Carbon Dot Functionalized Papers for the Selective Detection of 2,4,6-Trinitrophenol in Aqueous Solutions

Peng, Wenli; Gan, Li; Li, Weihan; Deng, Shixiong

doi:https://doi.org/10.1155/2021/4867869

Advances in Materials Science and Engineering

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Abstract Introduction Results and Discussion Conclusion Data Availability Conflicts of Interest Authors’ Contributions Acknowledgments References Copyright Related Articles

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Application and Policy Evaluation of New Energy and Materials

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Volume 2021 | Article ID 4867869 | https://doi.org/10.1155/2021/4867869

Carbon Dot Functionalized Papers for the Selective Detection of 2,4,6-Trinitrophenol in Aqueous Solutions

Wenli Peng,¹Li Gan,¹Weihan Li,¹and Shixiong Deng¹

Academic Editor: Wei Liu

Received04 Aug 2021

Revised31 Aug 2021

Accepted01 Sept 2021

Published17 Sept 2021

Abstract

The development of probes for the testing of the carcinogenic pollutant 2,4,6-trinitrophenol (TNP) is of great importance for environmental protection and human health. In this paper, a new rapid and sensitive fluorescence detection method based on carbon dots (CDs) was designed for the detection of TNP. The CDs were synthesized by simple pyrolysis using citric acid as raw material and characterized by various advanced techniques. The addition of TNP caused a significant turn off in the fluorescence of the CDs. The fluorescence quench intensity and TNP concentration exhibited a good linear correlation in the range of 0–80 μM with a minimum detection limit of 0.48 μM and a related coefficient of 0.994. The analytical method was applied to the determination of trace TNP in river water and tap water with recoveries in the range of 98%–110% and relative standard deviations less than 5%. Importantly, carbon dots functionalized papers (CDFPs) were prepared using the synthesized CDs and successfully applied to the determination of TNP in aqueous solutions, demonstrating the promising application of the method.

1. Introduction

2,4,6-Trinitrophenol (TNP) is a nitroaromatic compound that is widely used in the preparation of military explosives, pharmaceuticals, matches, insecticides, leather, glass, dyes, and fireworks [1–3]. Due to its high explosive velocity and low safety factor, TNP has more intense explosive properties than the well-known TNT [4, 5]. In addition, its widespread use in several industries has led to soil and water contamination due to its high water solubility [6–9]. Furthermore, TNP is also a highly carcinogenic agent with hepatic and renal toxicity [10–12]. Once TNP enters the body, it can cause damage to the eyes, skin, respiratory system, nervous system, liver, and kidneys and even induce a series of health problems such as anemia, cyanosis, male infertility, and cancer [13–17]. Given the impact of TNP on human health, the surrounding environment, and social and public safety issues, there is an urgent need to establish a rapid and sensitive method that can be used for on-site trace TNP detection. So far, many methods applied to TNP detection such as electrochemistry [18], mass spectrometry [19], surface-enhanced Raman spectroscopy [20], and colorimetric methods [21] have been able to meet market demand, but their application is limited by time-consuming, pretreatment processes, expensive instruments, complex operations, and low sensitivity and selectivity. In contrast, fluorescence-based detection methods are of interest because of their simplicity of operation, sensitivity, and low cost [22–25]. The common fluorescence analysis methods for TNP detection are mainly based on metal nanoclusters [26], photoluminescent polymers [27], organic frameworks [28–30], and semiconductor quantum dots doped with heavy metals [31, 32], which have low stability and environmental pollution problems. Therefore, a new fluorescent material that overcomes these limitations is needed for the rapid and sensitive detection of TNP.

Currently, carbon dots (CDs), as a novel nanomaterial, have been extensively applied in bioimaging, chemical sensors, drug delivery, and photocatalysis due to their outstanding water solubility, biocompatibility, low toxicity, and ease of synthesis [33–35]. In this study, we prepared fluorescent CDs by a simple hydrothermal route using citric acid as a precursor. The synthesis process is shown in Scheme 1. After the addition of TNP, the fluorescence of CDs was apparently quenched because of the internal filter effect (IFE). Therefore, the detection of TNP was achieved by the fluorescence quench of synthetic CDs. In addition, the effects of pH, ionic strength, incubation time, nitro analogs, and common metal ions on the fluorescence intensity of the synthesized CDs were discussed. Using the optimized parameters, the prepared fluorescent probes were validated and succeeded in the application for the detection of TNP in tap and river water. Importantly, the carbon dot functionalized papers prepared using CDs as probes showed good selectivity and sensitivity for trace amounts of TNP in water samples, demonstrating their remarkable potential for real-time and in situ detection of environmental pollutants.

2. Experiments

2.1. Materials

2,4,6-Trinitrophenol (TNP) was purchased from Beijing Zhongke Yingchuang Biotechnology Co. p-Nitrophenol (NP), p-nitrochlorobenzene (NC), nitrobenzene (NB), 1-chloro-2,4-dinitrobenzene (CDNB), and 1,3-dinitrobenzene (DNB) were purchased from Aladdin Co. Water samples were taken from tap water and Jialing River. All chemicals were of analytical grade and utilized directly without further purification.

2.2. Characterization

The morphological profile and particle size distribution of the CDs were assessed using an FEI Tecnai G2 F20 transmission electron microscope (TEM). Diffraction patterns of the CDs were recorded with an X-ray diffractometer (XRD) (X’Pert PRO MPD) at an accelerating voltage of 40 kV. The chemical composition of the CDs was obtained by X-ray photoelectron spectroscopy (XPS) (Thermo ESCALAB 250XI) analysis. Fourier transform infrared (FT-IR) spectroscopy was carried out using a Bruker Vertex 70 spectrometer at 4000–500 cm⁻¹. Fluorescence experiments on the prepared fluorescent CDs and mixtures of CDs with TNP were recorded on an FS5 fluorescence spectrophotometer in the wavelength range 300–600 nm. UV-Vis absorption spectra were recorded on a UV-2600 UV spectrophotometer in the wavelength range 200–600 nm. Absolute fluorescence quantum yields were determined on an Edinburgh FLS9800 (steady-state transient spectrometer). The CDs and CDs-TNP complexes were evaluated using a fluorescence lifetime system.

2.3. Preparation of CDs

1.0507 g of citric acid was added to 10 mL of deionized water. The mixed solution was then transferred to an autoclave (30 mL) lined with Teflon and heated for 5 hours at 200°C. It was cooled to room temperature, filtered through a microporous filter (0.45 μM), and purified using a dialysis bag (MWCO = 3500) for 24 h. Finally, the resulting solution was freeze-dried under a vacuum to obtain the purified CDs.

2.4. Detection of TNP

A mixture of CDs and TNP was obtained by mixing 1 ml of CDs solution (0.2 mg/ml) with 1 ml of different concentrations of TNP (0, 1, 2, 10, 20, 40, 60, and 80 μM). The solution was kept at room temperature with shaking for 3 min. The fluorescence quenching effect of CDs was observed with a fluorescence spectrometer under 340 nm excitation.

2.5. Sample Pretreatment

Tap water and river water samples were taken locally from Chongqing. Water samples were centrifuged and filtered through 0.45 μM microporous filters.

2.6. Preparation of CDFPs

The CDFPs were prepared as described in the previous literature [36]. In brief, a wax printer was used to print a circular hole pattern on one side and wax on the other side of the chromatography paper. The wax-imprinted chromatography paper was put on a heating table and heated at 150°C for 1 min to melt the wax to form a hydrophobic layer. The prepared carbon dot solution (4 μl) was placed in each circular hole of the wax-printed paper. The excess solvent was evaporated in an oven at 50°C.

3. Results and Discussion

3.1. Synthesis and Characterization of CDs

The XRD diffraction pattern (Figure 1(a)) shows a broad peak located at 2θ = 24.1°, comparable to the graphite lattice spacing (002), which is consistent with previous reports, and confirms that the synthesized CDs have a similar graphene structure [37]. The morphology and dimensions of the prepared CDs were characterized by TEM, as shown in Figure 1(b). The synthesized CDs are subspherical in shape and have good dispersion in aqueous solution. Figure 1(c) shows the lattice spacing of the prepared CDs. The particle size distribution of the CDs (Figure 1(d)) shows a narrow range of diameters from 1.49 to 3.09 nm, with an average diameter of 2.2 nm. We then investigated the optical properties of the synthesized fluorescent CDs using fluorescence spectroscopy and UV absorption spectroscopy. As shown in Figure 2(a), CDs do not have a prominent absorption peak in the visible region, but there is significant absorption at 200–300 nm. The fluorescence emission spectra of CDs were obtained at 10 nm intervals at different excitation wavelengths in the range of 310–400 nm. As shown in Figure 2(b), the fluorescence spectrum is red-shifted with increasing excitation wavelength. The carbon dot shift between the emission and excitation wavelengths is 80 nm, indicating that the synthesized CDs could be used as a candidate analytical material. The fluorescence quantum yield, an important property of synthetic CDs, is calculated to be 5.9%, which is comparable to the previously reported yield of undoped quantum dots [38]. The chemical bonding and functional groups at the carbon sites were further investigated using FT-IR spectroscopy (Figure 3(a)). The broad and strong peak at 3490 cm⁻¹ is attributed to the –OH stretching vibration [39]. The vibrational peak at 1724 cm⁻¹ is thought to be the C=O stretching vibration [40]. The stretching peak at 1187 cm⁻¹ is attributed to C-O [41]. The bands at 920 cm⁻¹ and 780 cm⁻¹ are identified as out-of-plane bending vibrations of the O-H bond. To further investigate the elemental composition of the CDs, they were subjected to further XPS assays. As shown in Figure 3(b), the wide scan XPS spectrum shows two peaks centered at 285.3 eV and 533.2 eV, attributed to the C 1s and O 1s signals, respectively [42]. The C 1s (Figure 3(c)) show three peaks, which correspond to C−C (284.8 eV), C-O (286.6 eV), and O=C-O (288.8 eV), respectively [43]. The O 1s peak (Figure 3(d)) can be deconvoluted into two peaks, C-O (531.7 eV) and O-C=O (532.9 eV) [44]. The peaks associated with the hydroxyl and carboxyl functional groups in the XPS analysis results are consistent with the FT-IR spectra of the CDs, favoring solubility and stability in water. The above results indicate that the blue fluorescent probes are successfully synthesized and can be further analyzed for applications.

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3.2. Parameter Optimization

Various factors such as buffer pH, ionic strength, and incubation time can affect the fluorescence intensity of CDs, so a series of experiments were carried out to optimize the parameters for the analysis of CDs. Firstly, the influence of PH on the fluorescence of CDs was studied, and the findings are illustrated in Figure 4(a). The fluorescence intensity of CDs remained relatively stable at pH 7.0–9.0. Therefore, we chose the pH 7.0 buffer for the sensitive detection of TNP. The effect of ion concentration was then explored, as shown in Figure 4(b). The fluorescence intensity remained essentially constant at different concentrations of NaCl solution, which demonstrates that CDs can be detected at stronger ionic concentrations. In addition, the relationship between incubation time and carbon dot fluorescence was investigated to ascertain the altered kinetics of the probes. As shown in Figure 4(c), the fluorescence of the CDs was effectively burst during 7 minutes after the incorporation of 20 μM TNP, indicating that the 7-minute incubation time could be used for further analytical studies. Therefore, we chose a pH 7.0 buffer incubated for 7 minutes at room temperature for the sensitive detection of TNP.

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3.3. Analysis of Performance

The above optimized analytical parameters were adopted to detect different concentrations of TNP and to evaluate the analysis properties of the presented fluorescent probes. Figure 5(a) shows the fluorescence spectra of the fluorescent CDs at 340 nm excitation under the effect of different levels of TNP. It can be seen that the fluorescence of the CDs is gradually quenched as the concentration of TNP increased. We plotted the Stern–Volmer curve between log (I₀/I) and TNP (Figure 5(b)), where I₀ and I represent the fluorescence intensity of CDs in the absence and presence of TNP. It showed a good linear relationship between the burst of fluorescence and TNP concentration in the 0–80 μM range with a regression coefficient (R²) of 0.994. The regression equation is log (I₀/I) = 0.007c (μM) − 0.014. The limit of detection (LOD) was 0.48 μM (3σ/k, n = 3), which was calculated from the standard deviation (SD) of the response and the slope of the calibration curve (S), which is comparable to previous studies (Table 1) in the literature. As the concentration of TNP increased, the bright blue fluorescence of the CDs-TNP mixture was gradually quenched under the UV lamp, while a change in colour could be seen in the CDs-TNP mixture, visually demonstrating the quenching phenomenon (Figure 5(c)). Therefore, our proposed analytical method has high affinity and sensitivity for the detection of trace amounts of TNP.

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3.4. Study of Possible Mechanisms

To investigate the mechanism of quenching of the prepared fluorescent probes, we investigated the optical properties of CDs and CDs-TNP complexes. In the recently published literature, three common mechanisms of fluorescence quenching include fluorescence resonance energy transfer, photoinduced electron transfer, and fluorescence internal filtration [45]. As shown in Figure 6(a), the emission spectra of CDs clearly superimpose on the absorbance spectrum of TNP, suggesting that the fluorescence quenching mechanism may be IFE or FRET [46]. As shown in Figure 6(b), the addition of TNP (20 μM) changed the fluorescence lifetime from 2.222 ns to 2.198 ns, which showed little change in fluorescence lifetime, in agreement with previous reports [47], ruling out the possibility of a quenching mechanism for FRET and PET [48]. Therefore, the fluorescence quenching mechanism of CDs was attributed to the IFE between TNP and CDs.

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3.5. Selective Detection

An important factor in the evaluation of the prepared fluorescent probes is selectivity. It was possible to detect the selectivity of the proposed fluorescent probes by assessing the change in the fluorescence intensity of the prepared CDs in the presence of TNP and other similar nitroaromatic compounds (NP, NC, NB, and CDNB). As shown in Figure 7(a), the fluorescence intensity of the CDs was significantly quenched by the addition of TNP compared to the other nitro compounds, showing the good selectivity of the prepared fluorescent probes for TNP. The selective detection of TNP was also applied to common metal ions. The results are shown in Figure 7(b). The effect of metal ions is almost negligible compared to TNP, indicating that the prepared probes still have good selectivity despite the interference of metal ions.

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3.6. Assaying TNP in Real Aqueous Samples

To test the practical application of the prepared probes, the prepared CDs were used to detect TNP in actual samples. We collected Jialing River water and tap water locally in Chongqing, and after adding different concentrations of TNP, the recoveries were analyzed and the findings are demonstrated in Table 2, where the recoveries of the samples ranged from 98% to 110% with relative standard deviations of less than 5% for each sample for three experiments. The analytical method proved to have good accuracy and recovery. Therefore, the sensor can be implemented for the detection of real samples.

3.7. Detection of TNP by CDFPs

To demonstrate the rapid sensitivity and easy portability of CDs for TNP detection, the CDFPs were prepared by immersing filter paper in solutions of different concentrations of CDs and drying at room temperature. It was found that the functionalized paper immobilised with 400 μg/mL CDs showed the strongest fluorescence under UV light. Therefore, a carbon dot concentration of 400 μg/mL was chosen as the optimum concentration for the preparation of CDFPs. The functionalized paper immobilised with 400 μg/mL CDs was treated with different concentrations of TNP, as shown in Figure 8(a). The fluorescence intensity of the indicator paper gradually decreased as the TNP concentration increased from 0 to 80 μM, indicating a rapid and naked-eye sensitive detection of TNP. Because of the relatively low emission backdrop of the chromatography paper, we chose a portable laser lamp at 254 nm, although the photoluminescence of the CDs was stronger at 360 nm excitation. In addition, we examined common nitro analogs using the prepared carbon dot functionalized paper. The results are shown in Figure 8(b), where the fluorescence quench of TNP on CDs is visible to the naked eye under UV lamp irradiation, demonstrating its potential application in the field for the detection of TNP.

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4. Conclusion

In summary, we synthesized environmentally friendly CDs using citric acid as the precursor. The prepared CDs showed excitation-dependent behavior at 310 nm–400 nm with a fluorescence QY of 5.9%. The results show that the synthesized CDs can be used as detection probes for TNP with high selectivity and sensitivity in the range of 0–80 μM TNP concentration and a detection limit of 0.48 μM. More importantly, the CDFPs we prepared were effectively used in actual water samples, showing promising potential for field monitoring of environmental water samples.

Data Availability

The data that support the findings of this study are available from the corresponding author upon reasonable request.

Conflicts of Interest

The authors declare no conflicts of interest.

Authors’ Contributions

Li Gan and Weihan Li helped to revise manuscript. Shixiong Deng revised the manuscript and coordinated the study.

Acknowledgments

This study was supported by funding from the Basic Medicine College, Chongqing Medical University. The authors are grateful for the financial support of this study.

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Copyright © 2021 Wenli Peng et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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