Efficient Destruction of Pollutants in Water by a Dual-Reaction-Center

Mar 15, 2018 - Key Laboratory of Drinking Water Science and Technology, Research Center for Eco-Environmental Sciences, Chinese Academy of Sciences, B...
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Remediation and Control Technologies

Efficient Destruction of Pollutants in Water by a Dual-Reaction-Center FentonLike Process over Carbon Nitride Compounds (CN)-Complexed Cu(II)-CuAlO2 Lai Lyu, Dengbiao Yan, Guangfei Yu, Wenrui Cao, and Chun Hu Environ. Sci. Technol., Just Accepted Manuscript • DOI: 10.1021/acs.est.7b06545 • Publication Date (Web): 15 Mar 2018 Downloaded from http://pubs.acs.org on March 15, 2018

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Efficient Destruction of Pollutants in Water by a Dual-Reaction-Center

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Fenton-Like Process over Carbon Nitride Compounds (CN)-Complexed

3

Cu(II)-CuAlO2

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Lai Lyuab, Dengbiao Yanc, Guangfei Yub, Wenrui Caoa and Chun Hu*,ab

5 6

a

7

Water Quality and Conservation of the Pearl River Delta, Ministry of Education,

8

School of Environmental Science and Engineering, Guangzhou University,

9

Guangzhou 510006, China b

10 11 12 13

Research Institute of Environmental Studies at Greater Bay, Key Laboratory for

Key Laboratory of Drinking Water Science and Technology, Research Center for

Eco-Environmental Sciences, Chinese Academy of Sciences, Beijing 100085, China c

School of Environmental and Chemical Engineering, Tianjin Polytechnic University, Tianjin 300387, China

14 15

*Corresponding author Tel: +86-10-62849628; fax: +86-10-62923541;

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e-mail: [email protected] / [email protected]

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ABSTRACT

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Carbon nitride compounds (CN) complexed with the in-situ produced Cu(II) on

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the surface of CuAlO2 substrate (CN-Cu(II)-CuAlO2) is prepared via a surface growth

21

process for the first time, which exhibits exceptionally high activity and efficiency for

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the degradation of the refractory pollutants in water through a Fenton-like process in a

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wide pH range. The reaction rate for BPA removal is ~25 times higher than that of the

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CuAlO2. According to the characterization, Cu(II) generation on the surface of

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CuAlO2 during the surface growth process result in the marked decrease of the

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surface oxygen vacancies and the formation of the C-O-Cu bridges between CN and

27

Cu(II)-CuAlO2 in the catalyst. The electron paramagnetic resonance (EPR) analysis

28

and density functional theory (DFT) calculations demonstrate that the dual reaction

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centers are produced around the Cu and C sites due to the cation–π interactions

30

through the C-O-Cu bridges in CN-Cu(II)-CuAlO2. During the Fenton-like reactions,

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the electron-rich center around Cu is responsible for the efficient reduction of H2O2

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to •OH, and the electron-poor center around C captures electrons from H2O2 or

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pollutants and diverts them to the electron-rich area via the C-O-Cu bridge. Thus, the

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catalyst exhibits excellent catalytic performance for the refractory pollutant

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degradation. This study can deepen our understanding on the enhanced Fenton

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reactivity for water purification through functionalizing with organic solid-phase

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ligands on the catalyst surface.

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INTRODUCTION

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Growing discharges of nonbiodegradable and persistent organic pollutants

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adversely affect the environment and potentially threaten human health.1, 2 Advanced

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oxidation processes (AOPs) have been applied for eliminating the recalcitrant organic

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pollutants in water due to the generation of the highly reactive free radicals.3, 4 Among

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various AOPs, Fenton reaction (Fe2+/H2O2) is an especially powerful and

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environmentally friendly method,5, 6 since it does not require any special energy input

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and can rapidly destruct the pollutant structure with the generated highly aggressive

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free hydroxyl radical (•OH).7-9 Unfortunately, the classical Fenton reaction suffers

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from its drawbacks such as the poor recyclability,10 the narrow working pH range

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and the accumulation of Fe-containing sludge,12, 13 which restrict its wide applications.

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To avoid or minimize these drawbacks, many researchers focus on looking for

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efficient heterogeneous Fenton-like catalysts as alternatives to the homogeneous

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process.14-18

11

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However, few of the developed heterogeneous Fenton catalysts exhibit good

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activity and high catalytic efficiency under neutral conditions, which is due to the

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rate-limiting step upon the reduction of the stationary M(n+m)+ to Mn+ (M represent

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metal species) by oxidizing H2O2 on the solid-liquid interface.9, 19-21 In addition, in

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this step, H2O2 was finally decomposed into O2•− or O2, leading to invalid

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consumption of H2O2.8, 12 Moreover, surface oxygen vacancies (Vo) were easy to be

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produced in the synthesis process of the metal-containing catalyst, which often

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promote the rapid decomposition of H2O2 to H2O and O2,19, 22, 23 leading low H2O2

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utilization. The problems above are contributed to the dependency for the redox of the

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metal ions which are difficult to solve by conventional means.24

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Recently, our research20 has revealed that constructing dual reaction centers with 3 ACS Paragon Plus Environment

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the non-uniform distribution of the electrons in a catalyst by lattice-doping method is

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essential for overcoming the limitations of the classical Fenton reaction, which gives

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us inspirations for in-depth exploration of more efficient dual-center Fenton catalysts

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using other means for tuning the electron distribution. Cation–π interactions are

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important intermolecular binding forces, which are relevant for the aromatic

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recognition in the chemical and biological processes.25,

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particularly crucial process in the cation–π interactions for transition-metal ions.26 It is

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reasonable to believe that creating a special bonding bridge enhancing the cation–π

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interaction through the charge transfer is the key for inducing the non-uniform

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distribution of the electrons on the catalyst surface.

26

Charge transfer is a

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Herein, a novel Fenton catalyst consisting of aromatic carbon nitride compounds

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(CN) complexed with in-situ produced Cu(II) on the surface of CuAlO2 substrate

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(CN-Cu(II)-CuAlO2)

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CN-Cu(II)-CuAlO2 exhibits excellent Fenton-like activity and efficiency in a wide pH

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range for the degradation of the refractory pollutants, as demonstrated with phenol,

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2-chlorphenol, ibuprofen, phenytoin and bisphenol A (BPA). The generation of Cu(II)

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on the surface of CuAlO2 and the formation of the key C-O-Cu bridges between CN

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and Cu(II)-CuAlO2 in the catalyst during the surface complexation process were

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verified and characterized by several characterization techniques. The electron-rich

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Cu and electron-poor C centers (i.e., dual reaction centers) are produced due to the

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cation–π interactions through the C-O-Cu bridges in CN-Cu(II)-CuAlO2, as

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confirmed by the electron paramagnetic resonance (EPR) analysis and density

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functional theory (DFT) calculations. A preliminary effort to identify a correlation

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between the surface electron properties of CN-Cu(II)-CuAlO2 and catalytic

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performance has been undertaken, and a dual-reaction-center mechanism for the

is

prepared

via

a

surface

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complexation

process.

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Fenton-like reaction has been proposed.

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EXPERIMENTAL SECTION

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Preparation of catalysts. CN-Cu(II)-CuAlO2 is prepared by two steps. The first one

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is to synthesize CuAlO2. In a typical procedure, 4.0 g of Cu(CH3COO)2•H2O was

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dissolved in 30 mL of ethylene glycol to form solution A. Then, 7.5 g of

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Al(NO3)3•9H2O was dissolved in 15 mL of ethylene glycol to form solution B. Next,

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solution B was added to solution A and stirred at room temperature for 2 h. After the

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mixture is kept at 150 ºC, vaporizing the ethylene glycol and volatile substances and

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getting the dry gel precursor. Then, the dry gel precursor was calcined in a muffle

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furnace at 1200 ºC in air for 2 h. The resulting solid was washed with deionized water

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several times. After drying at 60 ºC, CuAlO2 was obtained. Next, the prepared

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CuAlO2 and urea were mixed in deionized water with the mass ratio of 1:5. After that,

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the mixture was calcined for 4 h at 550 ºC in a muffle furnace. After natural cooling,

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the composite was obtained, which was designated as CN-Cu(II)-CuAlO2. The

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pristine g-C3N4 was prepared using the same procedure without the addition of

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CuAlO2.

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Procedures and analysis. The Fenton-like catalytic experiments were carried out

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under ambient conditions by using BPA, phenol, 2-chlorphenol, ibuprofen and

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phenytoin as model contaminants. Their structures are shown in Figure S1

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(Supporting Information, SI). In a typical experiment, 1.0 g L-1 catalysts were

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dispersed in 25 mg L-1 pollutant solutions and the whole process is keep 35 ºC

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(summer room temperature). The mixture was magnetic stirred for 30 min to establish

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the adsorption/desorption equilibrium. Then, H2O2 was added to the pollutant

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suspensions under stirring throughout the experiment. At given time intervals, 4 mL 5 ACS Paragon Plus Environment

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aliquots were collected and filtered using a Millipore filter (pore size 0.22 µm) for

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analysis. Then, the enzyme catalase was added to destroy the residual H2O2.

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The pollutant concentrations were measured by a high performance liquid

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chromatography (HPLC, 1200 series; Agilent) with an auto-sampler, a Zorbax SB-Aq

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column (4.6 × 250 mm, 5 µm; Agilent) and an UV detector at the wavelength of 225

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nm. The mobile phase was a mixture of methanol/water and was operated at a

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flow-rate of 1.0 mL min-1. The total organic carbon (TOC) was determined by a

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TOC-VCPH analyzer (Shimadzu) using high-temperature combustion. The H2O2

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concentration was determined using the reported DPD method.27 The amount of

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metallic ions releasing from the catalysts during the reaction were measured using the

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inductively coupled plasma optical emission spectrometry (ICP-OES) on an Optima

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2000 (Perkin Elmer, U.S.A.). To test the catalyst stability and recyclability, the used

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CN-Cu(II)-CuAlO2 sample was filtered, washed with water, and dried at 60 ◦C. The

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catalyst was continued to be used in the second cycle.

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BMPO-trapped

EPR

signals

were

detected

in

different

air-saturated

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methanol/aqueous dispersions of the corresponding samples. Typically, in the absence

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of H2O2, 0.05 g of the prepared powder sample was added to 1 mL of water (for

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detecting •OH) or water/methanol (10%/90%, V/V, for detecting O2•−). 20 µL of

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BMPO (250 mM) was added and held for 5 min. Then, the solution was sucked into

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the capillary. The EPR spectra were recorded on a Bruker A300-10/12 EPR

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spectrometer at room temperature. In the presence of H2O2, 0.01 g of the prepared

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powder sample was added to 1 mL of water (for detecting •OH) or methanol (for

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detecting O2•−). Then, 100 µL of the above suspension, 10 µL of BMPO (250 mM)

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and 10 µL of H2O2 (30%, w/w) were mixed and held for 5 min. The solution was

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sucked into the capillary to carry out EPR detection. 6 ACS Paragon Plus Environment

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The attenuated total reflection Fourier-transform infrared spectroscopy

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(ATR-FTIR) was recorded using a Nicolet 8700 FTIR spectrophotometer (Thermo

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Fisher Scientific Inc., USA) equipped with a Universal ATR accessory. To prepare an

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ATR sample, 0.1 g catalyst and 2 mL D2O were added to a 5 mL centrifuge tube and

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sonicated for 5 min. Subsequently, the solid in the stock was separated by

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centrifugation and treated again with another aliquot of D2O in order to eliminate

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residual H2O. The sample was sealed and centrifuged immediately. Half of the

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supernatant was used as the reference, and the solid resuspended in the other half was

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used as the sample. The BPA solution (100 ppm) was also prepared by D2O and the

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prepared process of the sample with BPA was the same as that of the pure D2O. The

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chemicals and reagents, characterization and density functional theory (DFT)

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calculations are presented in the SI.

151 152

RESULTS AND DISCUSSION

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Characterization of catalysts. Figure 1a shows the powder X-ray diffraction (XRD)

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patterns of the as-synthesized samples. The XRD peaks in the samples of CuAlO2 and

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CuAlO2 (550 ◦C, 4 h) were indexed to the standard CuAlO2 (e.g., 006, 101, 012, 009

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and 018 planes at 2θ = 31.6°, 36.5°, 37.8°, 48.2° and 56.9°, respectively; JCPDS No.

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73-9485),28 indicating that the second calcination procedure did not affect the

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structural properties of the catalyst without the addition of urea. However, in addition

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to the typical CuAlO2 diffraction pattern, two evident peaks indexed to CuO (200) at

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2θ = 35.8°29 and CuO (111) at 2θ = 39.1°30 were observed for CN-Cu(II)-CuAlO2,

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indicating that the second calcination procedure significantly influenced the crystal

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structure of catalyst in the presence of urea, which led to the formation of Cu(II).

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Differently, although the surface growth process of CN-Cu(II)-CuAlO2 was prepared 7 ACS Paragon Plus Environment

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using the g-C3N4 synthesis process, there was no significant XRD peaks were indexed

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to g-C3N4, suggesting that the produced surface species was not the standard g-C3N4

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structure with the characteristic (100) and (002) planes due to the influence of the

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surface Cu species of CuAlO2 during this surface growth process.

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The field emission scanning electron microscopy (FESEM) images of Figure

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S2a,b (SI) show that CuAlO2 consists of loosely packed grains with irregular shapes.

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The size of the fine particles is less than 100 nm and that of coarse particles is about 2

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µm. CN-Cu(II)-CuAlO2 (Figure S2c,d, SI) shows a larger particle size (0.4−3 µm)

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and a smoother surface generally. This is due to the in-situ growth of urea and

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covering the carbon nitride compounds on the CuAlO2 surface. Figure S3a (SI)

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shows the transmission electron microscopy (TEM) of CN-Cu(II)-CuAlO2. As seen

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from the micrographs, the CN-Cu(II)-CuAlO2 grain exhibits a plate like elongated

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morphology, which may form due to anisotropic crystal growth observed in CuAlO2.

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The HR-TEM image of CN-Cu(II)-CuAlO2 (Figure S3b, SI) exhibits clear lattice

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fringes. The measured distances of 0.21 and 0.24 nm can be attributed to the dhkl of

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(104) and (012) planes of the CuAlO2 substrate structure. The EDS linescan (Figure

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1b) and TEM elemental mappings (Figure 1c) of CN-Cu(II)-CuAlO2 show that Cu,

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Al and O were the main elements and uniformly distributed in the particle bulk

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horizontally and vertically. C was mainly distributed on the surface and edge of the

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particles. The top and bottom parts of C mapping were influenced by the C-containing

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support grid for TEM measurements. Differently, the N signals (may affected by the

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O element) were relatively weak on the whole scale. These results revealed the in-situ

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growth and formation of CN on the catalyst surface during the synthesis process.

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The X-ray photoelectron spectroscopy (XPS) spectra on Cu 2p3/2 of CuAlO2 and

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CN-Cu(II)-CuAlO2 samples were exhibited in Figure 2a,b. For CuAlO2 (Figure 2a), 8 ACS Paragon Plus Environment

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the obvious binding energy (BE) peak at 932.1 eV was attributed by the reduction

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state copper species.31 The auger parameters obtained at 1848.8 eV confirmed the

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reduction state copper species belonging to Cu(I). This result suggested that Cu

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species mainly exist in the form of cuprous state in CuAlO2. The weak peak located at

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934.6 eV accompanied by the appearance of shake-up satellite lines were attributed by

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the small amount of Cu(II)

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revealed that both Cu(I) and Cu(II) existed on the surface of CuAlO2 with the Cu(I) to

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Cu(II) atomic ratio of 1:0.61. After the surface growth process, the surface atomic

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ratio of Cu(I) to Cu(II) was significantly changed (Figure 2b), which obtained with

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1:1.79 for CN-Cu(II)-CuAlO2. The results indicated that the surface growth of the

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carbon nitride compounds (CN) on the CuAlO2 substrate greatly increased the

200

proportion of Cu(II) on the surface of CN-Cu(II)-CuAlO2, suggesting the surface CN

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compounds had a strong interaction with the Cu species during the synthesis process.

20

on the surface of CuAlO2. The XPS curve fittings

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CuAlO2 showed mixed bands in the BE range of 72 to 80 eV (Figure S4a, SI),

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the deconvolution of which indicated the co-presence of Al 2p (73.3 eV), Cu 3p3/2

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(74.4) and Cu 3p1/2 (76.8 eV).32 However, Al 2p did not appear, and only Cu 3p3/2

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(74.2) and Cu 3p1/2 (77.0 eV) were observed in the same BE range of

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CN-Cu(II)-CuAlO2 (Figure S4b, SI). This result revealed that the surface growth of

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CN obscured the Al species in the substrate.

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In the C 1s XPS spectra of CN-Cu(II)-CuAlO2 (Figure 2c), the distinct bands at

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284.7 and 288.7 eV corresponded to the sp2 C-C bonds and the sp2-hybridized C

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(N-C=N) in the aromatic tri-s-triazine rings,33 respectively, which were very close to

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the characteristic peaks of the pristine g-C3N4 (Figure S5a, SI). This result suggested

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that the produced surface species on the CN-Cu(II)-CuAlO2 sample formed the

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g-C3N4-like configuration although they were not the standard g-C3N4 due to the 9 ACS Paragon Plus Environment

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influence of the surface Cu species of CuAlO2 during this surface growth process.

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Differently, the intensity proportion of the peak corresponding to C-C at 284.7 eV

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markedly increased, and the intensity proportion corresponding to N-C=N at 288.7 eV

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significantly decreased in CN-Cu(II)-CuAlO2, which revealed that the excess C atoms

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were incorporated into the tri-s-triazine of g-C3N4, and then occupied and replaced the

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N atoms, resulting in the great increase of C-C and decrease of N-C=N. This result

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could also be confirmed by the atomic ratio of C to N. The value of

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CN-Cu(II)-CuAlO2 was ~63.9, which was much higher than that of the pristine

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g-C3N4 (~0.79).

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The above results suggested that the CN compounds on the surface of

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CN-Cu(II)-CuAlO2 was actually the g-C3N4 containing the excess C (i. e. C-g-C3N4).

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In addition, a new peak at 286.5 eV for the C 1s spectra emerged in

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CN-Cu(II)-CuAlO2 (Figure 2c), which is ascribed to the C atoms of the aromatic ring

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bonding to the deprotonated hydroxyl groups (C-O-M).34, 35 In combination with the

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Cu XPS analysis of CuAlO2 and CN-Cu(II)-CuAlO2, the binding energy in Cu 2p3/2,

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Cu 3p3/2 and Cu 3p1/2 were all shifted obviously after the surface growth of CN

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compounds, indicating that the CuAlO2 substrate had a strong interaction with

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C-g-C3N4, and the C-O-M bond occurs at the Cu sites. Thus, the evidence above

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revealed that the connection between the surface CN compounds and the CuAlO2

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substrate was achieved by the C-O-Cu bridge.

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The N 1s XPS of CN-Cu(II)-CuAlO2 was fitted into three main peaks at 398.8,

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400.1 and 402.3 eV (Figure S5b, SI), corresponding to the C=N-C in triazine rings,

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the tertiary N in the form of N-(C)3 and the amino functional groups (C-N-H),33

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respectively. The relative intensity proportion of C=N-C in triazine rings was greatly

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decreased in CN-Cu(II)-CuAlO2 compared with the pristine g-C3N4 (Figure S5c, SI), 10 ACS Paragon Plus Environment

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which further confirmed that the N atoms were substantially replaced by excess C

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atoms during the surface growth process.

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The O1s XPS of CuAlO2 (Figure S5d, SI) shows strong signals in the range of

242

528−534 eV, which can be fitted into 3 deconvolutions around 530.2 eV (lattice

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O-Cu(I) of CuAlO2),36, 37 530.9 eV (lattice O-Al(III) of CuAlO2)36 and 532.2 eV

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(surface –OH on CuAlO2).38-40 For the O1s XPS of CN-Cu(II)-CuAlO2 (Figure 2d),

245

the three peaks were still retained. The peak at 530.2 eV obviously weakened

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compared with that of CuAlO2, which was due to the conversion of Cu (I) to Cu (II)

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after the surface growth process according to the foregoing analysis. The emergence

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of a new peak at 532.5 eV futher confirmed the produced Cu(II) connecting with the

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deprotonated hydroxyl group through C-O-Cu bonding bridge,40,

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consistent with the result of C 1s XPS. In addition, the oxygen vacancy concentration

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could be reflected from the variation of area ratio R of the lattice O 1s peaks to the

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surface O 1s peaks (Plattice/Psurface).41 The value of R(CN-Cu(II)-CuAlO2)=2.68 was

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much higher than that of R(CuAlO2)=1.89, indicating that the surface oxygen vacancy

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(Vo) concentration of CN-Cu(II)-CuAlO2 was significantly lower than that of CuAlO2.

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Formation of active dual reaction centers. The EPR technique was used to monitor

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the electronic band structure information and investigate the presence of the single

257

electrons in the prepared samples. As shown in Figure 3a, g-C3N4 showed a sharp

258

EPR signal at g=1.996, which originated from the uncoupled electron of the skeleton

259

CN aromatic rings.42, 43 CuAlO2 showed no detectable EPR signals, indicating no

260

single electrons existing in CuAlO2. However, the as-prepared CN-Cu(II)-CuAlO2

261

displayed a very strong EPR signal at g=2.084, which was significantly enhanced

262

compared with the pure g-C3N4, revealing the conspicuous increase of the electron

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density around Cu due to the Cu(II)-π interactions of the formed C-O-Cu bonding 11 ACS Paragon Plus Environment

41

which was

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bridge on CN-Cu(II)-CuAlO2.44 These results indicated that the C-O-Cu produced by

265

the Cu(II) connecting with the deprotonated hydroxyl group on C-g-C3N4 gathered a

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large amount of single electrons around the Cu, forming the electron-rich reaction

267

centers.

268

The distributions of the valence-electron density can provide useful information

269

for the reaction center analysis. The negative and positive areas are expected to be the

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promising reactive sites for the reduction and oxidation reaction,45 respectively.

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Therefore, we investigated the distribution of the valence-electron density on

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CN-Cu(II)-CuAlO2 through DFT calculations. Figure 3b,c shows the optimized

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geometry structure (left) and the corresponding two-dimensional valence-electron

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density color-filled maps (right) of the CN-Cu(II)-CuAlO2 model fragments. The

275

construction and optimization of the geometry structure model were achieved by

276

using the B3LYP functional and Gaussian 09 package. The dangling bonds were

277

terminated with H atoms to obtain a neutral cluster. The valence-electron density was

278

analyzed using the Multiwfn package. As shown in Figure 3b, the largest electron

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distribution area appears around the Cu atom, and its maximum valence-electron

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density is as high as 4.0 e/Å3 compared with the O, C and N atoms in the

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CN-Cu(II)-CuAlO2 model fragment, which theoretically confirms that the

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electron-rich center is formed around the Cu atom, being consistent with the

283

experimental results. The valence-electron densities around C and N on the aromatic

284

rings of CN are remarkably lower than those around Cu and O atoms, revealing that

285

the π electrons on the surface of CN-Cu(II)-CuAlO2 shift to the Cu center (π→Cu, σ

286

donation) through the special Cu-O-C bonding bridge. Thus, the electron-poor centers

287

must be formed on the aromatic rings of CN. To accurately determine the electron

288

poor sites, the valence-electron density map of the CN fragments on the 12 ACS Paragon Plus Environment

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CN-Cu(II)-CuAlO2 model was magnified and presented on Figure 3c. Obviously, the

290

narrowest electron distribution area appears around the C atoms, and its maximum

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valence-electron density is only ~0.2 e/Å3, which is much smaller than that of the N

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atoms, indicating that the electron-poor sites is around the C atoms. In the aromatic

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rings of CN, the π electrons tends to be concentrated around the N atoms, which

294

suggests that in addition to the π→Cu (σ donation) electron transfer process, C

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replacing N in the CN-rings can also promote the formation of the electron-poor C

296

centers.

297

The highest occupied molecular orbital (HOMO) and lowest unoccupied

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molecular orbital (LUMO) distribution information of the dual reaction center

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fragment of CN-Cu(II)-CuAlO2 was obtained via DFT calculations (Figure S6, SI).

300

The energy separation of the HOMO and LUMO is often used as an indicator of

301

chemical reactivity.46 The HOMO–LUMO gap for pure g-C3N4 was calculated as 5.17

302

(α electron gap = β electron gap), representing a high kinetic stability and a low

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chemical reactivity. However, the gaps of the α and β electrons for the dual reaction

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center fragment of CN-Cu(II)-CuAlO2 evidently reduce to 3.62 eV and 2.24 eV,

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respectively, which is energetically favorable to extract the electrons from a low-lying

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HOMO and to add the electrons to a high-lying LUMO, forming an activated complex

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of the potential reaction.47 This result theoretically demonstrates that the chemical

308

reactivity of CN-Cu(II)-CuAlO2 is significantly enhanced by the formation of the dual

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reaction centers (electron-rich and electron-poor centers).

310

BMPO-trapped EPR spectra were used to detect •OH and HO2•/O2•− radicals in

311

the CN-Cu(II)-CuAlO2 air-saturated aqueous and methanol-aqueous dispersions

312

without adding H2O2, respectively. As shown in Figure S7a (SI), six distinct and

313

sharp

characteristic

peaks

of

BMPO-HO2•/O2•− 13

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were

observed

in

the

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methanol-aqueous

dispersion,

which

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314

CN-Cu(II)-CuAlO2

315

electron-rich reaction centers on CN-Cu(II)-CuAlO2 with copious single electrons

316

could efficiently reduce the dissolved O2 to HO2•/O2•−. By using the method of

317

detecting •OH radicals in aqueous dispersion, a series of distinct EPR signals were

318

also detected in the CN-Cu(II)-CuAlO2 suspension without adding H2O2 (Figure S7b,

319

SI). Although the EPR signals are complex due to the effect of the unpaired electrons

320

on CN-Cu(II)-CuAlO2, they also can split into four single lines with a spacing of ~14

321

G in the magnetic field due to the hyperfine interaction between the electron spin

322

of •OH and the orbital spin of N atom in BMPO. This result suggested that

323

CN-Cu(II)-CuAlO2 donated the electrons to O2 in the electron-rich reaction centers

324

and simultaneously accepted the electrons from H2O to produce •OH in the

325

electron-poor reaction centers, forming an electron transfer cycle. This effect was

326

predominantly due to the orbital interactions involving the electron transfer of π→Cu

327

(σ donation) and Cu→π* (π back-donation). All of the above evidence shows that the

328

activated dual reaction centers have been successfully built on CN-Cu(II)-CuAlO2.

329

Efficient degradation of pollutants over CN-Cu(II)-CuAlO2/H2O2 suspension.

330

The catalytic activities of the prepared samples were initially evaluated through the

331

degradation of BPA in the presence of H2O2 under the mild conditions. As shown in

332

Figure 4a, no significant BPA degradation was observed in the g-C3N4/H2O2

333

suspension. The degradation of BPA in the CuAlO2/H2O2 suspension was only 15.8%

334

within 120 min. Astonishingly, in the CN-Cu(II)-CuAlO2/H2O2 suspension, the

335

degradation degree of BPA could reach 95.5% within 120 min under the neutral and

336

mild conditions, which was 25 and 45 times higher than that in the suspensions of

337

CuAlO2/H2O2 and g-C3N4/H2O2, respectively. In addition, the TOC removal rate

338

reached 41.5% in CN-Cu(II)-CuAlO2/H2O2 suspension within 180 min (Figure 4b), 14 ACS Paragon Plus Environment

indicated

that

the

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339

which was greatly higher than that in the suspensions of g-C3N4 or CuAlO2 (almost no

340

any removal of TOC).

341

To further investigate the activity and adaptability of CN-Cu(II)-CuAlO2 for

342

different organic pollutants, four other refractory organic pollutants including phenol,

343

2-chlorphenol, ibuprofen and phenytoin were used to be degraded in the

344

CN-Cu(II)-CuAlO2 suspensions under natural conditions. As shown in Figure 4c, all

345

of the refractory compounds were substantially degraded and the degradation rate

346

could reached 88.3%-97.5% within 120 min. In addition, the degradation of higher

347

initial concentrations for BPA and 2-chlorphenol by CN-Cu(II)-CuAlO2 were also

348

carried out as shown in Figure S8 (SI). The degradation rates of both BPA (100 mg

349

L-1) and 2-CP (100 mg L-1) could reach ~90% within 120 min.

350

During the Fenton-like reactions, the maximum concentration of dissolved Cu

351

was ~0.8 mg L-1 (including the surface free Cu ions), which was much lower than the

352

limitations of the EU directives (< 2.0 mg L-1) and USA regulations (< 1.3 mg L-1).

353

No Al ions was detected in the CN-Cu(II)-CuAlO2 suspension. In addition, only 3.3%

354

TOC was removed for BPA degradation by the homogeneous Fenton reaction (Cu2+

355

concentration 0.8 mg L−1) within 120 min, which was much lower than that in the

356

CN-Cu(II)-CuAlO2 suspension, suggesting that the contribution for the pullutant

357

degradation of the released ions was negligible. The durability of CN-Cu(II)-CuAlO2

358

was tested by recovering the solid catalyst through filtration, washing and drying. As

359

shown in Figure S9 (SI), the degradation of BPA in the CN-Cu(II)-CuAlO2

360

suspension was not significantly decreased within the margin of tolerance even after 6

361

successive cycles of degradation testing. Cu2+ leaching from the catalyst significantly

362

decreased over the reuse cycles. These results suggested that CN-Cu(II)-CuAlO2 was

363

an efficient Fenton catalyst with a good repeatability and stability. 15 ACS Paragon Plus Environment

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364

The pH is often regarded as a sensitive factor for Fenton reaction, so the effect of

365

the initial pH value on BPA degradation in CN-Cu(II)-CuAlO2 suspension was

366

determined as presented in Figure 4d. Under the neutral conditions, the catalyst

367

showed the highest activity. In the range of pH 7-9, the degradation of BPA slightly

368

decreased with the increase of the initial pH, but it still could reach 70% within 120

369

min at pH 9. In the range of pH 5-7, the degradation rate of BPA was almost

370

unchanged with the change of the initial solution pH, which indicated that the activity

371

of the catalyst was not obviously affected by the pH values. In aqueous solution, the

372

metal-containing catalyst often forms surface hydroxyl groups by dissociative

373

chemisorptions of water molecules,48 leading to the activity of the metal-containing

374

catalyst strongly dependent on the solution pH, while CN-Cu(II)-CuAlO2 avoid this

375

effect due to the formation of the dual reaction centers. After the reaction, the final pH

376

values of the solutions (initial pH 6, 7, 8 and 9) generally declined (Figure S10, SI)

377

due to the production of the acidic intermediates, such as some low-molecular weight

378

organic acids, from the BPA degradation. For the solution of initial pH 5, the final pH

379

value did not change, indicating that the acidic intermediates had been degraded under

380

this condition. We also carried out the activity evaluation of CN-Cu(II)-CuAlO2 at

381

room temperature (Figure S11, SI). Within 120 min, the BPA degradation rates in the

382

CN-Cu(II)-CuAlO2/H2O2 suspensions at room temperature (~25°C), 30°C and 35°C

383

were ~90%, ~93% and ~96%, respectively. The results suggested that the activity of

384

the catalyst for BPA degradation did not change obviously at the three different

385

temperatures and the reactions were not highly temperature-dependent.

386

Fenton-like reaction mechanism on active dual reaction centers. The H2O2

387

decomposition experiment was performed in the presence of the catalysts and BPA

388

(Figure 5a). The decomposition rate of H2O2 in the CN-Cu(II)-CuAlO2 system was 16 ACS Paragon Plus Environment

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389

significantly slower than that in the CuAlO2 system, suggesting that CuAlO2 and

390

CN-Cu(II)-CuAlO2 exhibited the opposite reactivity for the decomposition of H2O2

391

compared to the degradation of BPA. CN-Cu(II)-CuAlO2 exhibited the highest

392

catalytic activity toward to the BPA degradation but consumed the least amount of

393

H2O2, revealing a high utilization efficiency of H2O2 in CN-Cu(II)-CuAlO2 system,

394

which indicated that the formation of the dual reaction centers were extremely

395

selective for promoting the pollutant degradation with minor spurious decomposition

396

of H2O2 to O2. Generally, oxygen vacancies often take part in the fast decomposition

397

of H2O2 into O2.19, 22 According to the previous XPS results, the oxygen vacancy

398

concentration of CuAlO2 was significantly more than that of CN-Cu(II)-CuAlO2.

399

Thus H2O2 was rapidly and invalidly decomposed in the CuAlO2 system with very

400

little pollutant degradation.

401

Figure 5b shows the in-situ ATR-FTIR spectra for the CuAlO2 and

402

CN-Cu(II)-CuAlO2 suspensions. In order to clearly distinguish the hydroxyl groups

403

from different sources, we carried out the experiments with D2O instead of H2O. The

404

bands in the range of 2200-2700 cm−1 are assigned to the -OD stretching of D2O ν(-OD)

405

on the catalyst surface, and the band at ~1190 cm−1 is assigned to the molecular

406

bending modes of D2O δ(D-O-D).49 For CuAlO2/D2O suspension, the ν(-OD) bands

407

centered at 2302 and 2560 cm-1. However, the bands toward adsorbing BPA on

408

CuAlO2 surface were shifted to low frequency (2550 and 2290 cm-1), which was due

409

to the deprotonation of the phenolic OH group of BPA complexing with the surface

410

Cu via σ bonding to the lone pairs of the oxygen atom.12 For CN-Cu(II)-CuAlO2/D2O,

411

the intensities of all the peaks corresponding to D2O greatly weakened, and the ν(-OD)

412

shifted to lower frequency (2285 cm-1) compared to the CuAlO2 suspension (2302

413

cm-1). The results indicated that the CN compounds had complexed with the surface 17 ACS Paragon Plus Environment

Environmental Science & Technology

414

Cu via σ bonding on CN-Cu(II)-CuAlO2, forming the dual reaction centers, which

415

greatly impedes the direct adsorption of D2O on the Cu sites. In the presence of BPA,

416

the ν(-OD) band did not continuously shift to low frequency but to a higher frequency

417

(2304 cm-1), which is the evidence that the pollutants do not directly adsorb to the

418

electron-rich Cu centers, but are mainly degraded in the electron-poor centers during

419

the Fenton-like reaction.

420

The conversion paths of H2O2 on different surfaces of the catalysts during the

421

Fenton-like reaction process were studied by the EPR spin-trap technique with BMPO.

422

As shown in Figure 5c, after adding H2O2, very weak BMPO-•OH signals were

423

detected in the CuAlO2/H2O2 system, suggesting the low conversion rate of H2O2 to

424



425

very strong BMPO-•OH signals, which was ~4 times higher than that in the

426

CuAlO2/H2O2 system. This result indicated that H2O2 were efficiently reduced to •OH

427

by the free electrons on the electron-rich centers of CN-Cu(II)-CuAlO2. Similarly, no

428

significant BMPO-HO2•/O2•− signals were observed in the CuAlO2/H2O2 system

429

(Figure 5d) due to the direct oxidation of H2O2 by the surface oxygen vacancies on

430

CuAlO2, whereas four distinct characteristic signals of BMPO-HO2•/O2•− were

431

observed in the CN-Cu(II)-CuAlO2/H2O2 system. The strong BMPO-HO2•/O2•−

432

signals might originate from three reactions: the reduction of the dissolved O2 on the

433

electron-rich reaction centers, the oxidation of H2O2 on the electron-poor reaction

434

centers and the activation of H2O2 in the small amount of surface copper ions. These

435

phenomena suggested that the creation of the dual reaction centers could efficiently

436

and rapidly activate H2O2 and produce the reactive free radicals, which was extremely

437

selective for promoting the pollutant degradation with minor spurious decomposition

438

of H2O2 to O2. However, CuAlO2 with a great amount of oxygen vacancies only

OH on the surface of CuAlO2. In contrast, CN-Cu(II)-CuAlO2/H2O2 system exhibited

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439

promoted the rapid and inefficient decomposition of H2O2 and did not result in the

440

generation of the reactive species in the solutions. This is the reason that

441

CN-Cu(II)-CuAlO2 exhibited the highest catalytic activity toward the pollutant

442

degradation but consumed the least amount of H2O2, whereas CuAlO2 exhibited low

443

activity for pollutant degradation but invalidly consumed a large amount of H2O2

444

during the Fenton-like reactions. These results confirmed that the formation of the

445

dual reaction centers on CN-Cu(II)-CuAlO2 was responsible for the high utilization

446

efficiency of H2O2 and the high Fenton-like reactivity. Moreover, the •OH signal

447

intensities for the CN-Cu(II)-CuAlO2/H2O2 system are not changed after adding BPA

448

(Figure 5c), indicating that the presence of the organic pollutants does not affect the

449

reduction of H2O2. However, the HO2•/O2•− signals are evidently weakened in the

450

CN-Cu(II)-CuAlO2/H2O2 system after adding BPA (Figure 5d), which is because the

451

electron-poor C sites tend to be complexed with the electron-rich organic compounds.

452

Thus, the organic pollutants can also act as electron donors at the electron-poor sites,

453

avoiding the oxidation of partial H2O2 into HO2•/O2•−.

454

The remained single electrons of CN-Cu(II)-CuAlO2 after reacting with the

455

dissolved O2/H2O and H2O2 were measured through EPR. As shown in Figure S12

456

(SI), the EPR signal intensity almost did not change after reaction with the dissolved

457

O2/H2O and H2O2. This result further confirmed the dual center reaction process and

458

revealed the electron compensation effect on the dual reaction centers that O2 or H2O2

459

captured electrons from the electron-rich centers, and simultaneously H2O or H2O2

460

donated electrons to the electron-poor centers. These donated electrons of H2O or

461

H2O2 were quickly diverted to the electron-rich centers from the electron-poor centers

462

due to the special connecting mode of Cu-O-C by the produced Cu(II) connecting

463

with the deprotonated hydroxyl group on C-g-C3N4. The EPR signal that did not 19 ACS Paragon Plus Environment

Environmental Science & Technology

464

weaken after reaction revealed the excellent electron cycle capability of the dual

465

reaction centers on CN-Cu(II)-CuAlO2.

466 467

ASSOCIATED CONTENT

468

Supporting Information

469

Supplementary Methods and Figures S1-S12. This material is available free of charge

470

via the Internet at http://pubs.acs.org.

471

AUTHOR INFORMATION

472

Corresponding Author

473

*[email protected] / [email protected] (Hu C.)

474

Notes

475

The authors declare no competing financial interest.

476

ACKNOWLEDGMENTS

477

This work was supported by the National Key Research and Development Plan

478

(2016YFA0203200), the National Natural Science Foundation of China (51538013)

479

and the Science Starting Foundation of Guangzhou University (27000503151 and

480

2700050302).

481 482

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x α-Fe2O3-(1-x)ZrO2 for oxygen gas sensing application. Mater. Chem. Phys. 2002, 75, 25 ACS Paragon Plus Environment

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(1-3), 67-70.

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(42) Yu, X.; Li, Z. H.; Liu, J. W.; Hu, P. G., Ta-O-C chemical bond enhancing charge

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separation between Ta4+ doped Ta2O5 quantum dots and cotton-like g-C3N4. Appl.

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Catal., B 2017, 205, 271-280.

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(43) Zhang, J. S.; Zhang, M. W.; Sun, R. Q.; Wang, X. C., A facile band alignment of

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polymeric carbon nitride semiconductors to construct isotype heterojunctions. Angew.

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Chem. Int. Edit. 2012, 51, (40), 10145-10149.

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(44) Boukhvalov, D. W.; Osipov, V. Y.; Shames, A. I.; Takai, K.; Hayashi, T.; Enoki,

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T., Charge transfer and weak bonding between molecular oxygen and graphene zigzag

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edges at low temperatures. Carbon 2016, 107, 800-810.

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(45) Chu, S.; Wang, Y.; Guo, Y.; Feng, J. Y.; Wang, C. C.; Luo, W. J.; Fan, X. X.; Zou,

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Z. G., Band structure engineering of carbon nitride: In search of a polymer

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photocatalyst with high photooxidation property. ACS Catal. 2013, 3, (5), 912-919..

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(46) Zhang, L. P.; Xia, Z. H., Mechanisms of oxygen reduction reaction on

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nitrogen-doped graphene for fuel cells. J. Phys. Chem. C 2011, 115, (22),

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11170-11176.

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(47) Aihara, J., Reduced HOMO-LUMO gap as an index of kinetic stability for

631

polycyclic aromatic hydrocarbons. J. Phys. Chem. A 1999, 103, (37), 7487-7495.

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(48) Tamura, H.; Mita, K.; Tanaka, A.; Ito, M., Mechanism of hydroxylation of metal

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oxide surfaces. J. Colloid. Interf. Sci. 2001, 243, (1), 202-207.

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(49) Belhadj, H.; Melchers, S.; Robertson, P. K. J.; Bahnemann, D. W., Pathways of

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the photocatalytic reaction of acetate in H2O and D2O: A combined EPR and

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ATR-FTIR study. J. Catal. 2016, 344, 831-840.

637 638

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639

Figure Captions

640

Figure 1. (a) XRD patterns of the prepared samples. (b) EDS linescan (from TEM)

641

and (c) elemental mappings (from TEM) of CN-Cu(II)-CuAlO2.

642

Figure 2. XPS spectra in Cu 2p for (a) CuAlO2 and (b) CN-Cu(II)-CuAlO2, (c) C 1s

643

and (d) O 1s for CN-Cu(II)-CuAlO2.

644

Figure 3. (a) EPR spectra of the fresh g-C3N4, CuAlO2 and CN-Cu(II)-CuAlO2

645

samples. (b) and (c) DFT calculations for the optimized structure (left) and the

646

corresponding two-dimensional valence-electron density color-filled maps (right) of

647

the CN-Cu(II)-CuAlO2 model in -Cu(II)-CN vision fragment (b) and -CN vision

648

fragment (c). Orange, red, gray, blue and white circles denote Cu, O, C, N, and H

649

atoms, respectively. The valence-electron density is given in e/Å3.

650

Figure 4. (a) BPA degradation curves in various suspensions with H2O2 (Insert shows

651

the corresponding kinetic curves). (b) TOC removal curves during BPA degradation.

652

(c) Decomposition curves of different pollutants in CN-Cu(II)-CuAlO2 suspensions

653

with H2O2. (d) Effect of initial pH values for BPA degradation. Reaction conditions:

654

Natural initial pH (pH 6-7, except d), initial pollutants 25 mg/L, initial H2O2 10 mM,

655

catalyst 1.0 g L−1.

656

Figure 5. (a) H2O2 decomposition curves during BPA degradation in CuAlO2 and

657

CN-Cu(II)-CuAlO2 suspensions. Reaction conditions: Natural initial pH, initial

658

pollutants 25 mg/L, initial H2O2 10 mM, catalyst 1.0 g L−1. (b) ATR-FTIR spectra of

659

CuAlO2 and CN-Cu(II)-CuAlO2 in D2O environment with/without BPA. BMPO

660

spin-trapping EPR spectra for (c) •OH and (d) HO2•/O2•− in various suspensions in the

661

presence of H2O2 with/without pollutants.

662

27 ACS Paragon Plus Environment

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Page 28 of 33

663 ∗ g-C3N4

018



♥ ♥ ♥

10





1200



♥ ♥













CuAlO2 (550°C,4h)









C N O Al Cu

CPS



CN-Cu(II)-CuAlO2



110 1010



009



107

006

002 101 111 012 104



♦ ♦

CuAlO2 ∗100 g-C3N4

664

1800

(b)



♥ CuAlO 2 ♦ CuO

003

Intensity (a.u.)

(a)

600

♥ ♥



∗ 002

20

30

40 50 2θ (degree)

60

0 0.0

70

0.2

0.4

0.6 0.8 Distance (nm)

1.0

1.2

665 666

Figure 1. (a) XRD patterns of the prepared samples. (b) EDS linescan (from TEM)

667

and (c) elemental mappings (from TEM) of CN-Cu(II)-CuAlO2.

668

28 ACS Paragon Plus Environment

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Environmental Science & Technology

669

2.0x10

4

1.5x10

4

+

CuAlO2 Cu 2p +

1.0x10 5.0x10

3

(b) 1.8x10

4

1.5x10

4

1.2x10

4

9.0x10

3

6.0x10

3

3.0x10

3

Cu LMM-Auger

(Cu ) 932.1

+

Cu (1848.8)

1830

4

2+

Cu :Cu =1:0.61

CPS

CPS

(a) 2.5x104

1840 1850 1860 Auger Parameter (eV)

+

2+

Cu :Cu =1:1.79

CN-Cu(II)-CuAlO2 Cu 2p

Cu LMM-Auger

+

Cu (932.8)

+

Cu (1849.9) 2+

Cu (934.7)

1830

1840 1850 1860 Auger Parameter (eV) 2+

Cu satellite (941.6) (944.0)

2+

(Cu ) 934.6 2+

(Cu satellite)

0.0 925

0.0 930

670

935 940 945 Binding energy (eV)

950

4

(c) 1.2x10

925

950

CN-Cu(II)-CuAlO2 O 1s

Plattice/Psurface=2.68

4

4x10

284.7 C-C

9.0x10

CPS

4

CPS

935 940 945 Binding energy (eV)

4

(d) 5x10

CN-Cu(II)-CuAlO2 C 1s

3

3

6.0x10

3x10

530.2 O-Cu(I)

531.1 O-Al(III)

532.0 surface -OH

4

2x10

286.5 C-O-M

3

3.0x10

284

286

288

532.5 C-O-Cu

4

288.7 N-C=N

1x10

0.0

671

930

0 528

290

Binding energy (eV)

530

532 534 Binding energy (eV)

536

672

Figure 2. XPS spectra in Cu 2p for (a) CuAlO2 and (b) CN-Cu(II)-CuAlO2, (c) C 1s

673

and (d) O 1s for CN-Cu(II)-CuAlO2.

674

29 ACS Paragon Plus Environment

Environmental Science & Technology

(a) 1.5x10

5

g-C3N4

g=1.996

Intensity (a.u.)

Page 30 of 33

1.0x10

5

5.0x10

4

CuAlO2

g=2.084

0.0 2.6

2.4

2.2

675

CN-Cu(II)-CuAlO2

2.0 1.8 g Value

1.6

1.4

(b)

(c)

676 677

Figure 3. (a) EPR spectra of the fresh g-C3N4, CuAlO2 and CN-Cu(II)-CuAlO2

678

samples. (b) and (c) DFT calculations for the optimized structure (left) and the

679

corresponding two-dimensional valence-electron density color-filled maps (right) of

680

the CN-Cu(II)-CuAlO2 model in -Cu(II)-CN vision fragment (b) and -CN vision

681

fragment (c). Orange, red, gray, blue and white circles denote Cu, O, C, N, and H

682

atoms, respectively. The valence-electron density is given in e/Å3.

683

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Environmental Science & Technology

684

(b) 1.0

(a) 1.0

0.4

-1.5 -2.0 -2.5

g-C3N4

-3.0

CuAlO2

-3.5

g-C3N4

0.2

k=0.027

CN-Cu(II)-CuAlO2

0

30 60 90 Reaction time(min)

CuAlO2

120

0

g-C3N4

120

Phenol 2-Chlorphenol Ibuprofen Phenytoin

0.6 0.4

CuAlO2 CN-Cu(II)-CuAlO2

0

30

60 90 120 150 Reaction time (min)

(d) 1.0

180

pH=5 pH=6 pH=7 pH=8 pH=9

0.8

BPA C/C0

0.8

0.6 0.4 0.2

0.2

686

0.7

0.5

30 60 90 Reaction time (min)

(c) 1.0

0.0

0.8

0.6

CN-Cu(II)-CuAlO2

685

C/C0

TOC/TOC0

k=0.0011

-1.0

0.6

0.0

0.9

k=0.0006

0.0 -0.5

ln(C/C0)

BPA (C/C0)

0.8

0

30

60

90

0.0

120

0

30

Reaction time (min)

60 90 Reaction time (min)

120

687

Figure 4. (a) BPA degradation curves in various suspensions with H2O2 (Insert shows

688

the corresponding kinetic curves). (b) TOC removal curves during BPA degradation.

689

(c) Decomposition curves of different pollutants in CN-Cu(II)-CuAlO2 suspensions

690

with H2O2. (d) Effect of initial pH values for BPA degradation. Reaction conditions:

691

Natural initial pH (pH 6-7, except d), initial pollutants 25 mg/L, initial H2O2 10 mM,

692

catalyst 1.0 g L−1.

693

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694

(a)

1.0

(b)

Decomposition of H2O2

2302

CN-Cu(II)-CuAlO2

Absorbance (a. u.)

C/C0

CuAlO2/D2O

2290

0.8 0.6 0.4 0.2

1193

2560 CuAlO2/BPA/D2O

1190 2285

2550

CN-Cu(II)-CuAlO2/D2O

2304 CN-Cu(II)-CuAlO2/BPA/D2O

1190

2560

0.0

CuAlO2

0

30

695

(d)



BMPO- OH (with H2O2)

0

CuAlO2/H2O2

2400



2100 1800 1500 -1 Wavenumber (cm )

•−

0

CuAlO2/H2O2 CN-Cu(II)-CuAlO2/H2O2

CN-Cu(II)-CuAlO2/BPA/H2O2

CN-Cu(II)-CuAlO2/BPA/H2O2

3500 3520 Magnetic field (G)

3540

1200

BMPO-HO2/O2 (with H2O2)

CN-Cu(II)-CuAlO2/H2O2

3480

696

2700

180

Intensity (a.u.)

Intensity (a.u.)

(c)

60 90 120 150 Reaction time (min)

3480

3500 3520 Magnetic field (G)

3540

697

Figure 5. (a) H2O2 decomposition curves during BPA degradation in CuAlO2 and

698

CN-Cu(II)-CuAlO2 suspensions. Reaction conditions: Natural initial pH, initial

699

pollutants 25 mg/L, initial H2O2 10 mM, catalyst 1.0 g L−1. (b) ATR-FTIR spectra of

700

CuAlO2 and CN-Cu(II)-CuAlO2 in D2O environment with/without BPA. BMPO

701

spin-trapping EPR spectra for (c) •OH and (d) HO2•/O2•− in various suspensions in the

702

presence of H2O2 with/without pollutants.

703

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704

Table of Contents Art

705

33 ACS Paragon Plus Environment