this experiment, a plate in which 1% of Mn ferrite was added to MY10 agar medium (pH = 7) was prepared. Antagonistic bacteria A11 was applied with ase and cultured at 9 ° C. for 24 hours. Evaluation was made in three stages, “−, +, ++”. This experiment was repeated twice each.
[0023]
As shown in this table, when Mn ferrite is dispersed in the soil, the mycelial elongation rate (mm / day) of black sclerotia nuclei pathogen per day is 1.62 when only the medium is used. On the other hand, when Mn ferrite is added, it becomes 1.03, and it is understood that the elongation rate is suppressed by about 63%. This suppression effect is due to the action of the electromagnetic field as described above, and it can be said that this effect reduces the corrosion of plants by pathogenic bacteria.
[0024]
Table 1 (c) shows the result of examining the effect of increasing the amount of antagonistic substances produced by antagonistic bacteria by mixing Mn ferrite and dead antimicrobial microorganisms that suppress pathogenic bacteria.
[0025]
In this experiment, snow rot fungi were cultured in advance on a MY10 agar medium, the tip of the expanded mycelia was punched out with a cork borer (inner diameter 7 mm), and 1% Mn ferrite was added to the MY10 agar medium (pH = 7). The mycelial elongation rate per day was calculated by measuring the microflora diameter after culturing at 9 ° C. for 17 days.
[0026]
Since there was hardly any effect that should be seen in this regard, it is necessary to know from laboratory experiments that the application of Mn ferrite alone alone is sufficient for controlling snow rot caused by black microbe nuclei. Can do.
[0027]
In order to examine this result in a field test, a field test was conducted at a golf course, and snow rot measures at this golf course were examined. Table 2 shows the purpose, location, supply materials, spread rate, spread date, survey date and the results.
[0028]
[Table 2]

As can be seen from the above-described purpose, the present invention has the theme of how to reduce the amount of agricultural chemicals used and how to control snow rot with non-polluting (harmless to humans) materials.
[0029]
A specific example for making it as close as possible to this purpose is a photograph shown as a reference diagram in FIGS. In each of these photographs, the portion shown in green (dark gray) is an area where turfgrass grows, and the size of this area is A. The portion shown in light gray is a region where turfgrass is withered by pathogenic bacteria, and the size of this region is B. Then, the ratio of the area of turfgrass with respect to the total area (B / (A + B)) was calculated from the measured values of each area to calculate the morbidity.
[0030]
In the result column of Table 2, referring to the results of the untreated section (1) and A and B in the photograph of FIG. 5, the morbidity of turfgrass caused by pathogenic bacteria is as high as 90 to 95%. . This shows that most turfgrass is affected and that the damage caused by the pathogen is increasing.
[0031]
Similarly, in the result column of Table 2, when comparing the result of the microorganism (2) having the antagonism to the pathogen and the A and B in the photograph of the microorganism shown in FIG. Although it has a suppressive effect on pathogenic bacteria, the morbidity is still high at 32 to 78%.
[0032]
Similarly, when comparing A and B in the photograph shown in FIG. 6 for the food additive (with antiseptic effect) group of (3), the morbidity is 34% to 44%, compared to the microorganisms. Although the range is narrow, it has hardly changed when it comes to the suppression effect.
[0033]
Similarly, the Mn ferrite group of (4) has a morbidity of 24%, which indicates that the inhibitory effect against pathogenic bacteria is better than the microbial group and the food additive group. The morbidity rate in the agrochemical area was 2%.
[0034]
Although all of the test materials (2) to (4) in this table do not reach the morbidity rate of 2% in the agrochemical group of (5), the effect of suppressing the occurrence of disease was recognized as compared to the untreated group. Among these test materials 2 to 4, Mn ferrite was particularly excellent in suppressing effect.
[0035]
Then, the following examination was performed about the suppression effect of this Mn ferrite. Table 3 shows the results of experiments on whether Mn ferrite is absorbed together with moisture from cucumbers and turf roots when grown on cucumbers and turf roots sprayed with a suspension of Mn ferrite.
[0036]
[Table 3]

In this experiment, 30 cucumber (four leaf) seeds and 1.0 g (about 20,000) turf (pentgrass) seeds were sown in a pot (10 × 25 × 8 cm) in which vermiculite was laid down to a thickness of 10 mm. This was cultured in a greenhouse for 10 days. When the cucumbers were in a state where the foliage was unfolded, the turf was set to have a group in which 2 g of Mn ferrite was uniformly sprayed and a group in which the turf was not sprayed. Then, it was grown in a greenhouse for 20 days, all the above-ground parts were collected, dried at 80 ° C. for 24 hours, ground and decomposed with sulfuric acid, and the amount of iron contained was measured with an atomic absorption photometer. From this result, it was found that Mn ferrite was not absorbed together with moisture.
[0037]
The photograph shown in FIG. 10 shows the sample used in the above-described experiment, and the two pots shown on the left are those with Mn ferrite added. In this figure, the left outer pot is turf, the left inner pot is cucumber, the two pots on the right are non-added with Mn ferrite, the right inner pot is turf, and the right outer pot is cucumber. is there.
[0038]
When these photographs are compared, it can be seen that there is a difference in growth depending on whether or not Mn ferrite is added in the growth process of cucumber and turf. This can be said to be due to the effect that Mn ferrite suppresses the movement of pathogenic bacteria. This result also corresponds to the results of the photographs shown in Table 4 and FIGS.
[0039]
Although the test material was the result of Table 3, the following examination was performed about the effect at the time of using together with other materials.
[0040]
Table 4 shows the results of examination in the field (golf course) tests on the effects of microorganisms, agricultural chemicals (granters), various ferrites alone, combined use of microorganisms and various ferrites, and combined use of agricultural chemicals and various ferrites. The measurement of the morbidity in this table was carried out in substantially the same manner as the measurement of the morbidity rate performed in Table 2.
[0041]
[Table 4]

When examining the results marked with ○ in Table 4, the average morbidity is 6 and 3 for Nos. 23 and 24 for Gransers 1g / m ² and 0.5g / m ^2. 32,34 Mn ferrite 1g / m ² + Grancer 0.5g / m ² and Magnetite 1g / m ² + Grancer 0.5g / m ² average morbidity is 1 and 0. In spite of being 0.5 g / m ² and half, when ferrite and these are used in combination, the morbidity rate is lower than the case of using pesticide 1 g / m ² . Compared with No. 19 and No. 11, the average morbidity when using No. 30, 31 Mn ferrite and magnetite alone is compared with that of No. 23 and 24 combined with pesticides. This shows that there is a considerable difference in the effect. Therefore, it can be said that the use of the pesticide can be reduced by using the pesticide in combination with the pesticide as in Nos. 32 and 34 rather than using the ferrite alone.
[0042]
From this result, it can be seen that the effect of the suspension of various ferrites is increased when used in combination with agricultural chemicals rather than when used alone. Accordingly, the amount of agricultural chemicals used can be reduced accordingly, which is important because the risk of environmental pollution can be improved.
[0043]
In addition, the inventors of the present invention, in parallel with the experiment of the present invention, about the morbidity and cost when the culture solution of the antagonistic culture, MYPG medium, pesticide (grancer) and sodium alginate are used in combination with this. The results are summarized in Table 5.
[0044]
Table 5 shows the morbidity due to the spraying of various culture solutions conducted at two experimental sites in Hokkaido, and shows each cost (Note that the morbidity of Mn ferrite is shown in Tables 3 and 4). See).
[0045]
As described above, when ferrite is used in combination with microorganisms or the like, an effect is obtained as compared with ferrite alone, but there are disadvantages in terms of cost as shown in Table 5.
[0046]
[Table 5]

[0047]
【The invention's effect】
According to the present invention, by spreading a disease control agent comprising a ferrite suspension, the growth of pathogenic bacteria in the soil is suppressed by the magnetic action generated in the soil, or the pathogenic bacteria are prevented from entering the plant. It is possible to prevent the occurrence of plant diseases without spraying the agricultural chemicals that are the source of pollution.
[0048]
In addition, if the commercially available pesticide is used in combination with a pesticide of the present invention in less than half of the normal amount, plant diseases can be reliably prevented, so that soil contamination by the pesticide and resulting river pollution can be significantly reduced. Can do.
[Brief description of the drawings]
FIG. 1 is a diagram showing the state of magnetization of Mn ferrite.
FIG. 2 is a diagram showing the state of magnetization of magnetite.
FIG. 3 is an explanatory diagram showing a distribution state of ferrite masses when a ferrite suspension is sprayed on soil in which plants are grown.
FIGS. 4A and 4B show a mechanism of current generation by a magnetic field due to a ferrite mass in soil, where FIG. 4A is an explanatory diagram showing a magnetic field formation state, and FIG. 4B is an explanatory diagram showing a current generation state by a magnetic field; .
FIG. 5 is a reference diagram obtained by copying a photograph taken of a ratio between a disease occurrence area and a non-occurrence area.
FIG. 6 is a reference diagram obtained by copying a photograph taken of a ratio between a disease occurrence area and a non-occurrence area.
FIG. 7 is a reference diagram obtained by copying a photograph taken of a ratio between a disease occurrence area and a non-occurrence area.
FIG. 8 is a reference diagram obtained by copying a photograph taken of a ratio between a disease occurrence area and a non-occurrence area.
FIG. 9 is a reference diagram obtained by copying a photograph taken of a ratio between a disease occurrence area and a non-occurrence area.
FIG. 10 is a reference diagram obtained by copying a photograph of a comparison between the cucumber and turf growing conditions.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Soil 2 Plant 2a Hair root 3 Ferrite 4 Magnetic field line 5 Pathogen 6 Current 7 Moisture

Claims (3)

The ferrite magnetic powder having a particle size of 200 to 300 angstroms is stirred in water to form a ferrite suspension, and the ferrite suspension is sprayed on the soil to be controlled for the plant disease, thereby causing the disease to the plant. A plant disease control agent using a ferrite suspension characterized in that it can be prevented. Strong magnetic field to the soil by particle size is sprayed 200-300 Angstroms ferrite magnet powder ferrite suspension and pear by stirring in water, the suspension control target and ing soil plant diseases And preventing the occurrence of disease of the plant by inhibiting the invasion of the pathogenic fungus into the plant through the magnetic action in the magnetic field and suppressing the growth of the pathogenic fungus in the soil. Plant disease control method using suspension. In claim 2, when spraying the ferrite suspension, together with spraying of the ferrite suspension, the ferrite suspension, characterized in that the fabric diffuser disease control agent prepared by chemical synthesis The plant disease control method used.

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