CN113155933A

CN113155933A - Graphene-molybdenum trioxide-based all-solid-state potassium ion selective electrode and preparation method and application thereof

Info

Publication number: CN113155933A
Application number: CN202110459263.9A
Authority: CN
Inventors: 牛利; 邱世平; 甘世宇; 钟丽杰
Original assignee: Guangzhou University
Current assignee: Guangzhou University
Priority date: 2021-04-27
Filing date: 2021-04-27
Publication date: 2021-07-23
Anticipated expiration: 2041-04-27
Also published as: CN113155933B

Abstract

The invention discloses an all-solid-state potassium ion selective electrode based on graphene-molybdenum trioxide and a preparation method and application thereof. According to the invention, the graphene-molybdenum trioxide nano composite material is used for constructing the all-solid-state potassium ion selective electrode, and the high surface area, high conductivity and high hydrophobicity of the reduced graphene oxide are combined with the high redox capacitance of the molybdenum trioxide, so that the transduction layer of the all-solid-state potassium ion selective electrode has an electric double layer, a redox capacitance, strong conductivity and hydrophobicity, the formation of an electrode water layer is effectively prevented, and the all-solid-state potassium ion selective electrode has good response and excellent potential stability to potassium ions.

Description

Graphene-molybdenum trioxide-based all-solid-state potassium ion selective electrode and preparation method and application thereof

Technical Field

The invention relates to the technical field of ion selective electrodes, in particular to a graphene-molybdenum trioxide based all-solid-state potassium ion selective electrode and a preparation method and application thereof.

Background

In recent years, with the rise of wearable sensors, research on all-solid-state ion-selective electrode transduction layer materials is also one of the most active subjects in the field of potentiometric sensors. The literature reports that conductive polymers with larger redox capacitance, such as polypyrrole, polythiophene, polyaniline and the like, as the transduction layer can enable the all-solid-state ion selective electrode to have higher capacitance, but light and oxygen are used as the transduction layer₂And CO₂And a water layer, etc., easily affect the stability of the potential. The carbon-based nano material such as the carbon nano tube, the graphene, the fullerene and the like can be used as a novel solid transduction layer to be applied to a transduction layer of an all-solid-state ion selective electrode, and has good anti-interference performance, relatively low capacitance and relatively large potential drift. Therefore, the development of new transduction layer materials is the focus of current all-solid-state ion selective electrode research.

MoO₃The material has important application in the fields of water pollution treatment, electrochemistry, photoelectric devices and the like. In addition, the organism and the ecosystem have strong self-regulation and internal stabilization mechanisms on the molybdenum-based material, so that MoO (molybdenum oxide) is generated₃Is of great interest to researchers. MoO₃The pseudocapacitance electrode material has the characteristics of low price, simple synthesis method, high theoretical capacity (2700F/g) and the like, and has great potential. But as a transition metal oxide, MoO₃Has poor conductivity and has the phenomena of dissolution and structural variation in the electrochemical reaction process, so that MoO reported in the literature at present₃Are all much lower than their theoretical capacity. Graphene has excellent electrochemical properties such as good conductivity, stable structure, strong anti-interference performance and the like, but due to the irreversible agglomeration phenomenon in the preparation process, documents report that the mass specific capacitance of the graphene used as an all-solid-state ion selective electrode is 100F/g, and the long-term stability of the potential is poor due to the low capacitance.

Disclosure of Invention

The present invention is directed to solving at least one of the problems of the prior art. Therefore, the invention provides an all-solid-state potassium ion selective electrode based on graphene-molybdenum trioxide, which has good response to potassium ions and excellent potential stability.

Meanwhile, the invention also provides a preparation method and application of the all-solid-state potassium ion selective electrode.

Specifically, the invention adopts the following technical scheme:

the invention provides an all-solid-state potassium ion selective electrode, which comprises a substrate, a transduction layer arranged on the surface of the substrate, and a potassium ion selective film covering the surface of the transduction layer, wherein the transduction layer comprises a graphene-molybdenum trioxide nanocomposite material.

The all-solid-state potassium ion selective electrode according to the first aspect of the invention has at least the following beneficial effects:

according to the invention, the graphene-molybdenum trioxide nano composite material is used as a transfer layer of the all-solid-state potassium ion selective electrode for the first time, and the high surface area, high conductivity and high hydrophobicity of the reduced graphene oxide are combined with the high redox capacitance of the molybdenum trioxide, so that the problem of potential drift of the graphene material is greatly improved.

In some embodiments of the invention, the graphene-molybdenum trioxide nanocomposite material is loaded in the all-solid-state potassium ion selective electrode in an amount of 0.5-2 mg/cm²。

In some embodiments of the present invention, the graphene-molybdenum trioxide nanocomposite contains reduced graphene oxide and molybdenum trioxide, and the mass ratio of the molybdenum trioxide to the reduced graphene oxide is 1: 0.5 to 2, preferably 1: 1 to 1.5.

In some embodiments of the invention, the loading amount of the potassium ion selective membrane in the all-solid-state potassium ion selective electrode is 15-25 mg/cm²。

In some embodiments of the present invention, the raw materials for preparing the potassium ion selective membrane include: potassium ion carrier, high molecular polymer, plasticizer and lipophilic macromolecule.

In some embodiments of the present invention, the mass ratio of the ionophore, the high molecular polymer, the plasticizer and the lipophilic macromolecule is 1-4: 50-100: 100-200: 1.

in some embodiments of the invention, the potassium ionophore comprises valinomycin.

In some embodiments of the present invention, the high molecular polymer includes any one or more of polyvinyl chloride (PVC), polyvinyl acetate, and polymethyl methacrylate.

In some embodiments of the invention, the plasticizer comprises any one or more of diisooctyl sebacate (DOS), 2-nitrophenyloctyl ether, bis (2-ethylhexyl) sebacate.

In some embodiments of the invention, the lipophilic macromolecule comprises any one or more of potassium tetrakis (4-chlorophenyl) borate (KTClPB), potassium tetrakis (pentafluorophenyl) borate (KTPFB), sodium tetraphenylborate.

In some embodiments of the present invention, the substrate may be an electrode substrate commonly used in the art, such as glassy carbon, copper, and the like.

The second aspect of the present invention provides a preparation method of the above all-solid-state potassium ion selective electrode, comprising the following steps:

coating the slurry containing the graphene-molybdenum trioxide nanocomposite on the surface of a substrate, and drying to form a transfer layer; and preparing a potassium ion selective membrane on the surface of the transfer layer.

In some embodiments of the present invention, the graphene-molybdenum trioxide nanocomposite is prepared by a method comprising: and mixing a molybdenum source with graphene oxide, and carrying out hydrothermal reaction to obtain the graphene-molybdenum trioxide nano composite material.

In some embodiments of the invention, the temperature of the hydrothermal reaction is 150 to 200 ℃; the time of the hydrothermal reaction is 5-15 h.

In some embodiments of the invention, the molybdenum source comprises any one or more of molybdenum trioxide, ammonium molybdate, sodium molybdate, potassium molybdate, or other molybdates.

In some embodiments of the present invention, the mass ratio of molybdenum trioxide to graphene oxide is 1: 0.5 to 2, preferably 1: 1 to 1.5.

In some embodiments of the present invention, the concentration of the graphene oxide in the reaction system of the hydrothermal reaction is 2-5 mg/ml.

In some embodiments of the present invention, the raw materials for preparing the slurry comprise a graphene-molybdenum trioxide nanocomposite, a binder, a slurry solvent; the mass ratio of the graphene-molybdenum trioxide nanocomposite to the binder is 1: 0.1-0.5, wherein the concentration of the graphene-niobium pentoxide nanocomposite and the binder in the slurry is 10-30 mg/ml. The binder and the slurry solvent may employ binders and solvents commonly used in the art, and the binder includes any one or more of polyvinylidene fluoride resin (PVDF), Styrene Butadiene Rubber (SBR), carboxymethyl cellulose (CMC), polyacrylic acid (PAA), Polyacrylonitrile (PAN), and polyacrylate, as examples; the dispersing agent comprises any one or more of N-methyl pyrrolidone (NMP), ethanol, acetone and ethyl acetate.

In some embodiments of the present invention, the potassium ion selective membrane is prepared by dissolving a potassium ion carrier, a high molecular polymer, a plasticizer and a lipophilic macromolecule in a solvent to obtain a potassium ion selective membrane solution, coating the potassium ion selective membrane solution on the surface of the transduction layer, and drying to form the potassium ion selective membrane. In the potassium ion selective membrane solution, the total concentration of a potassium ion carrier, a high molecular polymer, a plasticizer and a lipophilic macromolecule is 80-150 mg/ml; the solvent can be selected from common solvents, such as Tetrahydrofuran (THF), cyclohexanone, methanol, acetonitrile, etc.

The third aspect of the invention is to provide the above all-solid-state potassium ion selective electrode for detecting K⁺The use of (1).

A fourth aspect of the invention is to provide a wearable sensor comprising the above all-solid-state potassium ion selective electrode.

Compared with the prior art, the invention has the following beneficial effects:

the invention uses the graphene-molybdenum trioxide nano composite material (rGO-MoO) for the first time₃) The method is used for constructing the all-solid-state potassium ion selective electrode, and combines the high surface area, high conductivity and high hydrophobicity of the reduced graphene oxide with the high redox capacitance of the molybdenum trioxide, so that the transduction layer of the all-solid-state potassium ion selective electrode simultaneously has an electric double layer, the redox capacitance, high conductivity and hydrophobicity, and the electrode effectively prevents the formation of an electrode water layer. The experimental result shows that rGO-MoO₃Facilitating ion-electron charge transfer between the transport layer and the ion-selective membrane. The transduction layer material is simply dripped on the surface of an electrode, so that the electrode shows good electrochemical properties, one part of the electrode has excellent performance similar to that of carbon nano tube and graphene, namely the bulk capacitance of the electrode is derived from the electric double layer capacitance of the electrode, and the other part of the electrode has redox capacitance derived from MoO loaded on the graphene₃. The response of the solid potassium ion selective electrode to potassium ions is close to the lower detection limit of Nernst response, and no water layer is formed between the transduction layer and the selective membrane interface, so that the problems of potential drift and poor potential stability are greatly improved compared with pure graphene.

Drawings

FIG. 1 is rGO-MoO₃(ii) X-ray diffraction spectrum (a) and scanning electron microscope characterization result (b)

FIG. 2 is rGO-MoO₃And cyclic voltammetry test results (a) and charge-discharge test results (b) for rGO;

FIG. 3 is rGO-MoO₃/K⁺-ISM and rGO/K⁺-a potential response (a) and a linear range curve (b) of the ISM;

FIG. 4 is rGO-MoO₃/K⁺-ISM and rGO/K⁺-water layer test results of ISM;

FIG. 5 is rGO-MoO₃/K⁺-ISM and rGO/K⁺Impedance test results of ISM.

Detailed Description

The technical solution of the present invention is further described below with reference to specific examples.

Examples

An all-solid-state potassium ion selective electrode is prepared by the following steps:

(1) pretreatment of substrate

Wiping a Glassy Carbon Electrode (GCE) with a diameter of 5mm with alcohol cotton ball, and then sequentially using 0.3 μm and 0.05 μm Al₂O₃Polishing the aqueous solution on chamois leather, then ultrasonically cleaning the electrode by ultrapure water, ethanol and ultrapure water in sequence, and blowing the electrode dry under nitrogen gas flow.

(2) Preparation of graphene-molybdenum trioxide nanocomposite (rGO-MoO)₃)

11mL of graphene oxide (GO, 12mg/mL) was mixed with 100mg of MoO₃Adding 23ml of ultrapure water, carrying out ultrasonic treatment on the mixed solution for 2 hours, pouring the mixed solution into a 50ml reaction kettle after the ultrasonic dispersion is uniform, carrying out hydrothermal reaction at 180 ℃ for 12 hours, cleaning the sample for 3 times by using the ultrapure water after the reaction is finished, and carrying out vacuum freeze drying on the product for 14 hours to obtain the rGO-MoO₃。

(3) Preparing potassium ion selective membrane solution (K)⁺-ISM)

A mixture of 82.25mg PVC (32.9 wt%), 164.3mg DOS (65.7 wt%), 2.5mg valinomycin (1 wt%), 1mg KTPFB (0.4 wt%) was dissolved in 2.5ml THF to form 100mg/ml K⁺Ion-selective membrane solution (K)⁺-ISM)。

(4) Preparation of all-solid-state potassium ion selective electrode

60mg of rGO-MoO₃And 7.5mg PVDF (i.e., rGO-MoO)₃The proportion of the mixed solution and PVDF is 8:1), then 3mL of NMP solvent is added to prepare 20mg/mL rGO-MoO₃Carrying out ultrasonic dispersion on the solution for 4 hours; taking 10 mu L of 20mg/ml rGO-MoO₃The solution was uniformly applied dropwise to GCE at a loading of 0.2mg (1 mg/cm)²) Then drying the mixture in an oven at 60 ℃ for 4 hours, and then taking out the mixture and cooling the mixture to normal temperature; mixing 40 mu L K⁺-ISM drip-coated rGO-MoO₃Covered GCE (load of 20 mg/cm)²) Air drying at room temperature to obtain all-solid potassium ion selective electrode, and recording as rGO-MoO₃/K⁺-ISM。

Comparative example

This comparative example differs from example 1 in that no MoO was added during the hydrothermal reaction₃And obtaining reduced graphene oxide (rGO) after the hydrothermal reaction is finished. The other steps are the same as in example 1.

The all-solid-state ion-selective electrode obtained in this comparative example was designated as rGO/K⁺-ISM。

Performance testing

Pairing of the above rGO-MoO by a three-electrode system using a Gamry electrochemical workstation and a multi-channel potentiometer₃/K⁺-ISM and rGO/K⁺Electrochemical testing in ISM with rGO-MoO₃/K⁺-ISM and rGO/K⁺-ISM as working electrode, platinum wire and Saturated Calomel Electrode (SCE) as counter and reference electrode, respectively.

(1) Counter-rotating conductive layer material rGO-MoO₃Structural and compositional characterization was performed as shown in figure 1. X-ray diffraction (XRD) testing showed synthetic rGO-MoO₃With pure phase MoO₃The XRD structures of (a) were identical, confirming the composition (fig. 1 a). Simultaneous Scanning Electron Microscope (SEM) display of lamellar MoO₃Uniformly attached to rGO substrate (fig. 1 b).

(2) Evaluating the transduction layers rGO and rGO-MoO by using a cyclic voltammetry test method (CV) and a charge-discharge test technology₃The size of the capacitance of (c). The scanning potential window is-0.5V in 1M Na₂SO₄CV testing in solution rGO-MoO₃The capacitance was 10mV/s, and the result is shown in FIG. 2a, where an oxidation-reduction peak derived from MoO was observed₃The redox reaction of (a) confirms the contribution of the pseudocapacitance thereof; for all solid-state ion-selective electrodes, possessing a large capacitance will contribute to the stability of the potential.

Further obtaining a charge-discharge curve under the charge-discharge current density of 1A/g by a charge-discharge testing technology, as shown in FIG. 2b, calculating rGO-MoO₃Has a capacitance of 261F/g, and a capacitance of 94F/g, rGO-MoO₃The capacitance of (2) is improved by nearly 3 times compared with rGO.

(3) Potential response test, all electrodes at 10^-4Soaking in M KCl solution for 24 hours, 10^-7The potential was measured after soaking in M KCl solution for 4 hours. Research rGO-MoO₃/K⁺-ISM and rGO/K⁺-ISM all-solid-state ion-selective electrode at 10^-7～10^-1M K⁺The potential response over the concentration range is shown in FIG. 3. From FIG. 3a it can be seen that both electrodes are paired with K⁺Exhibits a good Nernst response, the corresponding calibration curve indicates (FIG. 3b) rGO/K⁺Response sensitivity and detection limit of ISM 54.5mV/dec and 10^-5.3M，rGO-MoO₃/K⁺ISM electrode response sensitivity and detection limits of 55mV/dec and 10^-5.4M, performance slightly better than rGO/K⁺-an ISM electrode.

(4) The presence of a water layer in the electrodes was checked by a water layer test, the results of which are shown in fig. 4. As can be seen from the figure, rGO/K⁺The potential drift of the ISM is relatively large over the entire test range, and significant water layer formation is observed especially in the second and third sections, with the critical second section potential drift amounting to 2.46 mV. h^-1. And for rGO-MoO₃/K⁺ISM, in the second stage, from 0.1M KCl to 0.1M NaCl, the potential is relatively level without a significant tendency to rise, and the amount of potential drift is 0.81 mV. h^-1Relative to rGO/K⁺ISM, the amount of potential drift decreased by a factor of 3. The water layer test result shows that rGO-MoO₃The transduction layer serving as the all-solid-state potassium ion selective electrode can effectively prevent the formation of a water layer between the ion selective membrane and the conductive substrate, thereby increasing the stability of the ion selective electrode.

(5) Electrochemical impedance testing

rGO-MoO evaluation using electrochemical impedance testing₃/K⁺-ISM and rGO/K⁺Ion-electron transfer impedance of-ISM two all-solid-state ion-selective electrodes, the results are shown in fig. 5. From the figure, rGO/K can be seen⁺The charge transfer resistance of the ISM is 0.25 M.OMEGA., and rGO-MoO₃/K⁺ISM Charge-to-impedance of 0.12M Ω, ratio rGO/K⁺The impedance of the ISM electrode is reduced by half, showing faster ion-electron transport capability.

The above embodiments are preferred embodiments of the present invention, but the present invention is not limited to the above embodiments, and any other changes, modifications, substitutions, combinations, and simplifications which do not depart from the spirit and principle of the present invention should be construed as equivalents thereof, and all such changes, modifications, substitutions, combinations, and simplifications are intended to be included in the scope of the present invention.

Claims

1. An all-solid-state potassium ion selective electrode, comprising: the composite membrane comprises a substrate, a transduction layer arranged on the surface of the substrate, and a potassium ion selective membrane covering the surface of the transduction layer, wherein the transduction layer comprises a graphene-molybdenum trioxide nanocomposite.

2. The all-solid potassium ion-selective electrode of claim 1, wherein: the loading capacity of the graphene-molybdenum trioxide nano composite material in the all-solid-state potassium ion selective electrode is 0.5-2 mg/cm²。

3. The all-solid potassium ion-selective electrode of claim 2, wherein: the graphene-molybdenum trioxide nanocomposite contains reduced graphene oxide and molybdenum trioxide, and the mass ratio of the molybdenum trioxide to the reduced graphene oxide is 1: 0.5 to 2, preferably 1: 1 to 1.5.

4. The all-solid potassium ion-selective electrode of claim 1, wherein: the capacity of the potassium ion selective membrane in the all-solid-state potassium ion selective electrode is 15-25 mg/cm²。

5. The all-solid-state potassium ion selective electrode according to any one of claims 1 to 4, wherein: the preparation raw materials of the potassium ion selective membrane comprise: potassium ion carrier, high molecular polymer, plasticizer and lipophilic macromolecule.

6. The method for preparing the all-solid-state potassium ion selective electrode according to any one of claims 1 to 5, wherein the method comprises the following steps: the method comprises the following steps:

7. The method according to claim 6, wherein: the graphene-molybdenum trioxide nano composite material is prepared by the following method: and mixing a molybdenum source with graphene oxide, and carrying out hydrothermal reaction to obtain the graphene-molybdenum trioxide nano composite material.

8. The method according to claim 7, wherein: the temperature of the hydrothermal reaction is 150-200 ℃.

9. The method for detecting K by using the all-solid-state potassium ion selective electrode of any one of claims 1 to 5⁺The use of (1).

10. A wearable sensor, characterized by: the wearable sensor comprises the all-solid-state potassium ion selective electrode of any one of claims 1 to 5.