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Article

Degradation of 2-Naphthol in Aqueous Solution by Electro-Fenton System with Cu-Supported Stainless Steel Electrode

1
Guangzhou Higher Education Mega Centre, School of Environment & Energy, South China University of Technology, Guangzhou 510006, China
2
The Key Laboratory of Pollution Control and Ecosystem Restoration in Industry Clusters of Ministry of Education, Guangzhou 510006, China
3
Guangdong Provincial Key Laboratory of Solid Wastes Pollution Control and Recycling, Guangzhou 510006, China
4
Guangdong Provincial Engineering and Technology Research Center for Environmental Risk Prevention and Emergency Disposal, Guangzhou 510006, China
*
Author to whom correspondence should be addressed.
Water 2022, 14(7), 1007; https://doi.org/10.3390/w14071007
Submission received: 22 February 2022 / Revised: 16 March 2022 / Accepted: 17 March 2022 / Published: 22 March 2022

Abstract

:
For the treatment of 2-naphthol wastewater, the homogeneous electro-Fenton process was considered as an effective method but some disadvantages greatly restrict its application. The three-dimensional electro-Fenton (3D-EF) system using a nano zero-valent iron-supported biochar (NZVIs-BC) particle electrode and a Cu-supported stainless steel electrode (Cu-SSE) was proposed to avoid the disadvantages of the homogeneous electro-Fenton. In this work, the 3D-EF system was developed, which consisted of a Cu-SSE (cathode), a graphite rod (anode) and a NZVIs-BC particle electrode. The effect of the ratio of ferrous sulfate heptahydrate (FS) to rice straw (RS), CuSO4•5H2O amount, initial pH of 2-naphthol wastewater and current intensity (the output current of the power supply) on the removal rate of 2-naphthol were investigated. It is noteworthy that more than 98.36% of the 2-naphthol in aqueous solution was removed by the 3D-EF system, and only about 60.09% of 2-naphthol was removed by the homogeneous electro-Fenton system. Furthermore, naphthalene, benzoic acid, β-naphthoquinone, 1, 2-naphthalenedione, phenol and aromatic hydrocarbon were the main degradation products of 2-naphthol by the 3D-EF system; the toxicity of 2-naphthol wastewater was also greatly reduced.

Graphical Abstract

1. Introduction

2-naphthol is also called β-hydroxynaphthalene and belongs to the polycyclic aromatic hydrocarbons (PAHs) with a stable chemical structure and strong biological toxicity [1,2]. In terms of bio-toxicity, 2-naphthol reduces the human body’s immunity by depleting glutathione in the lung cells, thereby making people more susceptible to lung cancer [3]. According to ECOSAR analysis, 2-naphthol is highly bio-toxic to aquatic organisms such as fish, daphnid and green algae. In terms of the chemical industry, 2-naphthol is also a necessary raw material for multiple chemicals and exists widely in coking wastewater [4,5]. Besides, as one of the priority pollutants and persistent organic pollutants (POPs), the toxicity of 2-naphthol is more than 1-naphthol [6].
At present, the treatment methods for 2-naphthol wastewater mainly include adsorption [7,8], biodegradation [9,10], electrochemical degradation [11], photocatalytic oxidation [12] and advanced oxidation processes (AOPs) [13,14]. Using immobilized organo-bentonite or modified biochar as adsorbent to remove 2-naphthol was widely studied, but none of them could degrade 2-naphthol fundamentally [7,15]. Factors such as harsher terms and longer residence time also greatly limit the practical application of biological treatments [6]. The degradation of 2-naphthol in aqueous solution by AOPs has been extensively studied, Wang et al [14] used sludge-based biochar as a heterogeneous catalyst for the persulfate degradation of 2-naphthol, only 88.7% of 2-naphthol and 47% of TOC were removed. The extremely low TOC degradation rate indicates the inadequacy of Wang’s method in mineralizing 2-naphthol.
As one of the AOPs, the electro-Fenton (EF) method can generate H2O2 at the cathode (Equation (1)), thereby generating hydroxyl radicals (•OH) under the catalysis of Fe2+ (Equation (2)). •OH (E0 = 2.80 V/SHE) as the iconic product of Fenton’s reaction can degrade and mineralize the refractory organic pollutants (ROPs) by destroying their chemical structure (such as chain-breaking reaction or ring cleavage reaction, etc.) within the half-life of 10−9 s [16,17,18].
O2 + 2H+ + 2e → H2O2
Fe2+ + H2O2 → Fe3+ + •OH + OH
The EF process has many advantages such as high efficiency, low cost and less secondary pollution [18], and most of the existing research was on the homogeneous electro-Fenton process: adding Fe2+ to the hydrogen peroxide solution or adding H2O2 to the iron-carbon micro-electrolysis system, which requires wastewater with a low pH value [19,20]. To avoid the disadvantages of the homogeneous electro-Fenton process, Zhang et al. [21] proposed a process of using modified iron-carbon materials as heterogeneous catalysts coupled with EF to form a three-dimensional electro-Fenton (3D-EF) system, this process greatly expanded the pH range of the EF reaction. Actually, the iron-carbon material used by Zhang et al. is a type of magnetic catalyst, which has more advantages than non-magnetic catalysts in degrading pollutants. For example, magnetic catalysts are more easily separated from pollutants, enabling activation and regeneration [22].
However, the anode material (RuO2/Ti mesh) and cathode materials (carbon fabric and nickel screen) used by Zhang’s process are expensive and not easy to prepare, which also bring inconvenience to the practical application of this 3D-EF system. On the premise of ensuring the efficient treatment of 2-naphthol wastewater, cheaper alternative electrode materials are significant for the application of the EF process.
Stainless steel wire mesh (SSWM) composed of plentiful transition metals (such as Fe, Cu, Ni, Mn, etc.) is a potential electrode material with a low price [23]. Sun [24], Chen [25], Chen [26] and Call [27] found that catalysts composed of multiple transition metals would have higher catalytic activity than single metal catalysts. As a transition metal element, Li [28], Zhou [29] and Andre A [30] found that Cu(I) and Fe(II) have a synergistic catalytic effect in the EF reaction, as described in Equations (3)–(5).
2Cu+ + O2 + 2H+ → 2Cu2+ + H2O2
Cu+ + H2O2 → Cu2+ + •OH + OH
Cu+ + Fe3+ → Cu2+ + Fe2+
Based on the excellent catalytic properties of copper ions and the low price advantage of SSWM, copper ions are supported on the surface of stainless steel as a Fenton reaction’s cathode, which is still worthy of further research.
Electro-deposition is a surface modification technique, including galvanostatic electrodeposition (GEP), potenti-ostatic electrodeposition (PED) and electrophoretic deposition (EPD) [31,32]. Miroslav [33] found that compared with GEP and EPD, the catalyst prepared by PED had better catalytic performance. Herein, a 3D-EF system was developed and used for the degradation of 2-naphthol in aqueous solution. The 3D-EF system consisted of a Cu-supported stainless steel electrode (Cu-SSE, cathode), graphite rod (anode) and nano zero-valent iron-supported biochar (NZVIs-BC) particle electrode. It is noteworthy that the Cu-SSE was prepared by PED process using SSWM as substrate, cheap being one of the advantages of Cu-SSE. The 3D-EF system we studied may also be the first time for the use of Cu-SSE and NZVIs-BC to treat 2-naphthol wastewater based on existing electro-Fenton research.

2. Materials and Methods

2.1. Experimental Reagents and Materials

2-naphthol (C10H8O): Macklin Biochemical Technology Co., Ltd. (Shanghai, China); copper(II) sulfate pentahydrate (CuSO4•5H2O): Aladdin Reagent Co., Ltd. (Shanghai, China); ferrous sulfate heptahydrate (FeSO4•7H2O): Aladdin Reagent Co., Ltd. (Shanghai, China); potassium iodide (KI): Aladdin Reagent Co., Ltd. (Shanghai, China); ammonium molybdate: Aladdin Reagent Co., Ltd. (Shanghai, China); potassium biphthalate (C8H5O4K): Aladdin Reagent Co., Ltd. (Shanghai, China); concentrated sulfuric acid (H2SO4): Guangzhou Chemical Reagent Factory (Guangzhou, China); sodium sulfate (Na2SO4): Titan Scientific Co., Ltd. (Shanghai, China); sodium nitrate (NaNO3): Guangzhou Chemical Reagent Factory (Guangzhou, China); nitric acid: Chron Chemicals Co., Ltd. (Chengdu, China). The above were all analytical reagents (AR).
Graphite rod: Zhongnuo Technology Co., Ltd. (Tianjin, China); S30210 stainless steel wire mesh (SSWM): Shuohe Metal Wire Mesh Products Co., Ltd. (Hengshui, China); platinum electrode: Yueci Electronic Technology Co., Ltd. (Shanghai, China). The quality inspection reports of graphite rod and SSWM are shown in Table 1 and Table 2 respectively.

2.2. Experimental Apparatus

DC regulated power supply (LP305DE): Leda Precision Tools Co., Ltd. (Shenzhen, China); air pump (H-9800): Chaoxin Electric Co., Ltd. (Zhongshan, China); magnetic stirrer (HJ-4A): Ronghua Instrument Co., Ltd. (Gongyi, China); ultraviolet−visible spectrophotometer: Thermo Fisher Scientific Co., Ltd. (Boston, MA, USA); high-speed multifunctional crusher (800Y): Boou Hardware Products Co., Ltd. (Jinhua, China); total organic carbon analyzer (TOC-5000A): Shimadzu Co., Ltd. (Shimane-ken, Japan); ultra-performance LC-MS instrument quadrupole combination-orbitrap (UPLC-MS-Q-O): Thermo Fisher Scientific Co., Ltd. (Boston, MA, USA); field emission-scanning electron microscope and energy dispersive spectrometer (FESEM-EDS): Carl Zeiss AG (Oberkochen, Germany); X-ray photoelectron spectroscopy (XPS; model: Escalab 250Xi): Thermo Fisher Scientific Co., Ltd. (Boston, MA, USA); X-ray diffractometer (XRD; model: SmartLab 9 kW): Rigaku Corporation (Tokyo, Japan); electrochemical workstation (CHI760e): Chenhua instrument Co., Ltd. (Shanghai, China); Fluorescence spectrometer (model: F-7000): Hitachi Co., Ltd. (Tokyo, Japan); atomic absorption spectroscopy (AAS; model: ICE3000): Thermo Fisher Scientific Co., Ltd. (Boston, MA, USA); Fourier transform infrared spectroscopy (FTIR; model: Nicolet iS50): Thermo Fisher Scientific Co., Ltd. (Boston, MA, USA); high speed automated surface area and pore size analyzer (NOVA4200e): Quantachrome Instrument Co., Ltd. (Beijing, China); pH analyzer (DZS-706-A): Inesa Scientific Instrument Co., Ltd. (Shanghai, China).

2.3. Reaction Device

The main reaction device was a beaker (500 mL), using a three-dimensional electrode system: the cathode was the Cu-SSE (size: length 280, thickness 5.00, height 120, mm, two layers; surrounding the inner wall of the beaker), the anode was a graphite rod (size: length 120, diameter 10, mm), the particle electrode was NZVIs-BC (adding 0.5 g NZVIs-BC per 500 mL 2-naphthol wastewater), the aeration rate was controlled at 0.1 L min−1, the stirring speed of magnetic rotor was controlled at 350 r min−1. The schematic diagram of the reaction device is shown in Figure 1.
The initial concentration of 2-naphthol was about 10.0 mg L−1. Sulfuric acid (1.0 mol L−1) and sodium hydroxide solution (1.0 mol L−1) was used to adjust the initial pH value of 2-naphthol wastewater.

2.4. Preparation of Modified Electrode

Preparation of Cu-SSE: SSWM was submerged into sodium hydroxide solution (40 wt%) for 30 min, and then put into dilute sulfuric acid solution (0.5 mol L−1) and ultrasonically cleaned for 3.0 min. Then, ultrasonically cleaned with distilled water several times until its pH value was bout 7.0. Finally, it was put in a vacuum desiccator for later preparation. In this experiment, the dosage of CuSO4•5H2O in electro-deposition solutions was 1.0 g L−1, 2.0 g L−1, and 3.0 g L−1 respectively. Copper was supported on S30210 stainless steel substrates by a PED process [32,34]. The temperature of the electro-deposition solution was 60 °C constantly, the initial pH was 3.0, and the deposition voltage was 32.5 V.
Preparation of NZVIs-BC: rice straw (RS) was washed with distilled water and dried to a constant weight in an oven at 90 °C. Then, the RS was crushed and filtered with a 300-mesh sieve. The NZVIs-BC was prepared by the impregnation-pyrolysis method, whereby (1) a 5.0 g measure of the RS powder (dry weight) was dipped into 50 mL FS solution (the dosage of FS was 0.0 g, 1.0 g, 2.0 g, 3.0 g, respectively) and left for 24 h; (2) then dried to constant weight in an oven at 80 °C; and (3) underwent high-temperature pyrolysis at 700 °C for 8.0 h (under nitrogen atmosphere).

2.5. Methods of Characterization

The FESEM-EDS was used to analyze the surface morphology of Cu-SSE and NZVIs-BC. The XPS was used to analyze the element valence on the surface of Cu-SSE. The AAS was used to determine the concentration of total copper ions in wastewater. The high-speed automated surface area and pore size analyzer was used to determine the surface area and pore size distribution of NZVIs-BC. The FTIR was used to determine functional groups on the surface of NZVIs-BC. The UPLC-MS-Q-O was used to analyze the degradation products of 2-naphthol. The concentration of 2-naphthol was measured by an ultraviolet−visible spectrophotometer at 229 nm. The concentration of •OH was measured by the fluorescence spectrometer: excitation wavelength was 419.4 nm and emission wavelength was 505.5 nm [35]. The concentration of H2O2 was measured by the potassium iodide method [28,36]. Cyclic voltammetry (CV) and an electrochemical impedance spectroscope (EIS) were used to test the electrochemical performance of Cu-SSE: the working electrode was Cu-SSE, the reference electrode was saturated calomel electrode, the auxiliary electrode was a platinum electrode (size: length 15, width 15, thickness 0.1, mm), the electrolyte was 0.05 mol L−1 Na2SO4 solution, the electrode potential range was from −1.2 V to +0.4 V, the scanning speed was 50 mV s−1, and the interval voltage was 0.001 V.

3. Results and Discussion

3.1. Characterization of Electrode

The SEM results of the Cu-SSE and NZVIs-BC are shown in Figure 2a–d and Figure 2e,f, respectively. Before the EF reaction, the surface of the Cu-SSE was covered with a dense copper coating, the diameter of the copper coating was about 1.0 μm, as shown in Figure 2a,b. This result indicates that copper ions had been successfully supported on the surface of SSWM by the PED process. After the EF reaction, dispersed particles appeared on the surface of the Cu-SSE, and a smooth SSWM substrate was also exposed at the same time, as shown in Figure 2c,d. Moreover, the surface of the NZVIs-BC obtained by high-temperature pyrolysis was covered with nano-zero-valent iron particles (NZVIs-particles), the diameter of NZVIs-particles varied from 10.0 nm to 200 nm, as shown in Figure 2e,f.
The elemental distribution on the surface of the Cu-SSE before the EF reaction is shown in Figure 3. Before the EF reaction, copper was the most abundant element on the surface of the Cu-SSE, and its proportion was as high as 86.28% (wt%) and 68.47% (at%). In addition, oxygen atoms also appeared on the surface of the Cu-SSE, which indicates that a portion of Cu0 had been oxidized before the electrolysis reaction.
Iron ions and copper ions are the most important catalysts for the EF reaction. To further analyze the valence distribution of iron ions and copper ions, XPS tests were performed on Cu-SSE, the results are shown in Figure 4.
As shown in Figure 4a, the copper ions on the surface of the Cu-SSE were mostly in the state of Cu0 or Cu(I) and had better reducibility. However, the aggregated copper oxides were also apparent, this result indicates that a portion of copper had been oxidized to Cu(I) and Cu(II) before the EF reaction. Specifically, the Cu-SSE had two obvious absorption peaks near 935.02 eV and 944.01 eV before the EF reaction, these two peaks indicate that copper ions were existing in the form of cupric carbonate basic [Cu2(OH)2CO3].
After the EF reaction for 200 min, Cu0 on Cu-SSE was mostly oxidized to Cu(I) and Cu(II), as shown in Figure 4b. Specifically, the Cu-SSE had obvious absorption peaks near 932.7 eV and 933.1 eV, these two peaks represent Cu(I) oxide and Cu(II) oxide, respectively. Additionally, Cu-SSE also had an obvious absorption peak near 934.8 eV, this result indicates that a small amount of Cu(II) carbonate dihydroxide (cupric carbonate basic) was formed on the surface of the Cu-SSE after the EF reaction. Figure 4b also reveals that the dispersed particles appearing in Figure 2c,d were most likely Cu(II) carbonate dihydroxide. This research was consistent with the results of copper corrosion in simulated industrial water by Monticelli. C et al [37]. In addition, a greater amount of Fe0 was oxidized to Fe (I) oxide and Fe(II) oxide by participating in the EF reaction, as shown in Figure 4c,d.
Figure 5a,b depicts the electrochemical performance of Cu-SSE and SSWM. After the PED process, there were two obvious oxidation peaks (−0.4V and −1.0V) and two obvious reduction peaks (−0.2 V and −0.4 V) on the Cu-SSE, while SSWM only had an indistinct reduction peak at −0.4 V (Figure 5a). The oxidation peaks may represent the process of Fe0 oxidized to Fe(III) (Equation (6)), and the reduction peaks may represent the production process of H2O2 on the cathode (Cu-SSE and SSWM) (Equation (1)).
Fe − 3e → Fe3+ E0 (Fe/Fe3+) = −0.037 V
Compared with the SSWM, the Cu-SSE had a more obvious reduction peak, which further verifies that copper ions could enhance the Fenton’s reaction, as shown in Equations (3)–(5). According to the EIS test, the Cu-SSE had less resistance and higher electrical conductivity than SSWM, which would accelerate the transfer rate of electrons in electrochemical reactions, as shown in Figure 5b.
The surface area and pore size distribution results of NZVIs-BC are shown in Figure 6a,b and Table 3. The specific surface area of NZVIs-BC was 218.400 m2 g−1, the average pore diameter was 3.689 nm, and the pore volume was 0.201 cc g−1. The large specific surface area means that NZVIs-BC has more attachment sites, the large pore volume of NZVIs-BC helps it to absorb more 2-naphthol molecules. Moreover, the adsorption and desorption isotherms of NZVIs-BC are nonlinear and have obvious hysteresis loops, as shown in Figure 6a. The hysteresis loop indicated that the desorption process of 2-naphthol by NZVIs-BC was slower than the adsorption process, which was more favorable for the removal of 2-naphthol [38].
During the adsorption process, the adsorbate diffuses into the interior of the NZVIs-BC through macropores (>50 nm) and mesopores (2–50 nm) [39]. The distribution of mesopores and macropores affects the diffusion rate of adsorbate in NZVIs-BC. It can be seen from Figure 6b that the pore size of NZVIs-BC is concentrated in the range of 3 to 30 nm, showing a mesoporous structure, which is beneficial to the diffusion of adsorbate in NZVIs-BC.
The FTIR results of NZVIs-BC are shown in Figure 6c. When the wavenumber ranged from 500 cm−1 to 4000 cm−1, six absorption peaks appeared in NZVIs-BC: (1) 650–680 cm−1 for aliphatic C-C or aliphatic C-H stretching vibrations; (2) 830 cm−1 for aromatic C-H bending (aromatic out-of-plane deformation); (3) 1290–1310 cm−1 for the bending of phenolic hydroxyl; (4) 1620–1700 cm−1 for the stretching vibrations of C=C (aromatic compounds or olefins) and C=O (aldehyde, ketone or organic acids); (5) 2120–2130 cm−1 for the stretching vibrations of C≡C, C=C=C or C=C=O; (6) 3500 cm−1 for the stretching vibrations of hydroxyl groups (alcohol, organic acids or hydrogen-bonded water).
The point of zero charges (pHpzc) could be used to describe the charge properties of NZVIs-BC in media of different acidities [40]. As shown in Figure 6d, the pHpzc of NZVIs-BC was about 10.50 and was measured by Yang’s method [41].
We investigated the stability of Cu-SSE electrodes, as shown in Figure S1. Within 100 min, the removal rate of 2-naphthol by 3d-EF system has reached 97.35%. At this time, the surface of Cu-SSE is still relatively smooth, as shown in Figure S1a. From 200 min, the substrate of Cu-SSE (SSWM) begins to be oxidized, and a large number of iron ions in SSWM may begin to participate in the Fenton reaction at this time, as shown in Figure S1b. From 300 min, the surface of Cu-SSE start to form forest-like metal oxides and porous structure, and the porous structure may contribute to adsorb 2-naphthol, as shown in Figure S1c. Compared with the third use, the surface condition of Cu-SSE after the fourth use did not change significantly, as shown in Figure S1d.
To obtain the crystal structure, elemental composition and other information of Cu-SSE, XRD analysis of Cu-SSE was carried out, as shown in Figure S2. The test conditions are as follows: copper target, Ni filter, Kα ray (λ = 0.15418 nm); voltage: 40 KV, current: 40 mA; scanning step size 0.02, scanning rate: 2° min−1, scanning range 10°–80°. According to Figure 1, there are five X-ray diffraction peaks on the Cu-SSE surface: (1) 43.297° (hkl = 111) and 50.433° (hkl = 200) for the sharp peaks of Cu0; (2) 37.009° (hkl = 111) for the sharp peak of Cu2O; (3) 74.976° (hkl = 004) for the peak of CuO; (4) 56.656° (hkl = 103) for the peak of Fe0. The above results confirmed that Cu-supported stainless steel electrode was successfully synthesized by PED process.

3.2. The Influence of Various Factors on 2-Naphthol Degradation

Figure 7a shows the effect of different ratios of FS to RS on the degradation of 2-naphthol by the NZVIs-BC system. When the ratios of FS to RS were 0:5, 1:5, 2:5, and 3:5, the highest removal rates of 2-naphthol were 64.07, 90.23, 91.10 and 91.25%, respectively; these results indicate that the removal rate of 2-naphthol by the NZVIs-BC system was better than the pure biochar system (FS to RS was 0:5). The possible reason is that NZVIs and biochar can form countless microscopic galvanic cells in acidic aqueous solutions (Equations (7) and (8)), thereby speeding up the electron migration in the reaction system and promoting the formation of many active products, such as hydroxyl (-OH), reducing atomic hydrogen ([H]) and Fe(II) [42]. These active products can effectively degrade 2-naphthol by participating in subsequent electro-flocculation, redox, adsorption or other chemical reactions [19]. In addition, copper ions are pollutants in aqueous solution, which need to be removed to a low enough concentration. Because of the adsorption effect of NZVIs-BC on copper ions, the concentration of total copper ions in 2-naphthol wastewater was 1.32 mg L−1 after treatment for 200 min. Considering the cost factor, the ratio of FS to RS in this research selected was 1:5.
Anode (NZVIs): Fe − 2e → Fe2+ E0 (Fe/Fe2+) = −0.447 V
Cathode (Biochar): O2 + 4H+ + 4e → 2O• + 4[H] E0 (O2/H2O) = +1.229 V
When the dosage of CuSO4•5H2O was 0.0, 1.0, 2.0 and 3.0 g L−1, the highest removal rates of 2-naphthol by 3D-EF system were 94.47, 97.51, 98.36 and 97.63% respectively. Therefore, the application of the Cu-SSE to the 3D-EF system could further improve the removal rate of 2-naphthol, as shown in Figure 7b. Copper ions maybe participate in the EF reaction as the catalyst (Equations (3)–(5)), and there was a synergistic catalytic effect between Cu2+ and Fe2+. Furthermore, Cu2+ also prevents NZVIs-BC from compaction or passivation and increases the potential difference between biochar and NZVIs [43].
It can be seen in Figure 7c that the removal rate of 2-naphthol first increased and then decreased with the increase of current intensity. When the current intensity was less than 300 mA, the ability of the Cu-SSE to capture electrons would be reduced, which would affect the production of H2O2 and •OH (Equations (1)−(4)). However, the excessive current intensity (>300 mA) would also cause a variety of side reactions (based on Faraday’s law), thereby reducing the efficiency of current utilization (Equations (9) and (10)). According to experiments, the best current intensity for the 3D-EF system to remove 2-naphthol was 300 mA.
H2O → H+ + OH
2H2O2 → 2H2O + O2
When the initial pH value of 2-naphthol wastewater ranged from 5.0 to 8.0, the removal rate of 2-naphthol was inversely proportional to the initial pH value, as shown in Figure 7d. Under acidic conditions, the 2-naphthol could be electrostatically adsorbed on the surface of NVZIs-BC. Furthermore, enough acid radical ions also improved the conductivity of the liquid environment and reduced the electrochemical impedance of the 3D-EF system.
Figure 8 shows the removal rates of 2-naphthol by the 3D-EF system (the dosage of CuSO4•5H2O was 2.0 g L−1, the current intensity was 300 mA, the initial pH value of 2-naphthol wastewater was 6.5, FS:RS = 1:5), the homogeneous EF system (without NZVIs-BC, the dosage of CuSO4•5H2O was 2.0 g L−1, the current intensity was 300 mA, the initial pH value of 2-naphthol wastewater was 6.5) and the pure NZVIs-BC system (FS: RS = 1:5, the initial pH value of 2-naphthol wastewater was 6.5). The removal rate of 2-naphthol by the 3D-EF system (the highest removal rate was 98.36%) was better than the homogeneous EF system (the highest removal rate was 60.09%) and the pure NZVIs-BC system (the highest removal rate was 90.23%); this result reveals that there may be a synergistic effect between NZVIs-BC and the EF system. Specifically, a variety of transition metals on the Cu-SSE surface would be oxidized during the electrolysis reaction. These transition metal oxides are positively charged and would increase the potential difference between biochar and NZVIs, which accelerates the electron migration rate between biochar and NZVIs. In addition, NZVIs-BC as an electrolyte not only helps to improve the conductivity of the 2-naphthol wastewater but also provides high-quality Fe0/Fe2+ catalysts for the EF reaction.
Based on the above analysis, the 3D-EF system has a higher removal rate of 2-naphthol and TOC under the original acidity of the 2-naphthol wastewater (initial pH was 6.5), the highest removal rate could reach 98.36% and 96.05%, as shown in Figure 8 and Figure 9a. Noteworthy is that the removal of 2-naphthol by the 3D-EF system reached 93.82% within 40 min and would slow down as the reaction progresses (NZVIs-BC may reach adsorption equilibrium at this time). By the fluorescence spectrometer and the potassium iodide method, •OH and H2O2 were also detected in 2-naphthol wastewater with the highest concentrations of 52.27 μmol L−1 and 1.39 mmol L−1, respectively.

3.3. The Degradation Pathway of 2-Naphthol

Based on the UPLC-MS-Q-O test in positive ion mode, the molecular weights of the main degradation products of 2-naphthol were 128.07, 130.08, 146.07, 158.04, 162.07, 164.07, and the possible main organic matters were naphthalene, benzoic acid, β-naphthoquinone, 1, 2-naphthalenedione, phenol, aromatic hydrocarbon, etc. By the 3D-EF system, the possible degradation pathways of 2-naphthol in aqueous solution are shown in Figure 10.
Based on the UPLC-MS-Q-O test and changes in the products’ functional groups, the main chemical reactions involved in the above conversion were: I—desaturation, II—carbonylation, III—hydration, IV—reduction, V—acetylation, VI—deacylation, and VII—substitution.
According to the “Globally Harmonized System of Classification and Labelling of Chemicals (GHS)” and the ECOSAR system, the toxicity of 2-naphthol and its degradation products is studied by the lethal concentration (LC50), concentration of 50% of maximal effect (EC50), chronic value (ChV) as toxicity indicators. In addition, the toxicity standards are divided into four categories, which are: very toxic (<1 mg L−1), toxic (1–10 mg L−1), harmful (10–100 mg L−1) and not harmful (>100 mg L−1). The evaluated toxicity of all degradation products is far below 2-naphthol, as shown in Figure 11.

4. Conclusions

In our work, a 3D-EF system was developed to degrade 2-naphthol in aqueous solution, consisting of a Cu-SSE (cathode), graphite rod (anode) and NZVIs-BC particle electrode. Through the determination of the electrode materials and wastewater, the main conclusions of this work are as follows:
(1)
SEM-EDS and XPS test results show that a dense copper coating was formed on the stainless steel surface by the PED process.
(2)
CV and EIS test results show that copper modification helps to improve the electrochemical performance of stainless steel electrodes.
(3)
NZVIs-BC was prepared by the impregnation-pyrolysis method, giving it a larger specific surface area and a higher pHpzc. The specific surface area of the NZVIs-BC was 218.4 m2 g−1. The pHpzc of the NZVIs-BC was about 10.50, which helped to adsorb weakly acidic 2-naphthol.
(4)
NZVIs-BC could act synergistically with the EF system, thereby improving the removal rate of 2-naphthol in aqueous solution.
(5)
Under certain conditions (a ratio of FS to RS of 1:5, a dosage of CuSO4•5H2O of 2.0 g L−1, an initial pH of 2-naphthol wastewater of 6.5, and a current intensity of 300 mA), the removal rate of 2-naphthol could reach 93.82% within 40 min, the removal rate of TOC could reach 96.05% within 200 min, which indicated that the 2-naphthol was well mineralized by the 3D-EF system.
(6)
Naphthalene, benzoic acid, 1, 2-naphthalenedione, β-naphthoquinone, phenol, aromatic hydrocarbon were the main degradation products of 2-naphthol, the toxicity of 2-naphthol wastewater had also been reduced.
Looking forward to the future, the 3D-EF system reactors will be developed by combining automatic control, fluid mechanics or other theories, which can be used for advanced treatment of industrial wastewater or efficient treatment of decentralized wastewater.

Supplementary Materials

The following are available online at https://www.mdpi.com/article/10.3390/w14071007/s1, Figure S1: The stability of the Cu-supported stainless steel electrode: (a) Electro-Fenton reaction for 100 min, firstly used; (b) Electro-Fenton reaction for 200 min, secondly used; (c) Electro-Fenton reaction for 300 min, thirdly used; (d) Electro-Fenton reaction for 400 min, fourthly used. Figure S2: The XRD result of Cu-SSE.

Author Contributions

Conceptualization, X.C. and X.Z.; methodology, X.Z., S.Z. and L.S.; software, X.C.; validation, X.Z., S.Z. and L.S.; formal analysis, X.C.; investigation, X.C.; resources, X.Z.; data curation, X.C.; writing—original draft preparation, X.C.; writing—review and editing, X.Z., S.Z. and L.S.; visualization, X.C.; supervision, X.Z., S.Z. and L.S.; project administration, X.Z.; funding acquisition, X.Z. All authors have read and agreed to the published version of the manuscript.

Funding

This work was financially supported by the National key research and development program of China (Grant No. 2016YFC0400702-2), the National Natural Science Foundation of China (Grant No. 21377041), the Guangdong Science and Technology Program (2020B121201003), and Guangdong Suchun Environmental Protection Technology Co. Ltd (Dongguan, China).

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Conflicts of Interest

The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.

Abbreviations

AASAtomic absorption spectroscopy
AOPsAdvanced oxidation process
BETBrunauer−Emmett−Teller, specific surface area test
Cu-SSECu-supported stainless steel electrode
CVCyclic voltammetry
EDSEnergy dispersive spectrometer
EFElectro-Fenton
EISElectrochemica l impedance spectroscopy
EPDElectrophoretic deposition
FTIRFourier transform infrared
FSFeSO4•5H2O
GEPGalvanostatic electro-deposition
LC-MSLiquid chromatography−mass spectrometry
NZVIsNano zero-valent iron
NZVIs-BCNano zero-valent iron-supported biochar
PAHsPolycyclic aromatic hydrocarbons
PEDPotentiostatic electro-deposition
pHpzcPoint of zero charges
POPsPersistent organic pollutants
ROPsRefractory organic pollutants
RSRice straw
SEMScanning electron microscope
SSWMStainless steel wire mesh
TOCTotal organic carbon
XPSX-ray photoelectron spectroscopy
3D-EFThree-dimensional electro-Fenton

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Figure 1. Schematic diagram of the reaction device: (1) DC regulated power supply; (2) magnetic stirrer; (3) air pump; (4) graphite rod; (5) aeration stone; (6) Cu-SSE; (7) NZVIs-BC; (8) magnetic rotor.
Figure 1. Schematic diagram of the reaction device: (1) DC regulated power supply; (2) magnetic stirrer; (3) air pump; (4) graphite rod; (5) aeration stone; (6) Cu-SSE; (7) NZVIs-BC; (8) magnetic rotor.
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Figure 2. SEM of Cu-SSE and NZVIs-BC before and after the EF reaction: (a) Cu-SSE before the EF reaction, 300×; (b) Cu-SSE before the EF reaction, 800×; (c) Cu-SSE after the EF reaction, 300×; (d) Cu-SSE after the EF reaction, 800×; (e) NZVIs-BC before the EF reaction, 3.00k×; (f) NZVIs-BC after the EF reaction, 3.00k×.
Figure 2. SEM of Cu-SSE and NZVIs-BC before and after the EF reaction: (a) Cu-SSE before the EF reaction, 300×; (b) Cu-SSE before the EF reaction, 800×; (c) Cu-SSE after the EF reaction, 300×; (d) Cu-SSE after the EF reaction, 800×; (e) NZVIs-BC before the EF reaction, 3.00k×; (f) NZVIs-BC after the EF reaction, 3.00k×.
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Figure 3. SEM-EDS of Cu-SSE before the EF reaction (300×).
Figure 3. SEM-EDS of Cu-SSE before the EF reaction (300×).
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Figure 4. XPS of Cu-SSE: (a,b) Cu 2p before and after the EF reaction; (c,d) Fe 2p before and after the EF reaction.
Figure 4. XPS of Cu-SSE: (a,b) Cu 2p before and after the EF reaction; (c,d) Fe 2p before and after the EF reaction.
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Figure 5. Electrochemical performance of SSWM and Cu-SSE: (a) CV test; (b) EIS test.
Figure 5. Electrochemical performance of SSWM and Cu-SSE: (a) CV test; (b) EIS test.
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Figure 6. Characterization of NZVIs-BC: (a) adsorption and desorption isotherm; (b) pore size distribution; (c) fourier transform infrared spectroscopy; (d) point of zero charges.
Figure 6. Characterization of NZVIs-BC: (a) adsorption and desorption isotherm; (b) pore size distribution; (c) fourier transform infrared spectroscopy; (d) point of zero charges.
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Figure 7. The influence of factors on removal rate of 2-naphthol: (a) the ratio of FS to RS; (b) the dosage of CuSO4•5H2O; (c) the current intensity; (d) the initial pH of 2-naphthol wastewater.
Figure 7. The influence of factors on removal rate of 2-naphthol: (a) the ratio of FS to RS; (b) the dosage of CuSO4•5H2O; (c) the current intensity; (d) the initial pH of 2-naphthol wastewater.
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Figure 8. The removal rate of 2-naphthol by different systems.
Figure 8. The removal rate of 2-naphthol by different systems.
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Figure 9. By the 3D-EF system: (a) removal rate of TOC; (b) concentration of •OH and H2O2.
Figure 9. By the 3D-EF system: (a) removal rate of TOC; (b) concentration of •OH and H2O2.
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Figure 10. The possible degradation pathways of 2-naphthol in aqueous solution.
Figure 10. The possible degradation pathways of 2-naphthol in aqueous solution.
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Figure 11. The toxicity of 2-naphthol degradation products.
Figure 11. The toxicity of 2-naphthol degradation products.
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Table 1. The quality inspection report of the graphite rod.
Table 1. The quality inspection report of the graphite rod.
IndexValues
Resistivity (μΩ m)9.00
Bulk density (g cm−3)1.85
Compressive strength (MPa)80.27
Ash (‱)8.00
Bending strength (MPa)43.00
True density (g cm−3)2.16
Shore hardness47.60
Table 2. The quality inspection report of SSWM.
Table 2. The quality inspection report of SSWM.
IndexValues
Wire diameter (mm)23.0
Bulk density (Kg m−3)150.0
Specific surface area (m2 m−3)320.0
Void fraction (%)98.1
Tensile strength (MPa)743.0
Elongation (%)43.0
C (‱)6.0
Si (‱)37.0
Mn (‰)10.2
P (‱)3.7
S (‱)0.8
Cr (%)17.2
Ni (‰)80.7
Cu (‱)21.0
Table 3. The isothermal nitrogen adsorption–desorption report of NZVIs-BC (FS:RS = 1:5).
Table 3. The isothermal nitrogen adsorption–desorption report of NZVIs-BC (FS:RS = 1:5).
IndexSurface Area (m² g−1)Average Pore Diameter (nm)Pore Volume (cc g−1)
Value218.4003.6890.201
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Cheng, X.; Zhang, X.; Zhou, S.; Shi, L. Degradation of 2-Naphthol in Aqueous Solution by Electro-Fenton System with Cu-Supported Stainless Steel Electrode. Water 2022, 14, 1007. https://doi.org/10.3390/w14071007

AMA Style

Cheng X, Zhang X, Zhou S, Shi L. Degradation of 2-Naphthol in Aqueous Solution by Electro-Fenton System with Cu-Supported Stainless Steel Electrode. Water. 2022; 14(7):1007. https://doi.org/10.3390/w14071007

Chicago/Turabian Style

Cheng, Xudong, Xiaoping Zhang, Shaoqi Zhou, and Lin Shi. 2022. "Degradation of 2-Naphthol in Aqueous Solution by Electro-Fenton System with Cu-Supported Stainless Steel Electrode" Water 14, no. 7: 1007. https://doi.org/10.3390/w14071007

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