CN111610240A

CN111610240A - Photoelectric biosensor constructed based on cathode photoelectrode

Info

Publication number: CN111610240A
Application number: CN202010497179.1A
Authority: CN
Inventors: 沈清明; 唐雪莹; 李美星; 范曲立
Original assignee: Nanjing University of Posts and Telecommunications
Current assignee: Nanjing University of Posts and Telecommunications
Priority date: 2020-06-04
Filing date: 2020-06-04
Publication date: 2020-09-01
Anticipated expiration: 2040-06-04
Also published as: CN111610240B

Abstract

The invention discloses a photoelectric biosensor constructed based on a cathode photoelectrode, which comprises Cu_xO NPs electrodes, Cu_xPTZ-CdSe QDs are modified on the surface of an electrode of the O NPs electrode, and under the irradiation of light, the CdSe QDs absorb energy, are subjected to electron-hole separation, and photo-generated electrons are transferred from VB of the CdSe QDs to CB and are finally captured by oxygen dissolved in a solution; holes separated from the CdSe QDs are transferred from VB to the HOMO energy level of PTZ and then transferred from the HOMO energy level of PTZ to VB of CuxO NPs; in addition, the LUMO energy level of PTZ is far higher than the CB energy level of CdSe QD, so that the effect of preventing electron backflow is achieved, the strength and the stability of cathode photoelectric signals can be improved, and the dryness of reducing substances to a cathode photoelectric sensor is reducedAnd the cathode photoelectrode has higher stability and sensitivity.

Description

Photoelectric biosensor constructed based on cathode photoelectrode

Technical Field

The invention relates to preparation of a cathode photoelectrode and application of photoelectric sensing, in particular to construction of a novel cathode photoelectrode, which has high photocurrent and stability and can be developed as a photoelectric sensor.

Background

In the last decade, the development of the photoelectric chemical sensor is rapid, the stability of the electrode is greatly improved, and the detection sensitivity is also greatly improved. The strength of the response signal of a photoelectric chemical sensor depends to a large extent on the formation of excitons within the electrode, the key process of which is the separation of electron-hole pairs. Methods for improving exciton transport efficiency are mainly used for constructing metal ion doped semiconductor materials or constructing semiconductor heterostructures, and few researchers choose to introduce functional substances, and combine the methods. Therefore, there is still much room for research and development in constructing electrodes combining functional materials with semiconductor heterostructures.

Disclosure of Invention

The purpose of the invention is as follows: in order to overcome the defects in the prior art, the invention provides a cathode photoelectrode and a preparation method thereof, wherein the cathode photoelectrode is made of Cu_xO NPs and PTZ modified CdSe QDs, composite compositions, wherein PTZ promotes semiconductor materials CdSe QDs and Cu_xAnd holes among the O NPs are transferred, the recombination of electron-hole pairs is prevented, and the strength and the stability of cathode photoelectric signals are improved.

The technical scheme is as follows: in order to achieve the purpose, the invention adopts the technical scheme that:

a cathode photoelectrode comprising Cu_xO NPs electrodes, Cu_xThe electrode surface of the O NPs electrode is modified with PTZ-CdSeQDs.

The invention promotes Cu by introducing PTZ into the electrode material_xHole transfer between O NPs and CdSe QDs, and blocking the recombination of electron-hole pairs. The generation method of the photoelectric signal is as follows: under light irradiation, the CdSe QDs absorb energy, undergo electron-hole separation, and photogenerated electrons are transferred from VB of the CdSe QDs to CB and are finally captured by oxygen dissolved in a solution. Holes separated by the CdSe QDs are transferred from VB to the HOMO level of PTZ, and then from the HOMO level of PTZ to VB of CuxO NPs. In addition, the LUMO level of PTZ is much higher than the CB level of CdSe QD (the LUMO level of PTZ is at least 1.5V greater than that of CdSe QD), which acts as a blockThe effect of electron reflux, therefore, PTZ promotes the semiconductor materials CdSe QDs and Cu_xAnd the hole transfer among the O NPs prevents the recombination of electron-hole pairs, improves the strength and stability of cathode photoelectric signals, and reduces the interference of reducing substances on the cathode photoelectric sensor.

A preparation method of a cathode photoelectrode comprises the following steps:

step 1, synthesizing TGA-CdSe QDs: : mixing Se powder with NaBH₄Adding the solution into a container, stirring until the solution is in a clear, transparent and colorless state, and synthesizing a precursor NaHSe. Adding CdCl₂And adding the solution and the TGA into another container to obtain a second solution, adjusting the pH value of the second solution to 10, adding a precursor NaHSe into the second solution, and refluxing at 100 ℃ to synthesize the TGA-CdSe QDs.

Step 2, TGA-CdSe QDs aggregation purification: the TGA-CdSe QDs obtained in step 1 were purified by aggregation with hydrochloric acid overnight, and after centrifugation, the supernatant was aspirated off, and the lower precipitate was retained.

Step 3, synthesis of PTZ-CdSe QDs: and (3) dissolving the precipitate obtained in the step (2) in a phenothiazine-ethanol solution, and continuously stirring until the precipitate is completely dissolved to synthesize PTZ-CdSe QDs.

Step 4, preparing a Cu film: two cleaned FTO electrodes were placed in opposition in a saturated copper sulfate solution and then at 100mVs^-1The scanning speed of the electrode is in the range of 0.0-4.0V, 20-40 sections are scanned, the copper film is obtained through electrochemical deposition, the electrode is quickly washed in ultrapure water, and residual CuSO is removed₄And obtaining the electrode with the copper film.

Step 5, Cu_xPreparing an O NPs photocathode electrode: annealing the electrode with the copper film obtained in step 4 to form Cu_xO NPs electrodes.

Step 6, PTZ-CdSe QDs/Cu_xPreparing an O NPs/FTO electrode: cu obtained in the step 5_xAnd (3) soaking the O NPs electrode into the PTZ-CdSe QDs obtained in the step (3) at 4 ℃ for 1-3 hours, and then washing the O NPs electrode with ultrapure water.

Preferably: in the step 2, the centrifugation speed is 3000-5000 rpm, and the centrifugation time is 5.0-10.0 min.

Preferably: in the step 3, the concentration of the phenothiazine-ethanol solution is 0.8-1.0 mg/mL, and the volume is 10-15 mL.

Preferably: in the step 5, the annealing temperature is 450-500 ℃, and the annealing time is 4-5 hours.

A photoelectric biosensor based on cathode photoelectrode comprises PTZ-CdSe QDs/Cu_xO NPs/FTO electrodes, said PTZ-CdSe QDs/Cu_xThe surface of the O NPs/FTO electrode is provided with a SOx modification layer.

A preparation method of photoelectric biosensor based on cathode photoelectrode comprises preparing PTZ-CdSe QDs/Cu_xThe ONPs/FTO electrodes were sequentially immersed in a 2% PDDA solution and a SOx solution to modify SOx to PTZ-CdSe QDs/Cu_xO NPs/FTO electrode, wherein the 2% PDDA solution contains 0.5M NaCl.

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

the invention promotes semiconductor materials CdSe QDs and Cu by PTZ_xAnd the hole transfer between the O NPs improves the strength and stability of cathode photoelectric signals and improves the photoelectric performance of the cathode photoelectric sensor. Therefore, the cathode photoelectrode can improve the strength and stability of cathode photoelectric signals, reduce the interference of reducing substances on the cathode photoelectric sensor and enable the cathode photoelectrode to have higher stability and sensitivity.

Drawings

FIG. 1 is a TEM image of PTZ-CdSe QDs

FIG. 2 is Cu_xSEM image of O NPs

FIG. 3 is Cu_xSolid UV absorption diagram of O NPs

FIG. 4 shows bare FTO (I), Cu during assembly_xO NPs/FTO(II)，PTZ-CdSe QDs/Cu_xO NPs/FTO (III) and SO_x/PTZ-CdSe QDs/Cu_xDifferential photocurrent response of O NP/FTO (IV) electrodes

Fig. 5 is a graph of the photocurrent response to various concentrations of sarcosine from a to i: 0.001mM,0.005mM,0.01mM,0.05mM,0.1mM,0.5mM,1mM,2mM,5mM

FIG. 6 is a graph of the photocurrent response of a photoelectric biosensor with increasing sarcosine concentration, the inset being the corresponding calibration curve

FIG. 7 is a schematic diagram of cathode photoelectrode energy levels

Here, Cu_xO NPs represent copper oxide nanocones, PTZ represents phenothiazine, CdSeQDs represent cadmium selenide quantum dots, TGA represents thioglycolic acid, Se represents selenium, NaBH₄Denotes sodium borohydride, CdCl₂Represents cadmium chloride, NaOH represents sodium hydroxide, NaHSe represents sodium hydroselenide, Cu represents copper, CuSO₄Represents copper sulfate, FTO represents fluorine-doped tin oxide glass, VB represents a valence band, CB represents a conduction band, HOMO represents a highest occupied molecular orbital, LUMO represents a lowest unoccupied molecular orbital, TEM represents a transmission electron microscope, SEM represents a scanning electron microscope, SOx represents Sarcosine oxidase, Ag/AgCl represents silver/silver chloride, Sarcosine represents Sarcosine, PDDA represents poly (diallyldimethylammonium chloride), NaCl represents sodium chloride, and S/N represents a signal-to-noise ratio.

Detailed Description

The present invention is further illustrated by the following description in conjunction with the accompanying drawings and the specific embodiments, it is to be understood that these examples are given solely for the purpose of illustration and are not intended as a definition of the limits of the invention, since various equivalent modifications will occur to those skilled in the art upon reading the present invention and fall within the limits of the appended claims.

Example 1:

The invention promotes Cu by introducing PTZ into the electrode material_xHole transfer between O NPs and CdSe QDs, and blocking the recombination of electron-hole pairs. The generation method of the photoelectric signal is as follows: under light irradiation, the CdSe QDs absorb energy, undergo electron-hole separation, and photogenerated electrons are transferred from VB of the CdSe QDs to CB and are finally captured by oxygen dissolved in a solution. Holes separated by the CdSe QDs are transferred from VB to the HOMO level of PTZ, and then from the HOMO level of PTZ to VB of CuxO NPs. In addition, the LUMO level of PTZ is much higher than the CB level of CdSe QD (the LUMO level of PTZ is at least 1.5V greater than that of CdSe QD), acting to prevent electron backflow, and therefore,PTZ-promoted semiconductor materials CdSe QDs and Cu_xAnd the hole transfer among the O NPs prevents the recombination of electron-hole pairs, improves the strength and stability of cathode photoelectric signals, and reduces the interference of reducing substances on the cathode photoelectric sensor.

A preparation method of a cathode photoelectrode is used for synthesizing CdSe QDs: 55.3mg Se powder and NaBH₄The solution (5.32mg/mL, 10mL) was added to a three-necked flask in sequence, and stirred until the solution became clear, transparent and colorless, to synthesize a precursor NaHSe. Adding CdCl₂The solution (0.458mg/mL, 50mL) and TGA (20 μ L) were added to another three-necked flask, and after adjusting the solution to pH 10.0 with NaOH (1M), 70 μ L NaHSe precursor was added to the solution and refluxed at 100 ℃ for 4h to synthesize TGA-CdSe QDs. The TGA-CdSe QDs obtained were purified by aggregating with HCl (1M, 10mL) overnight, centrifuging at 5000rpm, aspirating the supernatant after 5.0min, and retaining the lower precipitate. The precipitate was dissolved in a prepared PTZ-ethanol solution (0.8mg/mL, 10mL) to synthesize PTZ-CdSe QDs (see FIG. 1). In saturated CuSO₄Two cleaned FTO electrodes were placed in solution in opposition and then at 100mVs^-1Scanning at a scanning speed of 0.0-4.0V for 20 sections, electrochemically depositing to obtain Cu film, and rapidly rinsing the electrode in ultrapure water to remove residual CuSO₄. The obtained Cu film was annealed at 450 ℃ for 4 hours in a tube furnace to form Cu_xElectrodes of ONPs (see FIG. 2). As shown in FIG. 3, Cu_xThe O NPs electrode has a wide light absorption area and excellent light absorption capacity. Cu to be prepared_xAfter the O NPs electrode was immersed in PTZ-CdSe QDs at 4 ℃ for 3 hours, it was washed clean with ultrapure water for further photocurrent detection.

As shown in FIG. 7, the electrodes are made of CdSe QDs, PTZ and Cu_xThe three materials of O NPs are compounded, CB and VB of CdSe QDs are-1.6V and 1.3V respectively, HOMO of PTZ is 0.92V, and Cu_xCB and VB of O NPs are-0.8V and 0.65V, respectively. Under light irradiation, the CdSe QDs absorb energy, undergo electron-hole separation, and photogenerated electrons are transferred from VB of the CdSe QDs to CB and are finally captured by oxygen dissolved in a solution. Meanwhile, due to the existence of PTZ, holes separated from CdSe QD are transferred from VB to HOMO energy level of PTZ and then transferred from the HOMO energy level of PTZ to Cu_xVB for O NPs. In addition, the LUMO energy level of PTZ is much higher than the CB of CdSe QDs, acting to prevent electron reflux.

The cathode photoelectrode obtained in example 1 was used to construct a photoelectric biosensor, and the photoelectric biosensor was used for detecting sarcosine.

A cathode photoelectrode was prepared as in example 1. PTZ-CdSe QDs/Cu_xThe O NPs/FTO electrode was immersed in 2% PDDA (containing 0.5M NaCl) and SOx solutions for 15 minutes in order to decorate SOx onto the electrode, and this process was repeated 3 times to complete the sensor preparation for further photocurrent detection. The electrode photocurrent variation during assembly is shown in fig. 4. The sensor is used for detecting the concentration of sarcosine by adopting a three-electrode system, a platinum wire electrode is used as an auxiliary electrode, and an Ag/AgCl electrode is used as a reference electrode. The assembled electrodes were immersed in sarcosine solutions of 0.001mM,0.005mM,0.01mM,0.05mM,0.1mM,0.5mM,1mM,2mM,5mM, respectively, and the electrochemical station scanned the time-current curve to detect the change in cathode photocurrent (see FIG. 5). As shown in fig. 6, the sensor linear range is 0.001mM to 1mM, calibration curve: i (μ a) ═ 0.74552lg (Csar/mM) -4.46391 (correlation coefficient R ═ 0.9989), and the detection limit was 0.2 μ M according to S/N ═ 3.

Example 2

This example differs from example 1 in that 55mg of Se powder and NaBH are mixed₄The solution (5mg/mL, 11mL) was added to a three-necked flask in sequence, and stirred until the solution became clear, transparent and colorless, to synthesize a precursor NaHSe. Adding CdCl₂Solution (0.4mg/mL, 60mL) and TGA (19 μ L) were added to another three-necked flask, and after adjusting the solution to pH 10.0 with NaOH (0.9M), 68 μ L NaHSe precursor was added to the solution and refluxed at 95 ℃ for 5h to synthesize TGA-CdSe QDs. The TGA-CdSe QDs obtained were purified by aggregating with HCl (0.9M, 11mL) overnight, centrifuging at 3000rpm, aspirating the supernatant after 10.0min, and retaining the lower precipitate. The precipitate was dissolved in a prepared PTZ-ethanol solution (0.7mg/mL, 11mL) to synthesize PTZ-CdSe QDs (see FIG. 1). In saturated CuSO₄Two cleaned FTO electrodes were placed in solution in opposition and then at 99mVs^-1The scanning speed of the device is in the range of 0.0-4.0V for 40 sections, the Cu film is obtained by electrochemical deposition, and the device is fast in ultra-pure waterRapidly rinsing the electrode to remove residual CuSO₄. The obtained Cu film was annealed at 480 ℃ for 4.5 hours in a tube furnace to form Cu_xO NPs electrodes (see fig. 2). As shown in FIG. 3, Cu_xThe O NPs electrode has a wide light absorption area and excellent light absorption capacity. Cu to be prepared_xAfter the O NPs electrode was immersed in PTZ-CdSe QDs at 3 ℃ for 4 hours, it was washed clean with ultrapure water for further photocurrent detection.

Example 3

This example differs from examples 1 and 2 in that 56mg of Se powder and NaBH are mixed₄The solution (6mg/mL, 9mL) was added to a three-necked flask in sequence, and stirred until the solution became clear, transparent and colorless, to synthesize a precursor NaHSe. Adding CdCl₂Solution (0.5mg/mL, 45mL) and TGA (21 μ L) were added to another three-necked flask, and after adjusting the solution to pH 10.0 with NaOH (1.1M), 71 μ L NaHSe precursor was added to the solution and refluxed at 110 ℃ for 3.9h to synthesize TGA-CdSe QDs. The TGA-CdSe QDs obtained were purified by aggregating with HCl (1.1M, 9mL) overnight, centrifuging at 4500rpm, aspirating the supernatant after 8min, and retaining the lower precipitate. The precipitate was dissolved in a prepared PTZ-ethanol solution (0.9mg/mL, 9mL) to synthesize PTZ-CdSe QDs (see FIG. 1). In saturated CuSO₄Two cleaned FTO electrodes were placed in solution in opposition and then at 100mVs^-1Scanning at a scanning speed of 0.0-4.0V for 30 segments, electrochemically depositing to obtain Cu film, and rapidly rinsing the electrode in ultrapure water to remove residual CuSO₄. The obtained Cu film was annealed at 500 ℃ for 5 hours in a tube furnace to form Cu_xO NPs electrodes (see fig. 2). As shown in FIG. 3, Cu_xThe O NPs electrode has a wide light absorption area and excellent light absorption capacity. Cu to be prepared_xAfter the O NPs electrodes were immersed in PTZ-CdSe QDs at 5 ℃ for 2.5 hours, they were washed clean with ultrapure water for further photocurrent detection.

The above description is only of the preferred embodiments of the present invention, and it should be noted that: it will be apparent to those skilled in the art that various modifications and adaptations can be made without departing from the principles of the invention and these are intended to be within the scope of the invention.

Claims

1. A cathode photoelectrode characterized by comprising Cu_xO NPs electrodes, Cu_xThe electrode surface of the O NPs electrode is modified with PTZ-CdSe QDs.

2. The cathode photoelectrode of claim 1 wherein the photoelectric signal is generated by: under the irradiation of light, the CdSe QDs absorb energy, the electron-hole separation is carried out, and photo-generated electrons are transferred from VB of the CdSe QDs to CB and are finally captured by oxygen dissolved in the solution; holes separated from the CdSe QDs are transferred from VB to the HOMO energy level of PTZ and then transferred from the HOMO energy level of PTZ to VB of CuxO NPs; in addition, the LUMO level of PTZ is much higher than the CB level of CdSe QD, acting to prevent electron reflux.

3. A preparation method of a cathode photoelectrode is characterized by comprising the following steps:

step 1, synthesizing TGA-CdSe QDs: : mixing Se powder with NaBH₄Adding the solution into a container, stirring until the solution is in a clear, transparent and colorless state, and synthesizing a precursor NaHSe; adding CdCl₂Adding the solution and TGA into another container to obtain a second solution, adjusting the pH value of the second solution to 10, adding a precursor NaHSe into the second solution, refluxing at 100 ℃, and synthesizing TGA-CdSe QDs;

step 2, TGA-CdSe QDs aggregation purification: aggregating and purifying the TGA-CdSe QDs obtained in the step 1 by hydrochloric acid overnight, centrifuging, sucking out supernatant, and keeping lower-layer precipitates;

step 3, synthesis of PTZ-CdSe QDs: dissolving the precipitate obtained in the step 2 in a phenothiazine-ethanol solution, continuously stirring until the precipitate is completely dissolved, and synthesizing PTZ-CdSe QDs;

step 4, preparing a Cu film: two cleaned FTO electrodes were placed in opposition in a saturated copper sulfate solution and then at 100mVs^-1The scanning speed of the electrode is in the range of 0.0-4.0V, 20-40 sections are scanned, the copper film is obtained through electrochemical deposition, the electrode is quickly washed in ultrapure water, and residual CuSO is removed₄Obtaining an electrode with a copper film;

step 5, Cu_xPreparing an O NPs photocathode electrode: annealing the electrode with the copper film obtained in step 4 to form Cu_xAn O NPs electrode;

4. The method for producing a cathode photoelectrode according to claim 3, characterized in that: in the step 2, the centrifugation speed is 3000-5000 rpm, and the centrifugation time is 5.0-10.0 min.

5. The method for producing a cathode photoelectrode according to claim 4, characterized in that: in the step 3, the concentration of the phenothiazine-ethanol solution is 0.8-1.0 mg/mL, and the volume is 10-15 mL.

6. The method for producing a cathode photoelectrode according to claim 5, characterized in that: in the step 5, the annealing temperature is 450-500 ℃, and the annealing time is 4-5 hours.

7. A photoelectric biosensor constructed based on a cathode photoelectrode is characterized in that: comprising PTZ-CdSe QDs/Cu prepared according to claim 3_xO NPs/FTO electrodes, said PTZ-CdSe QDs/Cu_xThe surface of the O NPs/FTO electrode is provided with a SOx modification layer.

8. A preparation method of a photoelectric biosensor constructed based on a cathode photoelectrode is characterized by comprising the following steps: PTZ-CdSe QDs/Cu prepared according to claim 3_xThe O NPs/FTO electrode is sequentially immersed into a 2% PDDA solution and a SOx solution to modify SOx into PTZ-CdSe QDs/Cu_xO NPs/FTO electrode, wherein the 2% PDDA solution contains 0.5M NaCl.