RU2225086C1 - Method of phytoreclamation of oil-polluted lands - Google Patents

Abstract

FIELD: oil protection. SUBSTANCE: method, which can be used for removing toxic effects of crude oil hydrocarbons on soils and agricultural plants, envisages sowing annual and perennial plants on oil-polluted land. Prior to be grown, grains and/or plant shoots are treated with antifungal microbial preparations or antibiotics. These preparations diminish number and activity of saprotroph micromycetes associated with plants, which produce substances showing phytotoxic activity. In particular, plant sprouts are treated with aqueous solution of preparation called AGAT-25K in dose 1 ml per 10 l water or aqueous solution of Trichodermin in dose 150 mg per 10 l water, or yet antibiotic Nystatin taken in concentration at least 0.001% per soil layer 10 cm thick. Treatment is performed threefold in season with 20 day intervals, the first treatment being performed 10-14 days after sowing of grains. Antifungal microbial preparations used for soaking grains during at least 3 days are the following: preparation AGAT-25K in dose 5 ml per 1 kg grains, Trichodermin in dose 100 mg per 1 kg grains, or Nystatin in concentration 0.001%. EFFECT: increased productivity of plants on oil-polluted land. 3 cl, 3 dwg, 3 tbl, 7 ex

Description

 The invention relates to environmental protection and can be used to eliminate the toxic effects of oil hydrocarbons on soil and agricultural plants.

There is a phytomeliorative reclamation method for soil contaminated with oil products (Restoring oil-contaminated soil ecosystems. - M .: Hauka, 1988, p. 159), according to which peat in the amount of 500 m ³ / ha or manure 50 t / ha, full mineral fertilizers (N ₆₀ P ₄₀ K ₂₀ ), as well as unpolluted soil. Simultaneously with the introduction of the components, the soil was loosened to a depth of 15 cm. After a year, perennial grasses are sown. At the same time, germination, for example, boneless bonfire, is 70%, and meadow fescue 22%. The amount of residual oil after 1.5 years of reclamation is 20%.

The disadvantage of this method is the relatively large presowing period (1 year), the relatively low germination and productivity of perennial grasses after a period of ventilation, the lack of plant growth with a high degree of pollution (≥24 l / m ² ).

 The objective of the invention is to develop a simple and effective method of phytoremediation of oil-contaminated soils, which increases the survival and productivity of plants growing on oil-contaminated soils.

 The problem is solved using the characteristics specified in paragraph 1 of the claims common to the prototype, such as a method of phytoremediation of oil-contaminated soils, which includes the stage of sowing on oil-contaminated soil one and perennial plants, and distinctive essential features, such as seeds before planting and / or seedlings of plants are treated with antifungal microbial preparations or antibiotics that reduce the number and activity of saprotrophic micromycetes associated with plants that are food cents substances with phytotoxic action.

 In paragraph 2 of the claims reflected the type and conditions of use of the preparations for the treatment of plant shoots, namely, as an antifungal preparation for the treatment of plant shoots, it is preferable to use an aqueous solution of Agat-25K in a dose of 1 ml per 10 l of water, or an aqueous solution of Trichodermin a dose of 150 mg per 10 liters of water, or an antibiotic Nystatin in a concentration of at least 0.001% per 10 cm soil layer, and the treatment is carried out three times a season with an interval of 20 days, with the first treatment 10-14 days after eve seed.

 Clause 3 of the claims reflects the type and conditions of use of preparations for treating plant seeds, namely, as an antifungal agent for soaking plant seeds for at least 3 days, Agat-25K is preferably used at the rate of 5 ml of the preparation per 1 kg of seeds or the drug Trichodermin at the rate of 100 mg of the drug per 1 kg of seeds, or the Nystatin antibiotic solution at a concentration of 0.001%.

 The inventive plants are treated with antifungal drugs, causing a decrease in the number of saprotrophic micromycetes and their activity in the root zone of plants growing on oil-contaminated soil. The aim of the invention is to increase the survival and productivity of plants growing on soil with oil pollution. The ingress of oil into the soil causes an increase in saprotrophic micromycetes associated with the plant, which have phytotoxic properties, which leads to inhibition and death of plants. For the treatment of plants, antifungal antibiotics or preparations of symbiotic microorganisms are used that reduce the number of micromycetes in the rhizosphere and rhizoplan of plants. A decrease in the number of these microorganisms in the zone of plant roots leads to a decrease in toxicity to plants of oil-contaminated soil.

 As our studies have shown, the main factor affecting the germination of seeds in contaminated soil is the deterioration of water and air conditions during the application of oil, while there was no direct toxic effect of oil on plants (Fig. 1). In the variant with soaked seeds planted on the soil surface, a decrease in the number of sprouted plants is observed only after a dose of oil pollution of 30%. Above this dose, oil ceases to be absorbed by soil particles. In this case, individual plants appeared in the experiment even when contaminated with 40%, when the oil formed a film 3-4 mm thick.

 However, it is known that oil, when it enters the soil, has strong phytotoxicity. The experiments showed a significant effect on the survival of plants on oil-contaminated soil basal microflora. On non-sterile contaminated soil, with a dose of oil of 30%, the death of all plants is observed, while under sterile conditions, the survival of plants on soil with oil is comparable to the survival of plants on clean soil with a non-sterile environment (figure 2).

 When inoculation of fungal culture in oil-contaminated sterile soil is also observed complete death of plants. This shows that the main microorganisms toxin-forming in oil-contaminated soil are saprotrophic fungi.

 An analysis of the number of micromycetes in oil-contaminated soil and in the root zone of plants of beechless rump and clover meadow shows that, during oil pollution, there is a sharp increase in the number of micromycetes in the zone of plant roots, exceeding the increase in the number of fungi in the edaphosphere when oil is introduced (Table 1). Moreover, in most cases, in the basal zone of the boneless rump, their number is an order of magnitude higher than in rootless soil, and in meadow clover, by two orders of magnitude.

 To assess the increase in toxicity of non-oil-contaminated soil due to an increase in the number of saprophytic micromycetes, the germination of meadow clover seeds on soil extracts from the edaphosphere and from the rhizosphere of clover meadow and befootless campfire grown with different levels of oil pollution was studied. In this case, the extract was both from soil without plants, contaminated immediately before extraction, and incubated after contamination for 14 days.

 The obtained germination data showed (Fig. 3) that the number of germinated seeds depended on the number of saprotrophic micromycetes in the soil. The correlation coefficient between seed germination and the number of fungi in the soil from which the extract was made was -0.8.

 Thus, the stimulation of phytotoxic micromycetes in the root zone by oil pollution is one of the main factors determining the negative effect of oil-contaminated soil on plants, and the use of antifungal drugs significantly intensifies the phytomeliorative reclamation stage of oil-contaminated soils.

 The following examples illustrate the invention, but do not limit the scope of its use.

 The method is as follows.

 General process conditions. To inhibit fungi, industrial preparations are used - Trichodermin, Agate-25K, the antibiotic Nystatin or any other antifungal agents - in current concentrations. Working suspensions of bacterial preparations were prepared according to the instructions proposed by the manufacturers.

 Trichodermin is a bacterial preparation based on Trichoderma viride micromycete, which is able to parasitize on many phytopathogenic fungi and release a number of antibiotics into the soil (Viestus U., Leite M. Some new biotechnologies and technologies for their implementation // Applied Biochemistry and Microbiology. - 1997. - T. 33. - N 3. - S. 243-256).

Used in the experiments Trichodermin was obtained at the Perm State Agricultural Academy. D.N. Pryanishnikov by inoculating barley grains with a fungus culture. The number of spores of the fungus in the bacterial preparation (1.0-1.2) • 10 ¹⁰ cells / g. For treatment with Trichodermin, 150 mg of the bacterial preparation was diluted in 10 l of water, the suspension obtained is sufficient for processing 10 m ^{2 of} land.

 Agate-25K is a bacterial preparation based on a number of soil bacteria, in addition to them it contains trace elements and physiologically active substances. Agate-25K induces the protective properties of plants against bacterial and fungal diseases; the bacterial component of the drug fixes nitrogen from the air, mobilizes insoluble phosphorus compounds in the soil, and improves the mineral nutrition of plants; physiologically active substances stimulate the growth and development of plants (Instructions for the use of the biological product "Agat-25K", 1998).

Agate-25K working solution was obtained by diluting the drug at the rate of 1 ml of the drug per 10 liters of water; the resulting solution is sufficient to treat an area of 10 m ² .

 Bacterial treatment was carried out 3 times per season with an interval of 20 days, the first spraying of plants was carried out 10 days after sowing seeds.

Nystatin is a broad-spectrum antifungal antibiotic, it belongs to polyolene macrolide antibiotics, the total formula is C ₄₇ H ₇₅ O ₁₈ , produced by Streptomyces noursei (Egorov N.S. Fundamentals of the doctrine of antibiotics. - M.: Moscow State University, 1994, 512 pp.).

 The antibiotic was used according to the recommendations proposed in the literature (Shigaeva M.Kh., Tulemisova K.A. Antibiotics in crop production. - Almaty: Publishing House "Science" of the Kazakh SSR, 1977, 170 pp.), The dose of Nystatin was 0.001 % per 10 cm soil layer.

 Nystatin treatment was carried out at the same time as bacterial preparations.

Trichodermin for use is mixed with 150 mg per 10 liters of water, Agat-25K - 1 ml of the drug per 10 liters of water, Nystatin - contribute at a concentration of not less than 0.001% per 10 cm soil layer. The resulting mixture of Trichodermin and Agate-25K is uniformly applied to plants on contaminated soil by spraying at the rate of 1 liter per 1 m ² . Antifungal treatment is carried out at least three times per season with an interval of 20 days, the first spraying of plants is carried out no more than 10-14 days after sowing seeds.

Example 1. Survival and yield of plants was studied at experimental oil-contaminated sites in the field. The seeds of clover meadow (Trifolium pratense) were sown in experimental plots with different periods of contamination (in the same year, 1, 2, 3 and 4 years after the oil was added) with a dose of 24 l / m ² . After three months after sowing, the biomass and the percentage of plants surviving after this period were evaluated.

Example 2. Similar studies were carried out with the treatment of plants with the bacterial preparation Agat-25K, for the use of which 1 ml of the preparation and 10 l of water were mixed, the resulting mixture was uniformly applied to plants on contaminated soil by spraying at the rate of 1 l per 1 m ² . The treatment was carried out 3 times per season with an interval of 20 days, the first spraying of plants was carried out 10 days after sowing seeds.

Example 3. The experiment was carried out analogously to example 2. The difference was in the treatment of plants with a micromycetic preparation using Trichodermin. The drug for use was mixed with 150 mg per 10 l of water. The resulting mixture was uniformly applied to plants on contaminated soil by spraying at the rate of 1 liter per 1 m ² . Trichodermin treatment was carried out 3 times per season with an interval of 20 days, the first spraying of plants was carried out 12 days after sowing seeds.

 Example 4. The study of the survival and productivity of plants on oil-contaminated soil was carried out analogously to example 3. Only for the treatment of plants used the antibiotic Nystatin. Nystatin was added at a concentration of not less than 0.001% per 10 cm soil layer. Treatment with Nystatin was carried out 3 times per season with an interval of 20 days, the first spraying of plants was carried out 14 days after sowing seeds.

 Example 5. The studies were carried out analogously to example 2. The experience was different in that, along with the treatment of plants with Agat-25K, it was also used to soak the seeds. Seed treatment was carried out for 3 days at the rate of 5 ml of the drug per 1 kg of seeds.

 Example 6. The experiment was carried out analogously to example 3. The differences were in the treatment before sowing the seeds with Trichodermin, the seeds were soaked in a suspension of the drug for 3 days, Trichodermin was added to the suspension at the rate of 100 mg of the drug per 1 kg of seeds.

 Example 7. Similar studies are shown in example 4, conducted with seed treatment with the antibiotic Nystatin. When soaking, the seeds were poured with a solution of Nystatin at a concentration of 0.001%, the processing time was also 3 days.

 The research results shown in examples 1-4 are given in table. 2, and the experimental data in the examples specified in examples 5-7 are in table. 3.

 As can be seen from the table. 2, where examples 2, 3 and 4 of the claimed method, reducing the number of micromycetes in the root zone using antifungal drugs leads to increased survival and productivity of plants in oil-contaminated sites.

 Treatment with Nystatin and Trichodermin increased the total biomass of plants grown on oil-contaminated soil, in most cases by 2–3 times, and with the bacterial preparation Agat-25K, by 6–11 times, while treatment with the first two drugs increased the survival of plants on oil-contaminated soil by 2-3 times, and Agat-25K - 4-10 times.

 The use of soaking seeds in a solution or suspension of antifungal drugs together with their treatment of grown plants (examples 5,6,7 - the claimed method) increases their productivity and survival relative to plants in which the seeds were not treated with antifungal drugs (examples 2, 3, 4 ) in most cases, 1.5-2 times (table. 3).

Claims (3)

1. The method of phytoremediation of oil-contaminated soils, which includes the stage of sowing on oil-contaminated soil one and perennial plants, characterized in that the seeds before planting and / or seedlings of the plants are treated with antifungal microbial preparations or antibiotics that reduce the number and activity of saprotrophic micromycetes associated with plants that are plants producers of substances with phytotoxic effects. 2. The method according to claim 1, characterized in that as an antifungal agent for the treatment of plant emergence, an aqueous solution of the drug Agat-25K in a dose of 1 ml per 10 l of water is preferably used, or an aqueous solution of the drug Trichodermin in a dose of 150 mg per 10 l of water or Nystatin antibiotic at a concentration of not less than 0.001% per 10 cm soil layer, the treatment being carried out three times a season with an interval of 20 days, and the first treatment 10-14 days after sowing the seeds. 3. The method according to claim 1, characterized in that as an antifungal agent for soaking the seeds of the plants for at least 3 days, it is preferable to use the drug Agat-25K at the rate of 5 ml of the drug per 1 kg of seeds, or the drug Trichodermin at the rate of 100 mg of the drug per 1 kg of seeds, or a solution of Nystatin antibiotic in a concentration of 0.001%.

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