CN110143614B - Preparation method and application of molybdenum oxide with one-dimensional nanostructure - Google Patents

Abstract

The inventionDiscloses a preparation method and application of molybdenum oxide with a one-dimensional nano structure, belonging to the field of biological probes. The invention, by H₂O₂Preparation of orange MoO by oxidizing high-purity molybdenum powder₃Adding a certain amount of absolute ethyl alcohol into the precursor solution, and then heating for 48 hours at 180 ℃ to obtain black MoO₂‑MoO₃Filtering, washing and drying the suspension to obtain high-purity one-dimensional MoO₂‑MoO₃A nanomaterial; by introducing the substrate plate, the crystal growth speed and fineness of the precursor solution on the surface of the substrate plate in the vertical direction are accelerated. Provides a preparation method of a substrate material of a biological probe with high toughness and high sensitivity.

Description

Preparation method and application of molybdenum oxide with one-dimensional nanostructure

Technical Field

The invention belongs to the field of biological probes, and particularly relates to a preparation method and application of molybdenum oxide with a one-dimensional nano structure.

Background

MoO, a potential application of molybdenum oxide with performance increased by controlling and excavating morphology of molybdenum oxide through a plurality of research subjects in recent years₂Is an excellent semi-metallic semiconductor material, although the research on the application base is far inferior to that of MoO₃The method has wide application range, but has wider application effect in the aspect of building functional microelectronic devices; and due to MoO₂Has huge surface area, which has obvious advantages in nano-scale interfacial chemistry and nano-adsorption.

The development of biosensors has been over 30 years, the existing biological probes generally select porous silicon sensitive materials as substrate materials, and the porous silicon sensitive nano materials have small particle size and large specific surface area, so that the high specific surface area promotes the combination of bioactive probes in porous silicon and detected molecules, and the biological sensitivity has many advantages. Meanwhile, due to the fact that the porous silicon is made of the non-metallic semiconductor material, on one hand, the toughness of the porous silicon is poor, a few of incompletely-formed substrates are easy to break in a long-term use process, the service life of the biosensor is greatly shortened, and on the other hand, due to the poor conductivity of the porous silicon, when the porous silicon is used as a biological probe substrate, metal nano particles need to be filled, and therefore the sensitivity of the biosensor is low.

Disclosure of Invention

The purpose of the invention is as follows: provides a preparation method of molybdenum oxide with a one-dimensional nano structure, which aims to solve the problems in the background technology.

The technical scheme is as follows: a preparation method of molybdenum oxide with a one-dimensional nanostructure comprises the following steps:

s1, slowly adding 4g of high-purity molybdenum powder into 30-40 g of H for 4-8 times₂O₂And 58-68 g of purified water, and fully stirring for 3-5 h at normal temperature to form an orange precursor solution;

s2, adding absolute ethyl alcohol with the mass being 5-15% of that of the precursor solution into the orange precursor solution, and stirring for 2-3 h at constant temperature;

s3, adding the precursor mixed solution into a sealed reaction kettle, putting the reaction kettle into a constant-temperature heating box, heating for 48-96 hours at the temperature of 100-200 ℃, and obtaining black MoO after the reaction is finished₂- MoO₃Suspending liquid;

s4, filtering, washing and drying to obtain MoO₂-MoO₃A one-dimensional nanomaterial.

In further embodiments, the H₂O₂Is an oxidation source and has the mass fraction of 30 to 100 percent.

In further implementation, in the step S1, the molybdenum powder is mixed with H₂O₂The molar concentration ratio of (1): (25-30).

In the further implementation process, the reaction kettle shell in the steps S1 and S3 is made of high-temperature and high-pressure resistant sealed stainless steel, and a layer of sealed polytetrafluoroethylene material is embedded in the inner layer to form a protective layer.

In a further implementation process, in the step S1, a temperature measuring step is further included, in which a temperature measuring device is disposed in the reaction vessel for measuring the temperature of the reaction system; and detecting the absorbance in the orange solution by using a spectrophotometric agent, and calculating the concentration of the precursor solution.

In a further implementation, the step of S2 may further be: diluting the orange solution to a water solution with the mass concentration of 0.05g/ml, adding the diluted orange solution into a transparent glass container, then thoroughly cleaning and drying the surface of the substrate plate, stably placing the substrate plate on the liquid surface of the diluted solution, sealing the glass container, finally placing the sealed glass container into an oven, and heating for 6-24 hours at the temperature of 40-60 ℃.

In a further embodiment, the substrate plate has an area of 1X 1cm²Hollow simple substance silicon is used as a main body, and the average density of the whole body is 1.1 g/ml; and a 600-900 nm silicon dioxide coating is plated on the surface of the simple substance silicon.

In a further implementation process, in the step S3, the filtering, washing, and drying processes specifically include:

the method comprises the following steps: solid MoO on filter paper₂- MoO₃The one-dimensional nano material is transferred into a beaker, and absolute ethyl alcohol washing liquid is sprayed to the solid MoO coagulated into blocks from a spray head at a high speed₂- MoO₃Scattering the one-dimensional nano material into particles;

step two: slightly stirring for 10-15 min to enable solid MoO₂- MoO₃One-dimensional nano material and absolute ethyl alcohol washing liquid form uniformly distributed heterogeneous dispersion liquid, and then the dispersion liquid is filtered and separated to obtain solid MoO₂- MoO₃A one-dimensional nanomaterial filter cake;

step three: repeating the first step and the second step for 1-2 times; replacing the absolute ethyl alcohol washing liquid with distilled water, and continuously repeating the first step and the second step for 2-3 times;

step four: drying solid MoO by natural air drying₂- MoO₃And (3) a one-dimensional nano material filter cake.

On the other hand, the application of the molybdenum oxide with the one-dimensional nano structure can be used as a substrate for manufacturing various biological probes.

In further implementation, as a substrate for RNA nucleic acid biological probe, the synthesis steps are as follows:

the method comprises the following steps: the synthesized MoO₂-MoO₃Soaking the one-dimensional nano material in 0.01mol/L isobutyl triethoxy silicon solution for 2 hours, washing with ionized water, and drying; then continuously soaking in 2.5% glutaraldehyde water solution for 2h, washing with phosphate buffer solution, and drying;

step two: to functionalizeOf MoO₂-MoO₃One-dimensional nano material is used as a substrate, probe RNA with the concentration of 40umol/L is dripped into MoO by a micropipette₂-MoO₃Standing the surface of the one-dimensional nano material for 2 hours at the constant temperature of 36.5 ℃, and then adding MoO₂-MoO₃Soaking the one-dimensional nano material in 3mol/L Ethanolamine (EA) solution, standing for 2h at the constant temperature of 36.5 ℃, and finally washing the unconjugated probe RNA by PBS.

Has the advantages that: the invention relates to a preparation method and application of molybdenum oxide with a one-dimensional nano structure, which is prepared by H₂O₂Preparation of orange MoO by oxidizing high-purity molybdenum powder₃Adding a certain amount of absolute ethyl alcohol into the precursor solution, and then heating for 48 hours at 180 ℃ to obtain black MoO₂-MoO₃Finally filtering, washing and drying the suspension to obtain high-purity MoO with a one-dimensional structure₂-MoO₃A nanomaterial; by introducing the substrate plate, the crystal growth speed and fineness of the precursor solution on the surface of the substrate plate in the vertical direction are accelerated. Provides a preparation method of a substrate material of a biological probe with high toughness and high sensitivity.

Drawings

FIG. 1 shows X-ray diffraction (XRD) data of molybdenum oxide samples obtained in examples 1 to 4.

FIG. 2 shows the red shift of the reflectance spectra for different RNA concentrations obtained in example 1.

FIG. 3 shows the RNA detection limit and sensitivity of the RNA nucleic acid bioprobe samples obtained in examples 1 and 4 to 6.

Detailed Description

In the following description, numerous specific details are set forth in order to provide a more thorough understanding of the present invention. It will be apparent, however, to one skilled in the art, that the present invention may be practiced without one or more of these specific details. In other instances, well-known features have not been described in order to avoid obscuring the invention.

In order to solve the problems of the prior art, the applicantAfter the intensive study on the preparation process of the existing biological probe-bearing material, the following findings are obtained: 1. most of the existing biological probes adopt porous silicon nano materials as substrates; the porous silicon nano material is mostly prepared by adopting an electrochemical carving method in the preparation process, and belongs to a top-down process for cutting and refining macroscopic substances by adopting a physical or chemical method to obtain the nano-scale substances. The purity, the nanometer fineness and the one-dimensional structural integrity of the one-dimensional nanometer material prepared by the method are generally low, so that the use effect and the service life of the biological probe are influenced. And are not discussed in detail herein. 2. MoO in a conventional one-dimensional structure₃Adding a certain amount of absolute ethyl alcohol, and in the hydrothermal reaction crystallization process, under the reduction action of the ethyl alcohol, MoO₃Re-dissolving and re-crystallizing nano wire to obtain MoO₂In a one-dimensional structure of MoO₃A layer of rough MoO is formed on the surface₂Layer, MoO of one-dimensional structure during long-term reaction₃Can be completely converted into coarse MoO₂. 3. When the substrate plate is placed on the surface of the solution, the substrate plate can float on the liquid surface due to the density of the substrate plate is close to that of the diluted solution and the tension between the substrate plate and the liquid surface, and because the lattice matching degree between the coating and molybdenum oxide is poor, the substrate plate can only perform crystal growth on the surface of the substrate plate and cannot grow into the coating, a layer of compact molybdenum oxide film is formed on the substrate plate, molybdenum oxide particles gradually crystallize downwards along the film under the action of gravity, and MoO with a one-dimensional structure is formed in the vertical direction₃Array of wherein MoO₃The surface is reduced by ethanol to generate MoO₂Form MoO₂-MoO₃An array; by introducing a substrate plate, MoO is accelerated₃And the precursor solution is subjected to crystallization growth speed and fineness in the vertical direction on the surface of the substrate plate.

In order to facilitate understanding of the technical scheme and the design idea, the applicant designs the following scheme for verification and explanation.

Example 1

A preparation method of molybdenum oxide with a one-dimensional nanostructure comprises the following steps:

s1, slowly adding 4g of high-purity molybdenum powder into the mixture by 4 timesTo 30g of H₂O₂And 68g of purified water, and fully stirring for 3 hours at normal temperature to form an orange precursor solution;

s2, adding absolute ethyl alcohol accounting for 5% of the mass of the precursor solution into the orange precursor solution, and stirring at constant temperature for 2 hours;

s3, adding the precursor mixed solution into a sealed reaction kettle, heating at 200 ℃ for 48 hours to obtain black MoO after the reaction is finished₂- MoO₃Suspending liquid;

s4, filtering, washing and drying to obtain MoO₂-MoO₃A one-dimensional nanomaterial.

Wherein, the reaction kettle shell in the steps S1 and S3 is made of high temperature and high pressure resistant closed stainless steel, and the inner layer is embedded with a layer of closed polytetrafluoroethylene material to make a protective layer. In the step S1, a temperature measuring step is further included, in which a temperature measuring device is provided in the reaction vessel for measuring the temperature of the reaction system; after adding the molybdenum powder once, sampling once, and detecting the absorbance of the orange solution by using a spectrophotometric agent.

The specific steps of filtering, washing and drying are as follows:

step S401: solid MoO on filter paper₂- MoO₃The one-dimensional nano material is transferred into a beaker, and absolute ethyl alcohol washing liquid is sprayed to the solid MoO coagulated into blocks from a spray head at a high speed₂- MoO₃Scattering the one-dimensional nano material into particles;

step S402: slightly stirring for 15min to make solid MoO₂- MoO₃One-dimensional nano material and absolute ethyl alcohol washing liquid form uniformly distributed heterogeneous dispersion liquid, and then the dispersion liquid is filtered and separated to obtain solid MoO₂- MoO₃A one-dimensional nanomaterial filter cake;

step S403: repeating the first step and the second step 2 times; replacing the absolute ethyl alcohol washing solution with distilled water, and continuously repeating the first step and the second step for 3 times;

step S404: dry solid MoO₂- MoO₃A one-dimensional nanomaterial filter cake; by natural windAnd (5) drying.

The RNA nucleic acid biological probe is prepared by adopting the one-dimensional nano material, and the specific synthetic steps are as follows:

the method comprises the following steps: the synthesized MoO₂-MoO₃Soaking the one-dimensional nano material in 0.01mol/L isobutyl triethoxy silicon solution for 2 hours, washing with ionized water, and drying; then continuously soaking in 2.5% glutaraldehyde water solution for 2h, washing with phosphate buffer solution, and drying;

step two: with functionalized MoO₂-MoO₃One-dimensional nano material is used as a substrate, probe RNA with the concentration of 40umol/L is dripped into MoO by a micropipette₂-MoO₃Standing the surface of the one-dimensional nano material for 2 hours at the constant temperature of 36.5 ℃, and then adding MoO₂-MoO₃Soaking the one-dimensional nano material in 3mol/L Ethanolamine (EA) solution, standing for 2h at the constant temperature of 36.5 ℃, and finally washing the unconjugated probe RNA by PBS.

Example 2

The present embodiment is different from embodiment 1 in that step S3: heating at 200 deg.C for 120 h. The rest of the procedure was the same as in example 1.

Example 3

The present embodiment is different from embodiment 1 in that step S2: adding absolute ethyl alcohol accounting for 15% of the mass of the precursor solution into the orange precursor solution, and stirring for 2 hours at constant temperature; the rest of the procedure was the same as in example 1.

Example 4

The present embodiment differs from embodiment 1 in that step S2 is not performed; the rest of the procedure was the same as in example 1.

Example 5

The present embodiment is different from embodiment 1 in that in step S3: diluting/purifying the orange precursor solution to a water solution with the mass concentration of 0.5mol/L, then thoroughly cleaning and drying the surfaces of a plurality of substrate plates, stably placing the substrate plates on the liquid level of the diluted solution, finally adjusting the temperature of the reaction kettle, and heating for 24 hours at the temperature of 40 ℃. Wherein the substrate plate has an area of 1 × 1cm²Mainly hollow simple substance siliconA bulk, and the average density of the bulk is 1 g/ml; a600 nm copper plating layer is plated on the surface of the simple substance silicon. The rest of the procedure was the same as in example 1.

Example 6

The difference between this example and example 1 is that an RNA nucleic acid biological probe is prepared by using a porous silicon nanomaterial, and the specific steps are as follows:

the method comprises the following steps: soaking the synthesized porous silicon nano material in 0.01mol/L isobutyl triethoxy silicon solution for 2h, washing with ionized water, and drying; then continuously soaking in 2.5% glutaraldehyde water solution for 2h, washing with phosphate buffer solution, and drying;

step two: taking a functionalized porous silicon nano material as a substrate, dropwise adding probe RNA with the concentration of 40umol/L on the surface of the porous silicon nano material by using a micropipette, standing for 2 hours at the constant temperature of 36.5 ℃, then soaking the porous silicon nano material in 3mol/L Ethanolamine (EA) solution, standing for 2 hours at the constant temperature of 36.5 ℃, and finally washing the unconjugated probe RNA by using PBS.

Dripping 40uL of complementary peptide chain with the concentration of 0.20 to 70.00umol/L onto the RNA biological probe by using a micropipette, then placing the sample in a 37 ℃ thermostat for 1h to ensure that sufficient specific reaction occurs, washing the sample by using normal saline after the reaction is finished to remove unreacted complementary DNA, and drying the sample in nitrogen; and then testing the reflection spectrum of each sample between 800nm and 2000nm, analyzing the reflection spectrum, and calculating the corresponding red shift amount to obtain the attached figures 2-3. From FIG. 2, it can be seen that the red shift of the reflectance spectrum is linear with the concentration of complementary DNA, wherein the slope of the linear equation is the sensitivity of the RNA biological probe, and the detection limit formula is: detection limit = instrument minimum resolution/sensitivity of sensor, where the minimum resolution of the uv spectrophotometer employed in this embodiment is 0.01 nm.

In the present invention, from the X-ray diffraction (XRD) data of the molybdenum oxide sample, it can be seen that: molybdenum oxide obtained in example 1 contains MoO as a main component₂-MoO₃Composition having an inner layer structure of MoO₃The surface layer is MoO₂(ii) a Example 2E3 the main component of the obtained molybdenum oxide is MoO₂One-dimensional, linear structures have been destroyed and cannot become substrates for biological probes; molybdenum oxide obtained in example 4 contains MoO as a main component₃. The data of RNA detection limit and sensitivity of the RNA nucleic acid bioprobe samples obtained in comparative example 1 and examples 4 to 6 are preferably the data of example 5.

It should be noted that the various features described in the above embodiments may be combined in any suitable manner without departing from the scope of the invention. The invention is not described in detail in order to avoid unnecessary repetition.

Claims (8)

1. The application of one-dimensional nanostructured molybdenum oxide is characterized by comprising the following steps:

the preparation method of the molybdenum oxide with the one-dimensional nano structure comprises the following steps:

s1, slowly adding 4g of high-purity molybdenum powder into 30-40 g of H for 4-8 times₂O₂And 58-68 g of purified water, and fully stirring for 3-5 h at normal temperature to form an orange precursor solution;

s2, adding absolute ethyl alcohol with the mass being 5-15% of that of the precursor solution into the orange precursor solution, and stirring for 2-3 h at constant temperature;

s3, adding the precursor mixed solution into a sealed reaction kettle, putting the reaction kettle into a constant-temperature heating box, heating for 48-96 hours at the temperature of 100-200 ℃, and obtaining black MoO after the reaction is finished₂- MoO₃Suspending liquid;

s4, filtering, washing and drying to obtain MoO₂-MoO₃A one-dimensional nanomaterial;

the molybdenum oxide with the one-dimensional nano structure prepared based on the preparation method is used as a substrate for manufacturing various biological probes, and the application method comprises the following steps:

the method comprises the following steps: the synthesized MoO₂-MoO₃Soaking the one-dimensional nano material in 0.01mol/L isobutyl triethoxy silicon solution for 2 hours, washing with ionized water, and drying; then continuously soaking in 2.5% of pentaneAdding dialdehyde water solution for 2h, washing with phosphate buffer solution, and drying;

step two: with functionalized MoO₂-MoO₃One-dimensional nano material is used as a substrate, probe RNA with the concentration of 40umol/L is dripped into MoO by a micropipette₂-MoO₃Standing the surface of the one-dimensional nano material for 2 hours at the constant temperature of 36.5 ℃, and then adding MoO₂-MoO₃Soaking the one-dimensional nano material in 3mol/L ethanolamine solution, standing for 2h at the constant temperature of 36.5 ℃, and finally washing the uncoupled probe RNA by PBS.

2. Use of one-dimensional nanostructured molybdenum oxide according to claim 1, characterized in that said H is₂O₂Is an oxidation source and has the mass fraction of 30 to 100 percent.

3. The use of one-dimensional nanostructured molybdenum oxide according to claim 1, wherein in step S1, the molybdenum powder is mixed with H₂O₂The molar concentration ratio of (1): (25-30).

4. The use of the one-dimensional nanostructured molybdenum oxide according to claim 1, wherein the reactor shell in the steps S1 and S3 is made of high temperature and high pressure resistant closed stainless steel, and the inner layer is embedded with a protective layer made of a closed polytetrafluoroethylene material.

5. The use of one-dimensional nanostructured molybdenum oxide according to claim 1, wherein said step S1 further comprises a temperature measuring step, wherein a temperature measuring device is disposed in the reaction vessel for measuring the temperature of the reaction system; and detecting the absorbance in the orange solution by using a spectrophotometric agent, and calculating the concentration of the precursor solution.

6. The use of one-dimensional nanostructured molybdenum oxide according to claim 1, wherein said step S2 is further comprising: diluting the orange solution to a water solution with the mass concentration of 0.05g/ml, adding the diluted orange solution into a transparent glass container, then thoroughly cleaning and drying the surface of the substrate plate, stably placing the substrate plate on the liquid surface of the diluted solution, sealing the glass container, finally placing the sealed glass container into an oven, and heating for 6-24 hours at the temperature of 40-60 ℃.

7. The use of one-dimensional nanostructured molybdenum oxide according to claim 6, wherein the substrate plate has an area of 1 x 1cm²Hollow simple substance silicon is used as a main body, and the average density of the whole body is 1.1 g/ml; and a 600-900 nm silicon dioxide coating is plated on the surface of the simple substance silicon.

8. The use of the one-dimensional nanostructured molybdenum oxide according to claim 1, wherein in the step S3, the processes of filtering, washing and drying are specifically:

the method comprises the following steps: solid MoO on filter paper₂-MoO₃The one-dimensional nano material is transferred into a beaker, and absolute ethyl alcohol washing liquid is sprayed to the solid MoO coagulated into blocks from a spray head at a high speed₂-MoO₃Scattering the one-dimensional nano material into particles;

step two: slightly stirring for 10-15 min to enable solid MoO₂-MoO₃One-dimensional nano material and absolute ethyl alcohol washing liquid form uniformly distributed heterogeneous dispersion liquid, and then the dispersion liquid is filtered and separated to obtain solid MoO₂-MoO₃A one-dimensional nanomaterial filter cake;

step three: repeating the first step and the second step for 1-2 times; replacing the absolute ethyl alcohol washing liquid with distilled water, and continuously repeating the first step and the second step for 2-3 times;

step four: drying solid MoO by natural air drying₂-MoO₃And (3) a one-dimensional nano material filter cake.

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