JP6375324B2 - A method for obtaining biomorphic silica nanoparticles from plant parts, wherein the plant parts are characterized by their high content. - Google Patents

Description

  The present invention relates to the decomposition of plant parts and the collection of nanosilica contained in those plant parts. Certain species of plants, such as Equisetophyta and oryza sativa, and some of those parts, including stems or grain husks, among others, contain sufficient amounts of silica. These nanometer-sized particles form a microscopic spatial structure that is characteristic of various plants and is retained even after removal of the organic phase. Silica may be accompanied by other ions such as potassium, sodium, calcium, aluminum, and magnesium. These are important for plant growth, and in their root system they can absorb them from the soil. The Applicant has separated the organic phase firmly attached to the nanosilica and removed the above-mentioned accompanying ions, i.e., ions that are not preferred for the final product, so that the nanosilica (- Silica of dimensions, purity, specific surface area and structure).

State of the Art The formation of silica from organisms, plants and animals takes place in an aqueous medium, using unsaturated silicic acid solutions under atmospheric pressure in the temperature range of 4 ° C to 40 ° C. This biological production reaches 1 billion tons per year (gigatons) and therefore exceeds the current industrial production of silica. The process by which silica formation in plants occurs has been subjected to extensive investigation. Organic media with a wide range of proteins, carbohydrates, lipids, metal ions, and phenolic compounds are so complex within the scope of these processes that they are not yet reproducible It has been known.

The simplest form of silica is a monomer of silicic acid formed from silicon, which is in the form of a tetrahedron and is surrounded by four hydroxyl groups. It is a common compound found in soil at low concentrations of a few mg / kg. It is this form that plants can get silicon from soil solution and accumulate it. A polycondensation process then occurs when the concentration in the plant exceeds a value of 100-200 mg / kg. The polycondensation reaction leads to polymerization of monomers and formation of critical size stable nuclei. In addition, it leads to an increase in nuclei in the form of spherical particles, aggregated particles forming branched chains, or structural motifs. When particles reach a size of 1-3 nm, they are found in nature and negative charges are formed. The charged particles then interact in the environment surrounding them. This environment is the plant cell wall to which the particles are bound. The silica condensation process is affected by many different factors such as the concentration of silicic acid, temperature, pH, and the presence of accompanying ions. In all cases, the material embodying the plant consists of O—Si—O with various bond angles and SiO ₄ tetrahedrons with bond lengths of Si—O. The size of the material is 1 nm amorphous. It contains hydroxyl groups and its parameters can vary based on the reaction environment and the type of organism formed by the silica.

  There are significant differences in the structure formed from silica nanoparticles depending on the plant species. Silica penetrates the entire plant structure or forms a surface or subsurface layer, which has typical protective functions, as shown, for example, in rice husk studies. The thickness of such a layer is on the order of micrometers. The layer is created by nanostructured particle formation, which has dimensions in the range of 10-60 nm. There can be several layers on top of each other, which can be clearly distinguished.

  In terms of chemical composition, silica in plants is usually accompanied by additional ions (ie, sodium, potassium, calcium, magnesium, and aluminum) at different concentrations. Although these ions are important for plant growth, they are inappropriate from the standpoint of obtaining nanosilica as a degradation product because they reduce purity, increase particle size, and reduce surface area. The silica particles surround it and are very tightly bound to the organic phase formed to various extents by cellulose, hemicellulose, and lignin.

  In order to obtain natural nanoparticles, ie biomorphic silica with the required parameters, both undesired accompanying ions and organic phases are removed and the silica nanoparticles are released from the natural composite system Is necessary, which serves as a reinforcement from a mechanical standpoint.

  The most common methods of treating plant debris to obtain high purity, small particle size, and suitable porous biomorphic silica include chemical modification following heat treatment or heat treatment following chemical modification, and A reheat treatment following a hydrothermal treatment or a biochemical treatment is mentioned. Heat treatment at a temperature above 1100 ° C. (ie, a combustion temperature range of 400 ° C. to 900 ° C.) converts amorphous silica into crystals. Silica obtained by any of the previously known methods is similar to silica produced by an industrial process at a temperature of about 1700 ° C. Many papers and patents such as Korean Patent Publication (KR 2013-0060297A, “Method of preparation high-purity silica derived from rice husks”), Russian patent publication Publication (RU 2003-125691A, “Method of production of silicon dioxide from wastes of rice production and device for realization of this method” ")"), International Publication (WO 02/092507, "Method for production of high purity amorphous silica from biogenic material")) All of the methods that utilize the process of combustion are to wash with raw water, dry and then remove the accompanying ions This involves a multi-stage process consisting of chemical treatment of the powdered or solid part of the plant required for subsequent combustion and subsequent combustion, which ensures removal of the organic phase. According to the proposed technique, burning of plant parts occurs either at the beginning or at the end of the process. It is indispensable to obtain the final product, which is a nanostructured biomorphic silica with high purity or fairly low content of sodium compounds, potassium, calcium, magnesium, aluminum, chemical pretreatment is Usually, hydrochloric acid is used with an alternative to sulfuric acid or nitric acid. Powdered or solid plant parts are placed in acid and boiled for several hours at temperatures above 100 ° C. The removal of the accompanying ions mentioned above is very important, on the one hand, because it leads to a decrease in the temperature of destruction of plant residues (ie they act as flux), which has an economic advantage. On the other hand, they will cause caking of plant residues, which adversely affects the size of the resulting particles and the pore size. Thermogravimetric analysis to identify temperature, which causes degradation of cellulose, hemicellulose, and lignin components, which are the main components of plant residues. The temperature range is 300 to 600 ° C. Complete decomposition of the organic phase occurs at a temperature of about 650 ° C. and, based on the pretreatment method, leaves ash contaminated to some extent with sodium, potassium, calcium, magnesium, aluminum and phosphorus. Pretreatment processes and shell burning have been verified and proven in many specialized magazines. According to literature reviews, these methods of obtaining silica are described for various types of products containing higher amounts of silicon dioxide in their plant parts, such as horsetail, rice husk and ears, sugarcane stems Has been. Commonly used analytical methods to describe the particle size, chemical composition, surface area, porosity, type of bond on the silica surface are SEM, EDX, TGA, FT-IR, BET, TEM, RTG. is there.

Principle of the Invention The principle of the present invention is to provide a suitable concentration of acid for an untreated plant site characterized by a high silica content in a volume that is reliably reacted at the appropriate temperature, pressure and microwave run. Addition of mixtures or inorganic acids. As a result, performing the inorganic acid or mixture of acids with appropriate temperature, pressure, and exposure to microwaves will result in organic phases (ie, cellulose, cellulose, hemicellulose, lignin, and others). , Decompose over time. Undesired accompanying ions of potassium, sodium, calcium, aluminum, magnesium are removed in the same time as the decomposition of the organic phase. The product of the degradation process is biomorphic silica nanoparticles that are washed and transferred to an aqueous solution, which is then dried to obtain a powder. The physical and chemical properties of the decomposition process are essential for carrying out the method according to the invention. During the course of the process, there is simultaneous decomposition of the organic phase and removal of undesirable elemental accompanying ions in a single step without prior mechanical, physical or chemical pretreatment of the feedstock.

The decomposition of the organic phase involves oxidation and reduction reactions and is accomplished using high concentrations of nitric acid or reverse aqua regia. The acid run also removes unwanted accompanying ions, which are expelled into the solution in the form of salts. According to the present invention, the plant part is a microwave reaction vessel with a maximum microwave output of 1500 W comprising 65% nitric acid or reverse aqua regia composed of 3 parts 65% nitric acid and 1 part 38% hydrochloric acid. Place in for 50-70 minutes. Plant site degradation occurs during three consecutive periods. In the first 15 minute period, the microwave reactor is heated to a temperature of 190 ° C. to 230 ° C. and the pressure is increased to 5.5 MPa (55 bar) with a maximum power of 1500 W. The plant material is then decomposed for 20-40 minutes at 230 ° C., a pressure of 5.5 MPa (55 bar), and an output in the range of 600 W to 750 W. During the third continuous stage, the microwave source is turned off, and during the remaining period the reaction vessel temperature may be reduced to about 75 ° C. and the pressure to a value of about 0.5 MPa (5 bar), and the resulting nanoparticles The biomorphic silica clusters are washed with distilled water to pH 7 and then dried. During the decomposition process using nitric acid or reverse aqua regia, undesirable potassium, magnesium, sodium, calcium, and aluminum accompanying ions and the organic phase of the plant parts are removed.

  The feedstock subjected to physical and chemical decomposition does not require pretreatment by grinding, rinsing with water or other solvents, or additionally drying. It has been found that the degradation reaction is more likely to occur due to freely scattered shells, for example, that the powder obtained in the form of rice or biomorphic silica nanoparticles appears more finely.

  The actual decomposition process along with the process of removing the accompanying ions of the undesired elements is performed in a microwave reactor at a power of 600 W to 750 W, a temperature of 190 ° C. to 230 ° C., and a maximum pressure of 5.5 MPa (55 bar). Occurs in the presence of the aforementioned acids under the conditions achieved in

  The products of these processes are agglomerates of biomorphic silica nanoparticles and are tens of nanometers in size. The particles can be retained during the next process in aqueous solution or dried to form a powder.

The weight ratio was tested on plant parts with the amount of acid used. In the case of nitric acid, 0.8-1.2 g of plant parts were used for 10-14 ml of 65% nitric acid. The same amount of plant part was used for 10 to 14 ml of reverse aqua regia.

  The biomorphic silica nanoparticles obtained according to the present application were characterized in terms of particle size and purity and compared with commercially available products. The methods described above, ie scanning electron microscope, FT-IR, and EDX analysis, were used for characterization.

  The procedure for obtaining biomorphic silica nanoparticles according to the present invention is illustrated in the accompanying figures.

FIG. 1 is a decomposition process that occurs in a microwave reaction vessel from three consecutive parts characterized by the process of microwave output of the reaction vessel, depending on temperature progression and pressure in the reaction vessel. It is a figure which shows the graph display of the comprised decomposition process. (Curve (A) represents the microwave in the reaction vessel during the cracking process, curve (B) represents the pressure during the cracking process, and curve (C) represents the temperature during the cracking process. ) FIG. 2 shows a scanning electron microscope image of biomorphic silica obtained by decomposition of plant material and depicts individual particles and clusters of biomorphic silica. FIG. 3 is an EDX analysis of the chemical composition of biomorphic silica obtained by decomposition of plant material containing C, O and Si. (Chemical composition is typically given in both weight and atomic percentage. The presence of carbon occurs only by fixing the powder during EDX analysis.) FIG. 4 shows a comparison of the SiO ₂ specific chemical bonds obtained by FT-IR analysis, where (A) fits the synthetically produced silica Cab-O-Sil and (B) Refers to nanoparticles of biomorphic oxide silica obtained by decomposition of whole rice husk in 65% HNO ₃ , (C) is a reverse aqua regia consisting of a mixture of 3 parts 65% HNO ₃ and 1 part 38% HCl It relates to nanoparticles of biomorphic silica obtained by decomposition of whole rice husks.

(Example 1)
Biomorphic silica nanoparticles were prepared by adding 12 ml of 65% nitric acid to 1 g of rice husk or ear of rice. The rice husks or ears soaked in acid are then placed in a microwave reactor in which the decomposition reaction takes place for 1 hour at a temperature of 190 ° C. to 230 ° C., a pressure of 5.5 MPa (55 bar), and 1500 W. (See FIG. 1). In this figure, (A) represents the microwave power of the reaction vessel during the cracking process, (B) represents the pressure during the cracking process, and (C) represents the temperature during the cracking process. . The process that takes place in a microwave reactor consists of three consecutive periods. In the first 15 minute period, the microwave reactor is heated to a temperature of 230 ° C. and the pressure is increased to 5.5 MPa (55 bar) with a maximum power of 1500 W. The plant material is then decomposed for 30 minutes at 230 ° C., a pressure of 5.5 MPa (55 bar), and an output in the range of 600 W to 750 W. During the third period of 15 minutes, the microwave source is turned off, the temperature in the reaction vessel may be reduced to a value of about 75 ° C. and the pressure to a value of about 0.5 MPa (5 bar). In this way, the undesirable accompanying ions of potassium, magnesium, sodium, calcium, and aluminum and the organic phase of the plant parts are removed from the cluster of biomorphic silica nanoparticles. The degradation product was washed with distilled water to pH 7 and then dried. The resulting biomorphic silica particles were then characterized by FT-IR, SEM, EDX analysis (-FIG. 2, with individual particles of biomorphic silica and their clusters, resulting biomorph (See FIG. 3 with information on the chemical composition of Fick silica, which is given in both weight and atomic percentage). The presence of carbon occurs only by fixing the powder during EDX analysis. The contents of oxygen and silicon in weight and atomic percentage are given by the table below in FIG. FIG. 4 compares the chemical bonds unique to silica, whereby the horizontal axis indicates wavelength and the vertical axis indicates normalized absorbance. Curve (A) shows synthetically produced silica and (B) shows biomorphic silica nanoparticles obtained by decomposition of whole rice husk in 65% HNO ₃ . Comparison of the two curves showed similarity for both obtained samples.

(Example 2)
Biomorphic silica nanoparticles were prepared by adding 12 ml of reverse aqua regia (a mixture of 3 parts 65% nitric acid and 1 part 38% hydrochloric acid) to 1 g of rice husk or ear. The rice husks or ears soaked in acid are then placed in a microwave reactor in which the decomposition reaction takes place for 1 hour at a temperature of 190 ° C. to 230 ° C., a pressure of 5.5 MPa (55 bar), and 1500 W. Of maximum microwave power. See FIG. In this figure, curve (A) represents the microwave in the reaction vessel during the cracking process, curve (B) represents the pressure during the cracking process, and curve (C) represents the temperature during the cracking process. Represents. The process that takes place in a microwave reactor consists of three consecutive periods. In the first 15 minute period, the microwave reactor is heated to a temperature of 230 ° C. and the pressure is increased to 5.5 MPa (55 bar) with a maximum power of 1500 W. The plant material is then decomposed for 30 minutes at 230 ° C., a pressure of 5.5 MPa (55 bar), and an output in the range of 600 W to 750 W. During the third period of 15 minutes, the microwave source is turned off and the temperature in the reaction vessel can be reduced to a value of about 75 ° C. and the pressure to a value of about 0.5 MPa (5 bar). In this way, the undesirable accompanying ions of potassium, magnesium, sodium, calcium, and aluminum and the organic phase of the plant parts are removed from the cluster of biomorphic silica nanoparticles. The degradation product was washed with distilled water to pH 7 and then dried. The resulting biomorphic silica particles were then characterized by FT-IR, SEM, EDX analysis. Figure 2 with individual particles of biomorphic silica and their clusters, Figure 3 with information on the chemical composition of the resulting biomorphic silica, given in both weight and atomic percentage. See The presence of carbon is only caused by fixing the powder during EDX analysis. The contents of oxygen and silicon in weight and atomic percentage are given by the table below in FIG. FIG. 4 compares the chemical bonding of a typical silica, whereby the horizontal axis shows wavelength and the vertical axis shows normalized absorbance. Curve (A) is synthetically show a manufacturing silica, (C) is obtained by decomposition of the total chaff in the reverse Wang water consisting of 38% mixture of hydrochloric acid 65% nitric acid and 1 part of 3 parts 1 shows nanoparticles of biomorphic silica. Comparison of the two curves showed similarity for both obtained samples.

Claims (6)

A method of obtaining biomorphic silica nanoparticles from plant parts, characterized in that the plant parts are characterized by their high content,
Without pretreatment, the plant part is a microwave with a maximum microwave output of 1500 W, including reverse aqua regia consisting of 65% nitric acid or a mixture of 3 parts 65% nitric acid and 1 part 38% hydrochloric acid Placed in the reaction vessel for 50-70 minutes,
The plant part decomposition reaction takes place in three consecutive periods, and in the first 15 minutes period, the microwave reaction vessel is heated to a temperature of 190 ° C. to 230 ° C., and the pressure is 1500 W maximum power, After that, the plant material is decomposed for 20-40 minutes at 230 ° C., a pressure of 5.5 MPa, and an output in the range of 600 W to 750 W, and during the third continuous stage, The microwave source is turned off, and during the remaining period, the temperature of the reaction vessel may be reduced to 75 ° C., the pressure may be reduced to a value of 0.5 MPa, and the resulting nanoparticulate biomorphic silica cluster may be diluted with distilled water. Said method characterized in that it is washed to pH 7 and then dried. The plant part according to claim 1, wherein the plant part is mixed at a ratio of 0.8 g to 1.2 g plant part to 10 ml to 14 ml of 65% nitric acid. To obtain the nanoparticles. The plant part according to claim 1, wherein the plant part is mixed at a ratio of 0.8 g to 1.2 g of plant part to 10 ml to 14 ml of reverse aqua regia. To obtain the nanoparticles.   During the decomposition process using 65% nitric acid or reverse aqua regia, undesired addition ions of potassium, magnesium, sodium, calcium, and aluminum and the organic phase of the plant part are simultaneously removed. A method for obtaining biomorphic silica nanoparticles from a plant part according to Item 1.   The biomorphic from the plant part according to claim 1, wherein the biomorphic silica nanoparticles obtained from the decomposition reaction are held either in an aqueous solution or in a dried powder. A method for obtaining silica nanoparticles.   Use of plant parts characterized by high content of silica, such as rice husks, ears of rice, various types of horsetail, barley straws, from plant parts to biomorphic silica according to claim 1 To obtain the nanoparticles.