CN115386376A - Nano platinum composite material based on carbon quantum dot assembly and preparation method and application thereof - Google Patents

Nano platinum composite material based on carbon quantum dot assembly and preparation method and application thereof Download PDF

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CN115386376A
CN115386376A CN202211322156.2A CN202211322156A CN115386376A CN 115386376 A CN115386376 A CN 115386376A CN 202211322156 A CN202211322156 A CN 202211322156A CN 115386376 A CN115386376 A CN 115386376A
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刘意
李丹
冯冰洁
黄杰
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Meijianji Bioengineering Technology Guangzhou Co ltd
Guangdong Pharmaceutical University
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Guangdong Pharmaceutical University
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Abstract

The invention discloses a nano platinum composite material based on a carbon quantum dot assembly and a preparation method and application thereof. The method takes Polyethyleneimine (PEI), dopamine (DA) and carbon quantum dots containing aldehyde (CHO-CQDs) as raw materials, and forms an assembly (N/O-s-CQDs) through chemical reaction 3+ The effect can be obviousFluorescence quenching effect, high sensitivity and rapid detection of iron ion Fe in sample 3+ Concentration and the like. The nano platinum composite material (Pt @ N/O-s-CQDs) based on the carbon quantum dot assembly is prepared by reducing platinum ions in situ by using active groups in the N/O-s-CQDs. The composite material is illuminated by near infrared light with the wavelength of 808 nm, has the photo-thermal effect, and can play an application value in the antibacterial field by combining the antioxidant property of nano platinum.

Description

Nano platinum composite material based on carbon quantum dot assembly and preparation method and application thereof
Technical Field
The invention relates to the technical field of nano composite materials, in particular to a nano platinum composite material based on a carbon quantum dot assembly and a preparation method and application thereof.
Background
Fe 3+ The ions play a crucial role in various biological activities of the human body, such as oxygen transport, enzyme catalysis, DNA synthesis, electron transport, formation of free radicals in enzyme-based reactions, cell metabolism, etc., and are deficient in Fe 3+ Ions can cause many diseases such as heart failure, anemia, tissue damage, parkinson's disease, kidney and liver damage, alzheimer's disease, cancer, arthritis, diabetes, and the like. Fe 3+ There are many conventional measurement methods such as inductively coupled plasma spectrophotometry (ICPMS), colorimetry, x-ray fluorescence spectrophotometry, electrochemistry, atomic absorption/emission spectrometry, etc., however, these methods are time consuming, complicated to operate, and require expensive instruments and complicated sample pretreatment procedures.
The chemical sensor based on the nano material has excellent electronic, magnetic and optical properties, and can be used for detecting the amount of heavy metal in aqueous solution, namely Fe 3+ Have developed a variety of nanoparticle-based fluorescent probes such as metal organic frameworks, gold nanoclusters, and the like. At present, the research on nano fluorescent probes is increasing, and the Fluorescence (FL) established based on these probes draws great attention from researchers due to its advantages of excellent sensitivity, detection capability at a minute concentration, low cost, short response time, and the like. In recent years, carbon Quantum Dots (CQDs) as a new fluorescent nanoparticle have a generally spherical structure, a particle diameter of less than 10 nm, strong and stable fluorescenceCompared with organic dyes, quantum dots and precious metal nanoparticles, CQDs have excellent water solubility, good light stability, super-strong biocompatibility, low toxicity and the like, the surfaces of CQDs are complex, generally have hydroxyl, carboxyl or amino, can coordinate with metal ions to cause fluorescence change, and are often influenced by interferents in the detection process because the CQDs do not have some specifically identified groups.
In view of this, there is a need to develop a new carbon quantum dot composite material and ferric iron ion Fe thereof 3+ The application in the aspect of rapid detection.
Disclosure of Invention
The invention aims to provide a preparation method and application of a novel carbon quantum dot assembly aiming at the defects of the prior art, and the novel carbon quantum dot assembly has the advantages of rapid detection of ferric ions and high accuracy.
The technical scheme adopted by the invention for achieving the purpose is as follows:
the invention firstly prepares nano platinum composite material Pt @ N/O-s-CQDs, and concretely comprises the following steps:
1) Dissolving 30-60 mg of carbon quantum dots N/O-s-CQDs in 30 mL of pure water, and fully dissolving by ultrasonic to obtain a solution C;
2) And (3) dropwise adding 20 mL of 60-120 nM chloroplatinic acid solution into the solution C, reacting at 25-80 ℃ for 4-8 h, dialyzing the obtained solution in pure water for a certain time, performing suction filtration, freeze drying to obtain a nano platinum composite material Pt @ N/O-s-CQDs, and storing for later use.
Preferably, the dialysis treatment in step 2) is carried out in a dialysis bag of 1000/2000 Da for 12-48 h.
Wherein the preparation process of the carbon quantum dots N/O-s-CQDs in the step 1) comprises the following steps:
firstly, 0.12-0.48 g of CHO-CQDs is dissolved in 40 mL of pure water and fully dissolved by ultrasonic to obtain a solution A; dissolving 2.24-3.20 g of Polyethyleneimine (PEI) and 0.1-0.0062 g of Dopamine (DA) into 40 mL of ethanol, and performing ultrasonic full dissolution to obtain a solution B; and then dropwise adding the solution B into the solution A, reacting for 6-10 h to obtain a mixed solution, dialyzing in pure water for a certain time, and then performing suction filtration and freeze drying to obtain the carbon quantum dot N/O-s-CQDs.
Preferably, the dialysis treatment in the preparation process of the carbon quantum dot N/O-s-CQDs is carried out in a dialysis bag of 1000/2000/8000-14000 Da for 12-48 h.
The invention applies the prepared novel carbon quantum dots N/O-s-CQDs to the detection of ferric ions, and specifically comprises the following steps: dissolving the prepared novel carbon quantum dots N/O-s-CQDs in ultrapure water to prepare a solution D, and testing the fluorescence intensity of the solution D and marking the fluorescence intensity as F 0 (ii) a Then Fe of different concentrations 3+ Respectively mixing the solution with the solution D to respectively obtain corresponding mixed solutions, and performing fluorescence test to obtain fluorescence intensity values of the mixed solutions, and marking the fluorescence intensity values as F; with Fe 3+ Concentration is abscissa, fluorescence quenching rate (1-F/F) 0 ) For ordinate, linear fitting was performed to obtain the regression equation y1= k1x1+ b1, where y1 is fluorescence quenching rate and x1 is Fe 3+ The value of k1 is the slope, and the value of b1 is the intercept; to be tested contains Fe 3+ The solution is mixed with the solution D to obtain a Fe-N/O-s-CQDs mixed solution for fluorescence test, the fluorescence intensity value of the Fe-N/O-s-CQDs mixed solution is obtained, the fluorescence intensity value is substituted into a linear regression equation y1= k1x1+ b1, and Fe is obtained through calculation 3+ The concentration of (c).
Preferably, the mass concentration of the solution D is 10-20 mg/mL.
Preferably, said different concentrations of Fe 3+ Fe in solution 3+ The concentration is 10-400. Mu.M.
Compared with the prior art, the invention has the following technical advantages:
1. the invention takes Polyethyleneimine (PEI), dopamine (DA) and carbon quantum dots containing aldehyde groups (CHO-CQDs) as raw materials, forms a novel carbon quantum dot assembly (N/O-s-CQDs) through chemical reaction, introduces a high-activity functional group (such as amino) simply and greenly, takes a nano platinum composite material (Pt @ N/O-s-CQDs) of the carbon quantum dot assembly as a closed fluorescent probe, and realizes Fe on the basis of a fluorescence quenching effect 3+ High sensitivity detection, high sensitivity, good selectivity, strong anti-interference, low cost and the like, and does not need to be carried outOnly the synthetic scheme is green and environment-friendly, and the biocompatibility is better.
2. By utilizing the residual active groups in the assembly (N/O-s-CQDs), platinum ions are reduced in situ to generate nano platinum (Pt NPs) under a certain temperature condition and are relatively uniformly loaded in the assembly, and a covalent modification method is adopted to carry out chemical reaction by adding functional molecules on the groups on the surfaces of the CQDs, so that the nano platinum composite material (Pt @ N/O-s-CQDs) based on the carbon quantum dot assembly is prepared. The composite material has a potential photo-thermal effect, when the composite material is prepared into an aqueous solution with a certain concentration, the temperature can be rapidly raised within a certain time, and the composite material has a potential application value in the antibacterial field by combining the antioxidation characteristic of nano platinum, so that the synthesis scheme is green and environment-friendly, and the biocompatibility is good.
The above is an overview of the technical scheme of the invention, and the invention is further explained with reference to the accompanying drawings and the detailed description below.
Drawings
FIG. 1 is an FTIR infrared detection of N/O-s-CQDs and Pt @ N/O-s-CQDs of the present example;
FIG. 2 is a TEM image of Pt @ N/O-s-CQDs of the present example;
FIG. 3 is an HRTEM image of Pt @ N/O-s-CQDs of the present example;
FIG. 4 shows the fluorescence intensity change of N/O-s-CQDs of this example with Fe 3+ The concentration is in the range of 10-400 μ M;
FIG. 5 shows the detection of Fe by N/O-s-CQDs 3+ A schematic diagram of (a);
FIG. 6 is a diagram of detection of Fe by N/O-s-CQDs 3+ Interference immunity schematic diagram of (a);
FIG. 7 is a graph showing fluorescence intensity measured by N/O-s-CQDs.
Detailed Description
In order to make the objects, technical solutions and advantages of the present invention more apparent, the following detailed description is given with reference to the embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and do not limit the invention.
The specific implementation process of the invention is mainly divided into three steps, wherein the first step is to synthesize N/O-s-CQDsTaking Polyethyleneimine (PEI), dopamine (DA) and carbon quantum dots containing aldehyde groups (CHO-CQDs) as raw materials, and forming an assembly (N/O-s-CQDs) through chemical reaction; the second step is to prepare aqueous solution with proper concentration by N/O-s-CQDs, prepare mixed solution after adding iron ion solution with certain concentration, detect Fe by fluorescence spectrophotometry 3+ The concentration of (2).
Synthesizing a nano platinum composite material Pt @ N/O-s-CQDs, utilizing residual active groups in the assembly (N/O-s-CQDs), carrying out in-situ reduction on platinum ions at a certain temperature to generate nano platinum (Pt NPs), and relatively uniformly loading the nano platinum (Pt NPs) in the assembly to prepare the nano platinum composite material (Pt @ N/O-s-CQDs) based on the carbon quantum dot assembly;
the first step of the synthesis of the assembly (N/O-s-CQDs) is carried out by taking CHO-CQDs (0.12-0.48 g), polyethyleneimine (PEI) (2.24-3.20 g) and Dopamine (DA) (0.1-0.0062 g) as raw materials, reacting for a certain time (6-10 h) at normal temperature, purifying the obtained crude product by a dialysis bag of 1000/2000/8000-14000 Da, and freeze-drying for later use. The specific implementation process is as follows:
example 1
The preparation method of the assembly N/O-s-CQDs of the embodiment comprises the following steps:
firstly, 0.32 g of CHO-CQDs is dissolved in 40 mL of pure water, and the solution A is obtained after full ultrasonic dissolution; dissolving 2.50 g of Polyethyleneimine (PEI) and 0.025 g of Dopamine (DA) in 40 mL of ethanol, and performing ultrasonic sufficient dissolution to obtain a solution B; and then dropwise adding the solution B into the solution A, reacting for 6 h to obtain a mixed solution, transferring the mixed solution into a 2000 Da dialysis bag, dialyzing for 48 h, carrying out suction filtration by using a 0.22 mu m organic filter membrane, carrying out rotary evaporation at 60 ℃, freezing for 4 h at-60 ℃, carrying out vacuum drying for 24 h to obtain a dark brown powdery assembly (N/O-s-CQDs), and storing for later use at 2-8 ℃. Because a certain amount of DA is added into the assembly reaction system, the DA participates in the assembly reaction and can also generate self-polymerization to form an indole ring structure (shown in figure 1), and the fluorescence intensity of the correspondingly prepared N/O-s-CQDs aqueous solution is obviously stronger than that of N-s-CQDs with the same concentration. (see FIG. 7)
Example 2
The preparation of the assemblies N/O-s-CQDs of this example was carried out by changing the amount of dopamine to 0.05 g, as compared with example 1.
Example 3
The preparation of the assemblies N/O-s-CQDs of this example was carried out in the same manner as in example 1 except that the amount of CHO-CQDs was changed to 0.48 g.
Example 4
Compared with the preparation method of the assembly N/O-s-CQDs in the example 1, the reaction time is changed into 10 hours under the normal temperature condition.
Example 5
The preparation of the assemblies N/O-s-CQDs of this example was carried out by changing the dialysis time to dialysis 24 hours, as compared with example 1.
Example 6
As an application example, the method of detecting Fe by fluorescence spectrophotometer 3+ In this embodiment, the application of the prepared novel carbon quantum dots N/O-s-CQDs to the detection of ferric ions specifically includes the following steps: the novel carbon quantum dots N/O-s-CQDs prepared in example 1 were dissolved in ultrapure water to prepare a solution D having a concentration of 10 mg/mL, and 500. Mu.M of Fe 3+ Mixing the solution with the solution D to obtain a mixed solution E1, performing fluorescence test on the mixed solution E1, and recording the fluorescence intensity of the mixed solution as F 0 (ii) a Then respectively mixing 0-550 mu M Fe3+ solution with the mixed solution E1 to obtain corresponding mixed solution E, and carrying out fluorescence test to obtain the fluorescence intensity value of each mixed solution, and marking as F; with Fe 3+ Concentration as abscissa, fluorescence quenching rate (1-F/F) 0 ) For ordinate, linear fitting was performed to obtain the regression equation y1= k1x1+ b1, where y1 is fluorescence quenching rate and x1 is Fe 3+ The value of k1 is the slope, and the value of b1 is the intercept; to be tested contains Fe 3+ The solution is mixed with the solution E1 to obtain a mixed solution of Fe-Pt @ N/O-s-CQDs for fluorescence test to obtain a fluorescence intensity value of the mixed solution of Fe-Pt @ N/O-s-CQDs, the fluorescence intensity value is substituted into a linear regression equation y1= k1x1+ b1, and Fe is obtained by calculation 3+ The concentration of (c).
The third step is the synthesis of nano platinum composite material Pt @ N/O-s-CQDs, the synthetic route is that the assembly N/O-s-CQDs (30-60 mg) and chloroplatinic acid (60-120 nM) are used as raw materials, the reaction is carried out for a certain time (4-8 h) at a certain temperature (25-80 ℃), the obtained crude product is purified by a dialysis bag of 1000/2000, and then the crude product is freeze-dried for standby. The specific implementation process is as follows:
example 7
The preparation method of the nano platinum composite material Pt @ N/O-s-CQDs comprises the following steps:
1) Dissolving 30 mg of carbon quantum dots N/O-s-CQDs into 30 mL of pure water, and fully dissolving by ultrasonic to obtain a solution C;
2) Dropwise adding 20 mL of 105 nM chloroplatinic acid solution into the solution C, continuously reacting for 8 h at 80 ℃, transferring the obtained solution into a dialysis bag of 2000 Da, dialyzing for 48 h in pure water, then carrying out rotary evaporation at 80 ℃ for a certain time, freezing for 4 h at-60 ℃, and carrying out vacuum drying for 24 h to obtain the nano platinum composite material (Pt @ N/O-s-CQDs), and storing for later use at 2-8 ℃. Wherein the nano platinum is spherical, and has an average particle diameter of about several nanometers (see attached figures 2 and 3).
In this embodiment, the nano platinum composite material (pt @ N/O-s-CQDs) with unique fluorescence characteristics is prepared by using the residual active groups in the carbon quantum dot assembly (N/O-s-CQDs) prepared in example 1 under a certain temperature condition, and the surface of the nano platinum composite material (pt @ N/O-s-CQDs) contains functional groups such as hydroxyl and carboxyl, and can be specifically combined with iron ions, so that the fluorescence of a pt @ N/O-s-CQDs solution with a certain concentration is obviously quenched, and Fe can be significantly quenched 3+ The high-efficiency detection (see the attached figures 5 and 6).
Example 8
Compared with the preparation method of the nano platinum composite material Pt @ N/O-s-CQDs in the embodiment 7, the concentration of the chloroplatinic acid is changed, and the solution is specifically a solution of 20 mL and 90 nM chloroplatinic acid.
Example 9
Compared with the preparation method of the nano platinum composite material Pt @ N/O-s-CQDs in the embodiment 7, the concentration of the chloroplatinic acid is changed, and the solution is specifically 20 mL and 120 nM chloroplatinic acid.
Example 10
Compared with the preparation method of the embodiment 7, the preparation method of the nano platinum composite material Pt @ N/O-s-CQDs changes the dosage of the N/O-s-CQDs, and specifically 60 mg of the N/O-s-CQDs is dissolved in 30 mL of water.
Example 11
Compared with the preparation method of the embodiment 7, the preparation method of the nano platinum composite material Pt @ N/O-s-CQDs changes the reaction temperature, and particularly continuously reacts for 6 hours at 60 ℃.
Example 12
Compared with the preparation method of the example 7, the preparation method of the nano platinum composite material Pt @ N/O-s-CQDs changes the reaction time, and particularly continuously reacts for 6 hours at 80 ℃.
Example 13
In the embodiment, the nano platinum composite material Pt/N-s-CQDs based on the carbon quantum dot assembly prepared by the preparation method is applied to photo-thermal, and the method specifically comprises the following steps: the nano platinum composite material Pt/N-s-CQDs based on the carbon quantum dot assembly prepared in the example 7 is dissolved in ultrapure water to prepare a solution D with the concentration of 1 mg/mL. The temperature of the sample is gradually increased to be stable in a certain time by adopting a photo-thermal instrument with 808 nm, and the temperature change of the sample is tested.
The products of the examples of the present invention were tested and N/O-s-CQDs was found at 3380 cm as shown in FIG. 1 of the accompanying drawings -1 The peak at (A) is attributed to the stretching vibration of O-H bond and N-H bond in amide bond, 1654 cm -1 Peak at (2) is ascribed to stretching vibration of C = O bond in amide bond, 1572 cm -1 The peak at (A) is attributed to the characteristic peak of the dihydroxyindole moiety in polydopamine, 1479 cm -1 The peak belongs to the stretching vibration of the C-N bond, which can show that the CHO-CQDs react with PEI and DA to introduce-CONH-into the assembly N/O-s-CQDs; comparing FTIR graphs of N/O-s-CQDs with Pt @ N/O-s-CQDs, the characteristic peaks are slightly shifted because of the interaction of amine groups, carbonyl groups and the like in the assembly and the loaded nano platinum.
As shown in the attached drawings of the specification, FIGS. 2 and 3, TEM and HRTEM images of Pt @ N/O-s-CQDs show that the Pt (IV) is reduced to the simple substance Pt and is uniformly loaded in the assembly, and the pattern has a 0.217 nm lattice fringe pattern corresponding to the Pt (100) lattice fringe.
In another exampleFIG. 4 shows the attached drawings in the description, the fluorescence quenching rate is 1-F/F 0 With Fe 3+ Graph of concentration dependence of fluorescence quenching rate on Fe 3+ The concentration is in a good linear relationship in the range of 10-400. Mu.M. Linear equation of 1-F/F 0 =0.00134C Fe3+ +0.05249, good linear correlation, correlation coefficient (R) 2 ) It was 0.99933.
Also shown in FIG. 5 of the accompanying drawings, the pair of Fe detected by N/O-s-CQDs is 3+ In the selectivity of (1), 500 mu M of Fe is respectively added into the N/O-s-CQDs solution 3+ 、Ni 2+ 、Na + 、Mg 2+ 、K + 、Zn 2+ 、Ba 2+ 、Hg 2+ 、Mn 2+ 、 Ca 2+ 、Pb 2+ Change of fluorescence intensity before and after the metal ions are plasma-generated. Degree of quenching of fluorescence (in F/F) when other common metal ions are added to N/O-s-CQDs solution 0 Expressed) has almost no influence, but only Fe is added thereto 3+ Then, the fluorescence of the N/O-s-CQDs solution is remarkably reduced, and fluorescence quenching is generated.
As shown in FIG. 6 of the attached drawings of the specification, N/O-s-CQDs detect Fe 3+ The anti-interference performance of the system. The data of group 1 is the control group, the left side of the data of group 2 (i.e. the 3 rd histogram) shows the experimental results corresponding to the N/O-s-CQDs solution added with a common metal ion, and the right side shows the experiment results added with a common metal ion and Fe at the same time 3+ The results of the experiments corresponding to the mixed N/O-s-CQDs solution. The results show that, except for Fe 3+ The other 10 common metal ions do not have particularly large influence on the fluorescence intensity of N/O-s-CQDs. However, when Fe 3+ When the fluorescent dye is added into N/O-s-CQDs solution, the fluorescence intensity is obviously reduced, and fluorescence quenching is generated. It can be concluded that N/O-s-CQDs are responsible for Fe 3+ Has good selectivity.
As shown in the attached figure 7 of the specification, the assembly N/O-s-CQDs are prepared according to different mass ratios of PEI and DA, when mPEI: mDA = 100: 1, the fluorescence intensity of the obtained N/O-s-CQDs is the highest, and the same concentration is multiplied by hours than that of the assembly N-s-CQDs without DA participation.
Variations and modifications to the above-described embodiments may occur to those skilled in the art based upon the disclosure and teachings of the above specification. Therefore, the present invention is not limited to the specific embodiments disclosed and described above, and modifications and variations of the present invention are also intended to fall within the scope of the appended claims.

Claims (9)

1. A preparation method of a nano platinum composite material Pt @ N/O-s-CQDs based on a carbon quantum dot assembly is characterized by comprising the following steps:
1) Dissolving 30-60 mg of carbon quantum dots N/O-s-CQDs in 30 mL of pure water, and fully dissolving by ultrasonic to obtain a solution C;
2) And (3) dropwise adding 20 mL of 60-120 nM chloroplatinic acid solution into the solution C, reacting at 25-80 ℃ for 4-8 h, dialyzing the obtained solution in pure water for a certain time, performing suction filtration, and freeze-drying to obtain the nano platinum composite material Pt @ N/O-s-CQDs, and storing for later use.
2. The method for preparing nano platinum composite material Pt @ N/O-s-CQDs based on carbon quantum dot assembly according to claim 1, wherein the dialysis treatment in the step 2) is performed in a dialysis bag of 1000/2000 Da for 12-48 h.
3. The method for preparing nano platinum composite material Pt @ N/O-s-CQDs based on carbon quantum dot assembly according to claim 1, wherein the process for preparing the carbon quantum dot N/O-s-CQDs in the step 1) comprises the following steps:
firstly, 0.12-0.48 g of CHO-CQDs is dissolved in 40 mL of pure water, and the solution A is obtained by ultrasonic full dissolution; dissolving 2.24-3.20 g of Polyethyleneimine (PEI) and 0.1-0.0062 g of Dopamine (DA) into 40 mL of ethanol, and sufficiently dissolving by ultrasonic to obtain a solution B; and then dropwise adding the solution B into the solution A, reacting for 6-10 h to obtain a mixed solution, dialyzing in pure water for a certain time, and performing suction filtration and freeze drying to obtain the assembly N/O-s-CQDs.
4. The method for preparing the nano platinum composite material Pt @ N/O-s-CQDs based on the carbon quantum dot assembly as claimed in claim 3, wherein the dialysis treatment in the preparation process of the carbon quantum dot N/O-s-CQDs is carried out in a dialysis bag of 1000/2000/8000-14000 Da for 12-48 h.
5. A carbon quantum dot assembly-based nano platinum composite material Pt @ N/O-s-CQDs, which is characterized in that the carbon quantum dot assembly-based nano platinum composite material Pt @ N/O-s-CQDs prepared by the preparation method of any one of the claims 1 to 4 is adopted.
6. The application of the novel carbon quantum dot assembly N/O-s-CQDs is characterized in that the novel carbon quantum dot assembly N/O-s-CQDs prepared by the preparation method of any one of the claims 3-4 are applied to the detection of ferric ions.
7. The use of the novel carbon quantum dot assemblies N/O-s-CQDs as claimed in claim 6 for the detection of ferric ions comprising the steps of:
s1, dissolving the prepared novel carbon quantum dot assembly N/O-S-CQDs in ultrapure water to prepare solution D, and testing the fluorescence intensity of the solution D, wherein the fluorescence intensity is marked as F 0
S2, then adding Fe with different concentrations 3+ Respectively mixing the solution with the solution D to respectively obtain corresponding mixed solutions, and performing fluorescence test to obtain fluorescence intensity values of the mixed solutions, and marking the fluorescence intensity values as F;
s3, with Fe 3+ Concentration as abscissa, fluorescence quenching rate (1-F/F) 0 ) Performing linear fitting to obtain a regression equation y1= k1x1+ b1 as an ordinate, wherein y1 is a fluorescence quenching rate, and x1 is Fe 3+ The value of k1 is the slope, and the value of b1 is the intercept;
s4, fe is to be detected 3+ The solution is mixed with the solution D to obtain a Fe-N/O-s-CQDs mixed solution for fluorescence test, the fluorescence intensity value of the Fe-N/O-s-CQDs mixed solution is obtained, the fluorescence intensity value is substituted into a linear regression equation y1= k1x1+ b1, and Fe is obtained through calculation 3+ Concentration of (2)。
8. The use of novel carbon quantum dot assemblies N/O-s-CQDs as claimed in claim 7, wherein said different concentrations of Fe 3+ Fe in solution 3+ The concentration is 10-400. Mu.M.
9. The use of the novel carbon quantum dot assemblies N/O-s-CQDs as claimed in claim 7, wherein the mass concentration of solution D is 10-20 mg/mL.
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