- Email: [email protected]
Laser engraved nitrogen-doped graphene sensor for the simultaneous determination of Cd(II) and Pb(II)
Accepted Manuscript Laser engraved nitrogen-doped graphene sensor for the simultaneous determination of Cd(II) and Pb(II)
Xueni Lin, Zhiwei Lu, Wanlin Dai, Baichen Liu, Yuxin Zhang, Junye Li, Jianshan Ye PII: DOI: Reference:
S1572-6657(18)30605-2 doi:10.1016/j.jelechem.2018.09.016 JEAC 12599
To appear in:
Journal of Electroanalytical Chemistry
Received date: Revised date: Accepted date:
22 June 2018 4 September 2018 5 September 2018
Please cite this article as: Xueni Lin, Zhiwei Lu, Wanlin Dai, Baichen Liu, Yuxin Zhang, Junye Li, Jianshan Ye , Laser engraved nitrogen-doped graphene sensor for the simultaneous determination of Cd(II) and Pb(II). Jeac (2018), doi:10.1016/ j.jelechem.2018.09.016
This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
ACCEPTED MANUSCRIPT Laser engraved nitrogen-doped graphene sensor for the simultaneous determination of Cd(II) and Pb(II)
College of Chemistry and Chemical Engineering, South China University of
RI
a
PT
Xueni Lina, Zhiwei Lua, Wanlin Daia, Baichen Liua, Yuxin Zhanga, Junye Lib, Jianshan Yea,*
b
SC
Technology, Guangzhou 510641, P.R. China
The Affiliated High School of South China Normal University, Guangzhou 510630,
AC
CE
PT E
D
MA
NU
P.R. China
Corresponding author at: College of Chemistry and Chemical Engineering, South China University of Technology, Guangzhou 510641, P.R. China. Tel.: +86 20 87113241. E-mail: [email protected] (J. Ye)
ACCEPTED MANUSCRIPT Abstract Recently, graphene-based nanomaterials have attracted widespread attention as new electrode-modified materials for different electrochemical sensing platforms. However, graphene-based nanomaterials modified heavy metal sensors often have the disadvantages in that
PT
their detection ranges are not wide enough. To solve this problem, an easy and feasible approach
RI
derived from laser engraving technique to fabricate a high-quality 3D porous graphene-based
SC
heavy metal sensor with a quite wide detection range was established. The nitrogen-doped laser
NU
engraved graphene (N@LEG) was synthesized via introducing polyaniline (PANI) and polyvinylpyrrolidone (PVP) as N-dopant. Herein, by coupling the unique electrochemical
MA
properties and the 3D porous structure framework with large electrochemical active surface areas of LEG with the strong metal ions affinity of N atoms, N@LEG modified glassy carbon electrode
D
(N@LEG/GCE) with in-situ bismuth film modification has been successfully utilized for the
PT E
simultaneous determination of Cd(II) and Pb(II) using square wave anodic stripping voltammetry (SWASV). After optimizing conditions, the proposed sensor exhibits quite wide linear ranges
CE
varying from 5 to 10 g L-1 and 10 to 380 g L-1 for Cd(II), and 0.5 to 10 µg L-1 and 10 µg L-1 to 380
AC
µg L-1 for Pb(II), respectively. In addition, the detection limits are calculated to be 1.08 g L-1 (S/N = 3) for Cd(II) and 0.16 g L-1 (S/N = 3) for Pb(II), which are nearly 3 times and 60 times less than the guideline values of the drinking water presented by the World Health Organization (WHO), for Cd(II) and Pb(II), respectively. Furthermore, the results describe satisfactory advantages of remarkable sensitivity, selectivity, anti-interference, repeatability, reproducibility and stability. Besides, the fabricated sensor is proved to be a potential perspective to detect Cd(II) and Pb(II) in actual water samples.
ACCEPTED MANUSCRIPT
Keywords: Electrochemical determination; Modified electrode; Electrochemical impedance
AC
CE
PT E
D
MA
NU
SC
RI
PT
spectroscopy (EIS); Cyclic voltammetry (CV); Raman; Heavy metal.
ACCEPTED MANUSCRIPT 1. Introduction At present, due to the toxicity, stability and non-biodegradability of heavy metal ions (HMI) even trace amounts, which have a harmful impact on various environmental components, involving terrestrial and aquatic biota, the effective determination of them is of great significant[1].
PT
The routine techniques used widely for the HMI determination, including atomic absorption
RI
spectroscopy (AAS) and inductively coupled plasma mass spectrometry (ICP-MS), etc., have
SC
several defects such as time-consuming, high-cost, requirement for cumbersome instrumentation
NU
and in particular unsuitability for on-spot monitoring[2, 3]. Compared with spectroscopic methods, electrochemical methods, especially anodic stripping voltammetry (ASV) have been generally
MA
regarded as a simple and efficient tool to detect HMI owing to their superiority of low-cost, satisfactory sensitivity, fast response, portable instruments, easy to operate and the possibility of
D
on-site analysis[2, 4-7]. ASV measurements often contain a pre-concentration step and a stripping
PT E
step on working electrode surface[8]. Therefore, the choice of good performance working electrode modified materials makes contributions to improving the electrochemical analysis.
CE
Graphene, a kind of carbon nanomaterials with a unique 2D hexagonal structure of
AC
sp2-hybridized carbon, has caused extensive attention recently due to its high specific area, unique electrical conductivity, self-assembly behavior and mechanical flexibility[9, 10]. Studies have shown that the porous structure of graphene could possess a large specific area as well as have access to an effective multidimensional pathway for mass transfer and electron transport[11]. Graphene-based sensors have been widely applied to the detection of glucose, dopamine and heavy metal ions. Although most graphene-based heavy metal sensors have low detection limits,[5, 12-14] there are few reports on graphene-based heavy metal sensors with fairly wide linear 1
ACCEPTED MANUSCRIPT ranges[15]. So it is an urgent requirement to find a method for the preparation of graphene-based heavy metal sensors with considerable wide detection ranges. On the other hand, functionalization or edge/basal plane doping plays a vital role in the electrical properties of graphene and its derivatives. Thus, various doped graphene-based nanomaterials, especially doped with
PT
heteroatoms (e.g., N, B, S and Cl), have been greatly expanded the applications of battery[16],
RI
supercapacitor[17, 18], non-metal electrocatalysis[19] and electrochemical sensing[20, 21].
SC
Among them, N-doping has attracted wide concern on account of N atoms comparatively strong electron affinity to improve the electrochemical activity and excellent compatibility with the
NU
carbon matrix[1]. Besides, N-doping could lead to defect sites by replacing C atoms, which
MA
allowed potential active sites to ameliorate electrochemical activities of graphene-based nanomaterials[22, 23]. In addition, PANI, one of the most vital conducting polymers, has been
D
utilized for the application of electrochemical sensors owing to its satisfactory conductivity, ease
PT E
of synthesis and fairly non-poisonous[24]. So far, the nitrogen-containing polymer, polyvinylpyrrolidone (PVP), also has been considered as N-dopant[1]. Moreover, PVP can prevent
CE
the nanoparticle aggregation during the synthesis.[15] Up to now, N-doped graphene-based
AC
electrochemical sensors have been reported for the determination of heavy metals, but their detection range is narrower.[14, 25] In this work, an N-doped graphene-based heavy metal sensor was prepared by introducing PANI and PVP as N-dopant to improve the detection ranges. Although there are many strategies for the synthesis of graphene, they require either high temperature treatments or complex and time-consuming chemical preparation routes,[26, 27] which hinder their application due to the poor efficiency and time-consuming operations. Hence, it is an urgent need to develop a method capable of fabricating graphene at low-cost, high-efficiency, 2
ACCEPTED MANUSCRIPT and large-scale to meet actual demand. In recent years, LEG technique has achieved rapid development and the LEG has opened up a new horizon for electrochemical applications. With a standard Light Scribe DVD drive, El-Kady et al.[28] have produced the reduced graphene oxide patterns via direct laser scribing graphene oxide, which opened up a new direction for the direct
PT
on-chip manufacture of micro supercapacitors. Arul et al.[29] have also investigated the
RI
mechanism of forming graphene features by scribing with a variety of laser sources. Lin et al.[30]
SC
has successfully simplified the preparation of graphene via a one-step laser scribing on a flexible commercial-available PI sheet with a CO2 infrared laser. The resultant sheets were named as laser
NU
scribed graphene (LSG) with remarkable electron conductivity and large surface area and could be
MA
directly used as supercapacitor electrodes without any additives. Using the process similar to that reported previously using CO2 laser, the graphene layer could be formed on the pinewood, a
D
natural and renewable material[31]. With the advantages of a 3D mesoporous framework,
PT E
outstanding conductivity and electroactivity, LEG has been applied to supercapacitors[32], sensors[33], and so on[34]. Therefore, an easy and rapid method, laser engraving technique, was
CE
adopted to prepare a graphene-based heavy metal sensing platform with 3D porous structures. It
AC
was because of the 3D porous structure framework with such a large electrochemical active surface area of LEG that made contributions on the rather wide detection range. Our group have reported a glassy carbon electrode modified with a bismuth film and laser etched graphene for simultaneous voltammetric sensing of Cd(II) and Pb(II)[35]. Besides, to the best of our knowledge, there is no report on the application of laser engraving technique to prepare N-doped graphene-based electrodes for the detection of HIM in real water samples.
In this paper, we fabricated 3D porous graphene-based electrode matrices by the simple and 3
ACCEPTED MANUSCRIPT rapid laser engraving technique, and then synthesized N@LEG via introducing PANI and PVP as N-dopant. Consequently, by combining the unique electrochemical properties and large electrochemical active surface area of LEG with the strong metal ions affinity of N atoms, newly-designed N@LEG/GCE shows excellent responses for the simultaneous determination of
PT
Cd(II) and Pb(II) with such a wide detection range in virtue of square wave anodic stripping
RI
voltammetry (SWASV). Moreover, the facile and fast preparation and the extremely wide linear
SC
range indicate that the sensor is promising and ideal for the applications of HMI sensing. Additionally, the acquisition of 3D porous N@LEG sheds light on the preparation of graphene and
AC
CE
PT E
D
MA
ranges based on laser engraving technique.
NU
graphene-based heavy metal sensors with comparable detection limits and fairly wide linear
Scheme.1 Schematic illustration of the fabrication process of N@LEG electrodes for the electrochemical
simultaneous detection of Cd(II) and Pb(II).
4
ACCEPTED MANUSCRIPT 2. Experimental 2.1 Materials and Reagents
Commercial PI sheets (thickness: 0.125 mm) were purchased from Shenzhen Golden Green
PT
Leaf Technology Co., Ltd. Potassium ferricyanide (K3[Fe(CN)6]), Potassium ferrocyanide (K4Fe(CN)6·3H2O), potassium chloride (KCl), acetic acid (CH3COOH, HAc), sodium acetate
RI
(CH3COONa, NaAc) and hydrochloric acid (HCl) were purchased from Sinopharm Chemical
SC
Reagent Co., Ltd. 0.1 M NaAc/HAc buffer with different pH was prepared by NaAc and HAc.
NU
Nafion (5%), aniline, PVP, and ammonium persulfate (APS) were from Sigma-Aldrich. Nafion (5%) was diluted to 0.125% with alcohol. Standard stock solutions of Cd(II), Pb(II) and Bi(III)
MA
were obtained from Aladdin Industrial Corporation. Ultra-pure water from a water purification
2.2 Instrumentations
PT E
were of analytical grade.
D
system GWA-UN1-10 (18.25 MΩ cm) was used throughout all the experiments. All chemicals
CE
The SEM images were conducted by a Zeiss LEO1530VP scanning electron microscopy.
AC
XRD patterns were executed with a Bruker D8 Advance diffractometer with a Cuκα radiation. Raman spectra were implemented with a Jobin Yvon LabRam Aramis spectrometer. XPS measurements were accomplished on an ESCALAB 250Xi spectrometer. Laser engraving was carried out on a laser engraving machine (K3020) with glass sealed off CO2 laser. Fourier transform infrared (FTIR) spectral studies were performed with traditional KBr pellet method on a Bruker VERTEX 70 spectrometer.
5
ACCEPTED MANUSCRIPT 2.3 Laser engraving and fabrication of nanocomposite
Firstly, the PI sheets were cleaned by rinsing with alcohol and ultra-pure water and then dried in an oven at 60 °C before laser irradiation. Then, laser engraving was executed on PI sheets by the design software at a power of 5 W and a scanning speed of 50 mm/s in atmospheric conditions
PT
to form a black carbonized layer on PI films. In the meanwhile, in order to compound PANI on the
RI
once-etched PI films, 12.4 g APS and 10.0 g PVP were dissolved in 70.0 mL ultra-pure water and
SC
then cooled in an ice water bath for about 30 min (solution I). After that,the once-etched PI films
NU
were moved to a 500ml beaker. Then 2 mol/L HCl was added until the black carbonized area was submerged and 5ml aniline was added. The mixture was placed in an ice water bath under
MA
continuous stirring with the solution I added dropwise and then left overnight. The resulting product was named as once-etched PI films compounded with polyaniline (OE-PI@PANI).
D
Afterwards, the OE-PI@PANI was cleaned by ultra-pure water and then dried in an oven. Finally,
PT E
the OE-PI@PANI was laser engraved again with a larger power (6.2 W) in the same area to make graphitization more sufficiently. The fully graphitized material which had been broken away from
CE
the PI film was scraped off to obtain the desired product. Since the PANI combined on the
AC
once-etched PI film was decomposed by the instantaneous high temperature generated during the laser engraving process[11], the obtained nanomaterials were defined as N@LEG. The direct twice-etched graphene (TE-LEG) was prepared in the similar ways except the procedure of combining with the PANI. The PANI was prepared using the method above aside from integrating with the PI sheets.
6
ACCEPTED MANUSCRIPT
2.4 Preparation of modified electrode
Before the modification, 4 mg N@LEG was ultrasonically dispersed in 2 mL 0.125% Nafion-alcohol solution (V:V=1:1) for more than 2 hours to acquire a homogeneous suspension.
PT
The bare GCE was polished with alumina powder and then sonicated with alcohol and ultra-pure water in turns for 2 minutes. Then the treated GCE was dried under an infrared lamp. After that, 4
RI
µL of N@LEG suspension was dropped onto the surface of GCE and then dried under an infrared
SC
lamp to acquire the N@LEG/GCE. Moreover, PANI-GCE and TE-LEG-GCE were obtained by
NU
the process mentioned above for comparison.
MA
2.5 Electrochemical measurements
Electrochemical measurements were implemented on an IGS6030 electrochemical
D
workstation (Guangzhou ingsens sensor technology Co., Ltd, China) with a conventional
PT E
three-electrode system consisting of a GCE working electrode, an Ag/AgCl saturated KCl reference electrode, and a platinum counter electrode. The CVs were implemented with the
CE
potential varied from -0.2 V to 0.6 V at a scan rate of 100 mV s-1. And the EIS measurements were
AC
carried out with the frequency from 0.1 Hz to 106 Hz and the amplitude of 5 mV. Both of them were executed in 5.0 mM Fe(CN)63-/4- solution containing 0.1 M KCl. Furthermore, SWASV was employed for the simultaneous determination of Cd(II) and Pb(II) with a deposition potential at -1.3 V for 210 s and a potential from -1.0 V to 0 V with 25 mV amplitude, 10 Hz frequency and 5 mV increment potential in 0.1 M NaAc/HAc buffer (pH=4.5) in the presence of 200 µg L-1 Bi(III). Prior to every experiment, a cleaning step by polarizing at 0.5 V for 60 s was adopted.
2.6 Preparation of samples 7
ACCEPTED MANUSCRIPT Real lake water samples were filtered twice through a 0.22 µm filter membrane before the measurements. Generally, 5.0 mL of lake water sample was mixed with 5.0 mL of 0.1 M NaAc/HAc buffer (pH 4.5) with 200 µg L-1 Bi(III)and then analyzed under the optimized SWASV.
PT
3. Results and discussion
RI
3.1 Surface characterization of N@LEG
SC
The surface morphologies of N@LEG were characterized by SEM. As shown in Fig. 1(a), it is clearly observed that there are rather compact 3D porous structures with different sizes on the
NU
surface of N@LEG. At higher magnification (Fig. 1(b)), there are typical 3D graphene
MA
frameworks of the stacked graphene sheets caused by laser scanning on PI films. This is due to the fact that the focused laser beams generated the instantaneous high temperature that causes the PI
D
decomposed into gaseous products so that the momentary gas spray resulted in the formation of
PT E
porous structures during the decomposition and graphitization processes.[11] It is because of the presence of the 3D porous stacked graphene sheets structures which provide such large specific
CE
surface areas and abundant reactive sites that facilitate the accumulation of metal ions and make
AC
contributions on the very wide detection range.
Fig. 1 (a) SEM image of N@LEG; (b) magnified SEM image of N@LEG.
8
ACCEPTED MANUSCRIPT In addition, the structure information of N@LEG was further analyzed by Raman spectroscopy. As exhibited in Fig. 2(a), the peaks of OE-PI@PANI are quite different from pure PANI or TE-LEG in peak numbers. As for the pure PANI, four prominent peaks located at 1163 cm-1, 1338 cm-1 and 1480 cm-1, which derive from the stretching vibration of C=C, C–N and C–H
PT
[36]. Besides, the Raman spectrum of the TE-LEG depicts three representative peaks of graphene,
RI
i.e. a D peak at 1350 cm-1, a G peak at 1585 cm-1 and 2D peak at 2700 cm-1 approximately[37].
SC
Since all of the above characteristic peaks appear in the Raman spectra of the OE-PI@PANI nanocomposite, it is certain that PANI was successfully combined with PI films after once laser
NU
engraved. Furthermore, just as the graphene obtained by directly laser etching PI sheets
MA
twice-TE-LEG, N@LEG also exhibits the D-band (at 1350 cm-1) corresponding to defects in disordered graphene flakes, the G-band (at 1585 cm-1) related to the hexagonal clamping mode of
D
graphite carbon, and 2D-band (at 2700 cm-1) deriving from the layer stacking pattern of carbon
PT E
atoms[38]. Additionally, the intensity ratio ID/IG, which is employed to evaluate the degree of defects and disorder in the sp2 hybridized graphitic carbon, are about 0.71 for N@LEG and 0.27
CE
for LEG, revealing the crystal defect and disorder degree ascended after compounding with PANI
AC
[39]. Despite that, the distinct 2D peak further illustrates the generation of 3D multilayer graphene [37], which is in accordance to with the SEM results. Nevertheless, the characteristic peaks of PANI does not appear in N@LEG, which might be due to the pyrolysis of PANI caused by the instantaneous high temperature generated during laser engraving[11]. The successful synthesis of 3D multilayer graphene with porous frameworks plays an important role in the very wide detection range of heavy metal sensors.
9
MA
NU
SC
RI
PT
ACCEPTED MANUSCRIPT
Fig. 2 (a) Raman spectra of PANI, OE-PI@PANI, TE-LEG and N@LEG; (b) XRD patterns of N@LEG; (c) XPS
PT E
D
survey spectra of TE-LEG and (d) N@LEG.
Furthermore, the structural information of N@LEG was also investigated by XRD. As shown
CE
in Fig. 2(b), N@LEG presents a distinct peak at 2θ =25.83° consistent with the typical C (002) plane of crystalline graphene, while the peak at 42.20° for the 100 plane is corresponding to an
AC
in-plane structure[40]. The XRD results are in agreement with Raman, which further proves the production of graphene.
To analyze the surface properties and the variation of the components of the TE-LEG and N@LEG nanocomposite, XPS was also performed. The XPS survey spectra of TE-LEG and N@LEG (Fig. 2(c) and Fig. 2(d)) reveal that both of them consist of C, N, O elements. The N element contents on the surface of TE-LEG and N@LEG are 0.09 at.% and 2.15 at.%, respectively. 10
ACCEPTED MANUSCRIPT Compared with TE-LEG, the N content of N@LEG increases, which is ascribed to the fact that the transient high temperature generated during the laser engraving process causes the PANI on the OE-PI@PANI film to be thermally decomposed[11]. The presence of N-doped graphene has a significant effect on the considerable wide detection range. The high-resolution curve-fitted XPS
PT
spectra and related analysis of TE-LEG and N@LEG in the C 1s, O 1s and N 1s regions are
RI
shown in Fig. S1(a-d) in Electronic Supplementary Materials (ESM). Moreover, the FTIR spectra
SC
of PANI, TE-LEG and N@LEG are displayed in Fig. S2. The FTIR results further justify the
3.2 Electrochemical behaviors of N@LEG.
NU
material as nitrogen-doped graphene. The specific graph and explanation are exhibited in ESM.
MA
Electrochemical characterizations of N@LEG were first studied by adopting [Fe(CN)6]3-/4- as electrochemical redox probes. Fig. 3(a) show the CVs of bare-GCE (curve a), PANI-GCE (curve
PT E
D
b), TE-LEG/GCE (curve c) and N@LEG/GCE (curve d) modified electrodes in 5.0 mM Fe(CN)63-/4- containing 0.1 M KCl. A pair of well-defined reversible redox peaks is exhibited at
CE
the bare GCE (curve a). Compared with the bare GCE (48.58 µA), modification with the PANI (61.68 µA) onto GCE surface will increase the anodic peak current of [Fe(CN)6]3-/4-, resulting
AC
from the good electrical conductivity of PANI which accelerates the electron transfer rate[24]. In addition, a larger peak current of [Fe(CN)6]3-/4- also attains with the modification of TE-LEG (60.66 µA) onto GCE, on account of the porous 3D graphene nanosheets that provide large specific areas for electrochemical reactions. Nevertheless, it is worth noting that N@LEG/GCE presents the highest peak currents (139.6 µA), which are more than 2-fold higher than other electrodes. This phenomenon indicates the fact that N@LEG has the best ability to facilitate the electron transfer as well as makes the fastest response to redox reactions. 11
ACCEPTED MANUSCRIPT Besides, the Nyquist plots are shown in Fig. S3. The resistance of 300 Ω on bare-GCE (curve a), 270 Ω PANI-GCE (curve b), and 260 Ω on TE-LEG/GCE (curve c) and 165 Ω on N@LEG/GCE (curve d) are observed respectively. The resistances change of these modified electrodes are consistent with the CV results, which not only verify that N@LEG was successfully
PT
modified on the GCE surface but also indicate the excellent electrical conductivity of N@LEG. In
RI
addition, the electrochemical surface area study (ESCA) related graphs and explanations are
SC
shown in Fig. S4 (ESM). The effective area was calculated to be 0.03 cm2 of bare-GCE and 0.06 cm2 of LEGCNs-GCE, respectively. The increased electrochemical activity surface area of
NU
LEGCNs-GCE (twice as large as bare-GCE) indicates that LEGCNs are beneficial to the
MA
improvement of the electrochemical performance and the adsorption of heavy metal ions. Moreover, the sensitivity is calculated to be 37.47 µA·µM-1·cm-2 for Cd(II) and
D
224.47µA·µM-1·cm-2 for Pb(II), respectively.
PT E
Furthermore, SWASV was performed for trace heavy metals determination in 0.1 M NaAc/HAc buffer (pH 4.5) accompanied by an in situ-incorporated Bi film with a concentration of
CE
200 µg L-1. The stripping voltammograms of 200µg L-1 Cd(II) and Pb(II) at different film-coated
AC
GCEs and bare GCE are presented in Fig. 3(b) (Bare-GCE: short dot line; PANI: dash dot line; TE-LEG: dash line; N@LEG: solid line). At the PANI modified GCE, the smallest stripping peaks of Cd(II) and Pb(II) are observed, suggesting that the PANI has a worst detection sensitivity of Cd(II) and Pb(II) so that it had better not be used to electrochemically detect them when compared to other electrodes. In contrast, at TE-LEG modified GCE, the stripping responses of Cd(II) and Pb(II) are much higher than bare GCE result from the large effective specific surface area which is beneficial to the adsorption of the probe metal ions. Most importantly, comparison with other 12
ACCEPTED MANUSCRIPT electrodes, N@LEG/GCE possesses not only the distinguishable and completely separated stripping peaks at almost -0.80 V (Cd(II)) and -0.55V (Pb(II)) but also the highest stripping signals, which revealed that N@LEG has wonderful affinity as well as excellent SWASV performance towards Cd(II) and Pb(II) due to the synergistic effect of LEG and N-doped. The analyses above
PT
certify that there are some merits at N@LEG/GCE: (1) 3D porous stacked graphene nanosheets
RI
structure provide a considerable large specific area to accelerate the electron transfer at interfaces;
SC
(2) multilayer stacked graphene nanosheets facilitate electron transfer and improve the conductivity; (3) The presence of N heteroatoms contributes to the structural stability and the
NU
affinity of metal ions. Thus, N@LEG is considered as a potential electrochemical sensor platform
CE
PT E
D
MA
for the simultaneous detection of Cd(II) and Pb(II).
AC
Fig. 3 (a) CVs of bare GCE (curve a), PANI (curve b), TE-LEG (curve c) and N@LEG (curve d) modified electrodes in 5 mM Fe(CN)63-/4- solution with 0.1 M KCl. Scan rate: 100 mV s-1; (b) SWASV responses of 200 µg L-1 Cd(II) and Pb(II) in 0.1 M NaAc/HAc buffer (pH 4.5) on the N@LEG (curve a), TE-LEG (curve b), bare GCE
(curve c) and PANI (curve d) modified electrodes. Deposition potential: -1.3 V. Deposition time: 210s. Bi(III) concentration: 200 µg L-1.
13
ACCEPTED MANUSCRIPT 3.3 Optimization of the determination conditions.
In order to improve the sensitivity of N@LEG/GCE in the determination of Cd(II) and Pb(II), several correlative factors were optimized via SWASV, such as (a) deposition potential; (b) deposition time; (c) pH; (d) the concentration of Bi(III). The optimal experimental conditions were
PT
listed as follows: (a) Deposition potential: -1.3 V; (b) Deposition time: 210 s; (c) Optimal pH: 4.5;
RI
(e) Bi(III) concentration: 200 µg·L-1. The specific charts and explanations are shown in Fig. S5 in
SC
Electronic Supplementary Materials (ESM)).
NU
3.4 Electrochemical determination of Cd(II) and Pb(II) using SWASV
MA
SWASV was employed to discuss the limit of detection and linear range of the N@LEG/GCE for the simultaneous determination of Cd(II) and Pb(II) under the optimized experimental
D
conditions. Fig. 4(a) depicts the SWASV curves of different concentrations of Cd(II) and Pb(II) in
PT E
0.1 M NaAc/HAc buffer (pH 4.5) containing 200 µg L-1 Bi(III) at N@LEG/GCE. The stripping peaks of Cd(II) and Pb(II) increase accompanied by the successive enhancement in probe metal
CE
ions concentration. And well-defined response peaks are observed at around -0.55 V and -0.80 V belonging to Cd(II) and Pb(II), respectively. The corresponding regression equations of Cd(II) and
AC
Pb(II) contain two wide linear ranges (Fig. 4(b)):
For Cd(II):
Ip (µA) = 0.04C (µg·L-1) + 1.64; (5 to 10 µg·L-1, R2 = 0.996) Ip (µA) = 0.14C (µg·L-1) +0.33; (10 to 380 µg·L-1, R2 = 0.991)
For Pb(II):
14
(1)
(2)
ACCEPTED MANUSCRIPT Ip (µA) = 0.13C (µg·L-1) + 1.86; (0.5 to 10 µg·L-1, R2 = 0.999)
(3)
Ip (µA) = 0.20C (µg·L-1) + 1.06; (10 to 380 µg·L-1, R2 = 0.997)
(4)
The reason for such wide linear ranges is due to the 3D porous stacked graphene sheets
PT
structures of N@LEG which provide large specific surface areas and abundant reactive sites that facilitate the accumulation of metal ions and the influence of N-doped graphene. Moreover, the
RI
limits of detection (LOD) (based on S/N = 3) is calculated according to the following formula:
SC
LOD =3 σB/b, in which σB is the standard deviation of the population of the blank responses and b
NU
is the slope of the regression line[1, 41, 42]. The LOD are 1.08 µg L-1 for Cd(II) and 0.16 µg L-1 for Pb(II), which are nearly 3 times and 60 times less than the guideline values of the drinking
MA
water presented by the World Health Organization (WHO), for Cd(II) and Pb(II), respectively. A comparison with the previously reported modified electrodes is given in Table 1. Apparently, the
PT E
D
new-designed N@LEG/GCE demonstrates lower or comparable detection limits and much wider linear ranges. In addition, N@LEG/GCE requires neither expensive instruments nor complicated
CE
and tedious processes. Thus, the fabricated sensor is applicable for sensitive and rapid determination of Cd(II) and Pb(II) with the merits of simple fabrication, easy operation and
AC
low-cost.
15
MA
NU
SC
RI
PT
ACCEPTED MANUSCRIPT
Fig. 4 (a) SWASV curves of Cd(II) and Pb(II) at 0.5, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 12.5, 15, 20, 40, 60, 80, 100, 120,
PT E
D
140,180, 220, 260, 300, 340 and 380 µg L-1 and (b) Corresponding calibration plots for Cd(II) at 6, 7, 8, 9, 10, 12.5, 15, 20, 40, 60, 80, 100, 120, 140,180, 220, 260, 300, 340 and 380 µg L-1 and Pb(II) at 0.5, 1, 2, 3, 4, 5, 6, 7, 8, 9,
CE
10, 12.5, 15, 20, 40, 60, 80, 100, 120, 140,180, 220, 260, 300, 340 and 380 µg L-1, respectively. (c-d) SWASV
responses and the corresponding calibration plots on N@LEG/GCE for the individual determination of Cd(II) at
AC
10, 50, 100, 150, 200 and 250 µg L-1, respectively. (e-f) SWASV responses and the corresponding calibration plots on N@LEG/GCE for the individual determination of Pb(II) at 10, 50, 100, 150, 200 and 250 µg L-1, respectively. Deposition potential: -1.3 V. Deposition time: 210s. Bi(III) concentration: 200 µg·L-1. Supporting electrolyte: 0.1
M acetate buffer (pH 4.5).
16
ACCEPTED MANUSCRIPT
Table 1 Comparison of our designed electrode for the determination of Cd(II) and Pb(II) with other modified
electrodes.
Linear range(µg L-1) Methods
References Pb(Ⅱ)
Cd(Ⅱ)
Pb(Ⅱ)
PT
Cd(Ⅱ)
Bi/Nafion/RGO-GNPs-GCE
SWASV
1–90
1–90
0.08
0.12
[13]
Bi/poly(p-ABSA)-GCE
DPASV
1–110
1–130
0.63
0.80
[43]
BiOCl/MWCNT-GCE
SWASV
5–50
RI
Electrodes
LOD(µg L-1)
1.20
0.57
[44]
RGO/Bi-CPE
DPASV
20–120
2.80
0.55
[45]
CB-15-crown-5-GCE
DPASV
15.7–191.9
10.9–186.5
4.70
3.30
[46]
Nafion/Bi/NMC-GCE
DPASV
2–10,10–100
0.5–10,10–100
1.50
0.05
[1]
Bi/Au-GN-Cys-GCE
SWASV
0.5-40
0.10
0.05
[12]
N@LEG/GCE
SWASV
1.08
0.16
This work
SC
5–50
MA
NU
20–120
D
0.5-40
0.5–10,10–380
PT E
5–10,10–380
RGO: reduced graphene oxide; GNPs: gold nanoparticles; Poly(p-ABSA): poly(p-aminobenzene sulfonic acid; DPASV: differential pulse
4-carboxybenzo-15-crown-5;
NMC:
nitrogen
doped
microporous
carbon
(NMC);
Au-GN-Cys:
gold
AC
CB-15-crown-5:
CE
anodic stripping voltammetry; BiOCl: bismuth-oxychloride; MWCNTs: multiwalled carbon nanotubes; CPE: carbon paste electrode;
nanoparticle-graphene-cysteine composite
3.5 Interference, repeatability, reproducibility and stability of N@LEG/GCE
Since the mutual interference between Cd(II) and Pb(II) during the simultaneous determination is so crucial for practical applications, an individual detection of Cd(II) or Pb(II) was conducted by altering one’s concentration whereas the concentration of another one was kept constant in the meanwhile. As seen in Fig. 4(c) and Fig. 4(d), the stripping signals of Cd(II) 17
ACCEPTED MANUSCRIPT ascend linearly over the range from 10 to 250 µg L-1 while the concentration of Pb(II) is kept at 50 µg L-1. However, the responses of Pb(II) fundamentally remain changeless at the same time. Analogous results are observed with the enhancement of the concentration of Pb(II) from 10 to 250 µg L-1 but fixing the concentration of Cd(II) in the meanwhile (Fig. 4(e) and Fig. 4(f)). As
PT
similar detection sensitivities of Cd(II) and Pb(II) are obtained (0.09 versus 0.04 for Cd(II) and
RI
0.19 versus 0.13 for Pb(II)) when compared with the results found in simultaneous determination,
SC
the results suggest that there is little mutual interference between Cd(II) and Pb(II).
NU
Aside from the mutual interference, the presence of non-target metal ions also disturbs the SWASV determination of target metal ions. To evaluate the anti-interference performance of the
MA
proposed sensor, various interfering metal ions (including Zn(II), Co(II), Ni(II), Cu(II), Mg(II), Cr(II), Fe(III), Mn(II), As(II), Hg(II) and Al(II)) were added to 0.1 M NaAc/HAc buffer (pH 4.5)
D
containing 50 µg L-1 Cd(II) and Pb(II) by SWASV under the optimum conditions. Fig. 5(a) shows
PT E
that 50-fold Zn(II), Co(II), Ni(II), Mg(II), Cr(II), Fe(III), Mn(II), As(II) and Al(II) have no distinct influences on response signals and the tolerance ratio was measured to be 4.15% at most. However,
CE
10-fold Cu(II) results in less than 30.33% peak current decrease, while 10-fold Hg(II) is calculated
AC
to be less than 26.90% peak current increase. This suppression effect is likely due to the formation of intermetallic compounds as well as competition for active sites on the surface of the electrode, reported previously[47-49]. Since the Cu2[Fe(CN)6] has a larger pKsp valueand is therefore more insoluble. And the hexacyanoferrate(II) was not found to have any effect on the Cd(II) and Pb(II) peaks except at concentrations above 0.1 M when a small drop in response was noted. Therefore, the Cu(II) interference can be reduced by the addition of 0.1 mM ferrocyanide to the sample extract solutions before analysis to form an insoluble and stable copper-ferrocyanide complex with 18
ACCEPTED MANUSCRIPT the help of a ligand[49]. In addition, it is obvious that the stripping peak currents of Cd(II) and Pb(II) are significantly increased when Hg(II) coexist, which is attributed to competition the formation of an amalgam as well as the competition between electrodeposited bismuth and Hg for surface sites on the electrode[47, 50]. Actually, in order to improve the sensitivity, the hanging
PT
mercury drop electrode (HMDE) and the mercury film electrode have been widely used in the
RI
electrochemical determination of heavy metal ions[48, 51]. Thus, the formation of mercury film
SC
and followed by the Metal-Hg intermetallic compound formation on the surface of the electrode increase the peak current for heavy metal ions. Overall, the presence of Hg strengthens the
NU
sensitivity in the detection of heavy metal ions[52]. Thus, the above results indicated the
MA
N@LEG/GCE had satisfactory anti-interference ability.
In addition, in the interference experiments, we also studied the effects of several organic
D
substances with 300-fold concentration. The 300-fold concentration of testing substances was
PT E
introduced into the sample which contained 50 µg·L-1 Cd(II) and Pb(II) and 200 µg·L-1 Bi(III). As shown in Fig. 5(b), the presence of chloroform (CH3Cl) has almost no effect on the response
CE
signals, the tolerance ratio of which is 1.3%. However, the complexing agents such as
AC
ethylenediaminetetraacetic acid disodium salt (EDTA-2Na) and citric acid, have an inhibitory effect on the test results, which will weaken or even eliminate the stripping signals of Cd(II) and Pb(II), especially the EDTA, whose presence causes the signals to almost disappear). On the contrary, the surface active substances such as sodium dodecyl benzene sulfonate (SDBS) and sodium laurylsulfonate (SDS) have an increased effect on the detection signal, whose tolerance ratio is 12.6% and 15.8%. As for formaldehyde (CH3CHO), both of the stripping signals of Cd(II) and Pb(II) weaken and the tolerance ratio is 16.6%. Therefore, this sensor is not suitable for 19
ACCEPTED MANUSCRIPT systems containing complexing agents or complex organic substances.
The repeatability was appraised by the relative standard deviation (RSD %) of ten repetitive experiments of SWASV (Fig. S6). The RSDs are 3.85% and 3.47% of each of Cd(II) and Pb(II), which manifest the wonderful repeatability performance of the N@LEG/GCE. The reproducibility
PT
was next judged with five different N@LEG/GCE and the RSDs are 7.12% for Cd(II) and 6.87%
RI
for Pb(II). The results indicate that the preparation procedures are reliable and the prepared sensor
SC
has excellent reproducibility. The stability was evaluated after two weeks of storage at room
NU
temperature. The RSDs are 5.54% for Cd(II) and 6.15% for Pb(II), so the prepared sensor
CE
PT E
D
MA
possesses long-time stability.
Fig. 5 (a-b) Selectivity of N@LEG/GCE for simultaneous detection of Cd(II) and Pb(II). Deposition potential: -1.3
AC
V. Deposition time: 210s. Cd(II) and Pb(II) concentration: 50 µg·L-1. Bi(III) concentration: 200 µg·L-1. Supporting
electrolyte: 0.1 M acetate buffer (pH 4.5).
3.6 Real sample analysis
To quantify of Cd(II) and Pb(II) in real samples and estimate the applicability of N@LEG/GCE, standard addition method was carried out in real lake water sample. The lake 20
ACCEPTED MANUSCRIPT water was treated by diluting with 0.1 M acetate buffer (pH 4.5) containing 200 µg L-1 Bi(III) (v:v=1:1). The results are listed in Table 2 and the recoveries of Cd(II) and Pb(II) vary from 97.80% to 113.65%. Furthermore, the results obtained are in accordance with the AAS method. Hence, N@LEG/GCE sensor has excellent accuracy and recovery, indicating the promising
RI
PT
application for the determination of Cd(II) and Pb(II) in practical samples.
Found by AAS(µg L-1)
Sample Cd(Ⅱ)
Pb(Ⅱ)
Cd(Ⅱ)
Pb(Ⅱ)
5.58
6.12
/
/
5.82
10
10
10.35
20
20
18.90
30
30
Pb(Ⅱ)
4.85
/
/
10.62
9.78
106.20
97.80
19.87
22.73
21.07
113.65
105.35
31.32
29.55
33.73
98.50
112.43
10.11
PT E
D
Lake water
CE
29.76
Recovery/%
Cd(Ⅱ)
MA
Cd(Ⅱ) Pb(Ⅱ)
Found by proposed method(µg L-1)
NU
Added (µg L-1)
SC
Table 2 Recovery for the determination of Cd(II) and Pb(II) in lake water (n = 3) .
AC
4. Conclusions
In the present work, the laser engraving technique provides a facile and novel method for efficient and large-scale fabrication of high-quality 3D porous graphene-based electrode matrices. By introducing PANI as N-dopant after once laser engraving PI sheets, the resulting OE-PI@PANI was subjected to the secondary etching so that the surface PANI was decomposed by the instantaneous high temperature generated during the laser engraving process[11], thereby synthesizing the N@LEG. The N@LEG possesses 3D porous stacked graphene morphologies 21
ACCEPTED MANUSCRIPT with large specific surface areas and the unique metal ions affinity of N atoms, which are conducive to the accumulation of HMI and the improvement of the quite wide detection ranges. Moreover, the simultaneous detection of Cd(II) and Pb(II) is achieved in terms of SWASV with high selectivity, extremely wide linear range and low detection limit. The quite wide linear ranges
PT
vary from 5 to 380 g L-1 for Cd(II), and 0.5 to 380 µg L-1 for Pb(II), respectively. In addition, the
RI
detection limits were calculated to be 1.08 g L-1 (S/N = 3) for Cd(II) and 0.16 g L-1 (S/N = 3) for
SC
Pb(II), which were nearly 3 times and 60 times less than the guideline values of the drinking water presented by the World Health Organization (WHO), for Cd(II) and Pb(II), respectively. In the
sensitivity is
calculated
to be 37.47 µA·µM-1·cm-2
NU
addition,
for
Cd(II)
and
MA
224.47µA·µM-1·cm-2 for Pb(II), respectively. The facile preparation process and satisfactory analytical performance of the proposed sensor indicate a promising application towards detection
D
of Cd(II) and Pb(II) in real water. In the future, abundant electrochemical sensors with such wide
PT E
detection ranges can be fabricated according to the above proposed method as well as expand
CE
in-field miniaturized or wearable sensing platforms.
AC
Acknowledgments
This work was supported by National Natural Science Foundation of China (NSFC, No. 21875070), Guangdong Nature Science Foundation (Project No. 2017A030312005), and Guangzhou Science Technology and Innovation Commission (No. 201508020010). We also wish to thank the engineer Qian Liu from Shiyanjia lab for help with the XPS analysis.
22
ACCEPTED MANUSCRIPT References [1] L. Xiao, H. Xu, S. Zhou, T. Song, H. Wang, S. Li, W. Gan, Q. Yuan, Simultaneous detection of Cd(II) and Pb(II)
by differential pulse anodic stripping voltammetry at a nitrogen-doped microporous carbon/Nafion/bismuth-film
electrode, Electrochim. Acta 143 (2014) 143-151.
PT
[2] X. Zhang, Y. Zhang, D. Ding, J. Zhao, J. Liu, W. Yang, K. Qu, On-site determination of Pb 2+ and Cd 2+ in
RI
seawater by double stripping voltammetry with bismuth-modified working electrodes, Microchem. J. 126 (2016)
SC
280-286.
NU
[3] R.O. Kadara, I.E. Tothill, Stripping chronopotentiometric measurements of lead(II) and cadmium(II) in soils
extracts and wastewaters using a bismuth film screen-printed electrode assembly, Anal. Bioanal. Chem. 378(3)
MA
(2004) 770-5.
[4] Z. Bi, C.S. Chapman, P. Salaün, C.M.G. van den Berg, Determination of Lead and Cadmium in Sea- and
D
Freshwater by Anodic Stripping Voltammetry with a Vibrating Bismuth Electrode, Electroanalysis 22(24) (2010)
PT E
2897-2907.
[5] Z. Wang, H. Wang, Z. Zhang, G. Liu, Electrochemical determination of lead and cadmium in rice by a
CE
disposable bismuth/electrochemically reduced graphene/ionic liquid composite modified screen-printed electrode,
AC
Sens. Actuators, B 199 (2014) 7-14.
[6] Z. Lu, J. Zhang, W. Dai, X. Lin, J. Ye, J. Ye, A screen-printed carbon electrode modified with a bismuth film
and gold nanoparticles for simultaneous stripping voltammetric determination of Zn(II), Pb(II) and Cu(II),
Microchim. Acta 184(12) (2017) 4731-4740.
[7] Z. Lu, W. Dai, B. Liu, G. Mo, J. Zhang, J. Ye, J. Ye, One pot synthesis of dandelion-like polyaniline coated gold
nanoparticles composites for electrochemical sensing applications, J. Colloid Interface Sci. 525 (2018) 86-96.
[8] C. Gao, X.-J. Huang, Voltammetric determination of mercury(II), TrAC, Trends Anal. Chem. 51 (2013) 1-12.
23
ACCEPTED MANUSCRIPT
[9] A.K.G.K.S. Novoselov, The rise of graphene, Nat. Mater. 6 (2007) 183–191.
[10] K.T. Paula, G. Gaál, G.F.B. Almeida, M.B. Andrade, M.H.M. Facure, D.S. Correa, A. Riul, V. Rodrigues, C.R.
Mendonça, Femtosecond laser micromachining of polylactic acid/graphene composites for designing interdigitated
microelectrodes for sensor applications, Opt. Laser Technol. 101 (2018) 74-79.
PT
[11] Z. Zhang, M. Song, J. Hao, K. Wu, C. Li, C. Hu, Visible light laser-induced graphene from phenolic resin: A
RI
new approach for directly writing graphene-based electrochemical devices on various substrates, Carbon 127
SC
(2018) 287-296.
[12] L. Zhu, L. Xu, B. Huang, N. Jia, L. Tan, S. Yao, Simultaneous determination of Cd(II) and Pb(II) using square
MA
electrode, Electrochim. Acta 115 (2014) 471-477.
NU
wave anodic stripping voltammetry at a gold nanoparticle-graphene-cysteine composite modified bismuth film
[13] G. Zhao, H. Wang, G. Liu, Z. Wang, J. Cheng, Simultaneous determination of trace Cd(II) and Pb(II) based on
D
Bi/Nafion/reduced graphene oxide-gold nanoparticle nanocomposite film-modified glassy carbon electrode by
PT E
one-step electrodeposition, Ionics 23(3) (2016) 767-777.
[14] J. Li, S. Guo, Y. Zhai, E. Wang, High-sensitivity determination of lead and cadmium based on the
CE
Nafion-graphene composite film, Anal. Chim. Acta 649(2) (2009) 196-201.
AC
[15] N. Ruecha, N. Rodthongkum, D.M. Cate, J. Volckens, O. Chailapakul, C.S. Henry, Sensitive electrochemical
sensor using a graphene-polyaniline nanocomposite for simultaneous detection of Zn(II), Cd(II), and Pb(II), Anal.
Chim. Acta 874 (2015) 40-8.
[16] H. Tao, X. Yang, L. Zhang, S. Ni, One-step synthesis of nickel sulfide/N-doped graphene
composite as anode materials for lithium ion batteries, J. Electroanal. Chem. 739 (2015) 36-42. [17] X. Lv, G. Li, H. Zhou, D. Li, J. Zhang, Z. Pang, P. Lv, Y. Cai, F. Huang, Q. Wei, Novel freestanding
N-doped carbon coated Fe3O4 nanocomposites with 3D carbon fibers network derived from bacterial
24
ACCEPTED MANUSCRIPT
cellulose for supercapacitor application, J. Electroanal. Chem. 810 (2018) 18-26. [18] Y. Luan, Y. Huang, L. Wang, M. Li, R. Wang, B. Jiang, Porous carbon@MnO2 and nitrogen-doped porous
carbon from carbonized loofah sponge for asymmetric supercapacitor with high energy and power density, J.
Electroanal. Chem. 763 (2016) 90-96.
PT
[19] X. Zhou, Q. Liao, J. Tang, T. Bai, F. Chen, J. Yang, A high-level N-doped porous carbon nanowire modified
RI
separator for long-life lithium–sulfur batteries, J. Electroanal. Chem. 768 (2016) 55-61.
SC
[20] F. Cao, L. Zhang, Y. Tian, A novel N-doped carbon nanotube fiber for selective and reliable electrochemical
determination of ascorbic acid in rat brain microdialysates, J. Electroanal. Chem. 781 (2016) 278-283.
NU
[21] H. Xing, J. Xu, X. Zhu, X. Duan, L. Lu, W. Wang, Y. Zhang, T. Yang, Highly sensitive simultaneous
MA
determination of cadmium (II), lead (II), copper (II), and mercury (II) ions on N-doped graphene modified
electrode, J. Electroanal. Chem. 760 (2016) 52-58.
D
[22] M. Li, Z. Wu, W. Ren, H. Cheng, N. Tang, W. Wu, W. Zhong, Y. Du, The doping of reduced graphene oxide
PT E
with nitrogen and its effect on the quenching of the material’s photoluminescence, Carbon 50(14) (2012)
5286-5291.
CE
[23] Y. Liu, X. Gong, W. Dong, R. Zhou, S. Shuang, C. Dong, Nitrogen and phosphorus dual-doped carbon dots as
AC
a label-free sensor for Curcumin determination in real sample and cellular imaging, Talanta 183 (2018) 61-69.
[24] L. Wang, X. Lu, S. Lei, Y. Song, Graphene-based polyaniline nanocomposites: preparation, properties and
applications, J. Mater. Chem. A 2(13) (2014) 4491-4509.
[25] C. Lei, Synthesis of N-doped Graphene for Simultaneous Electrochemical Detection of Lead and Copper in
Water, International Journal of Electrochemical Science
(2017) 4856-4866.
[26] S. Barg, F.M. Perez, N. Ni, P.V. Pereira, R.C. Maher, E. Garcia-Tunon, S. Eslava, S. Agnoli, C.
Mattevi, E. Saiz, Mesoscale assembly of chemically modified graphene into complex cellular networks,
25
ACCEPTED MANUSCRIPT
Nat. Commun. 5 (2014) 4328. [27] Y. Xu, K. Sheng, C. Li, G. Shi, Self-Assembled Graphene Hydrogel via a One-Step Hydrothermal
Process, ACS. Nano. 4(7) (2010) 4324-4330. [28] M.F. El-Kady, V. Strong, S. Dubin, R.B. Kaner, Laser Scribing of High-Performance and Flexible
PT
Graphene-Based Electrochemical Capacitors, Science 335(6074) (2012) 1326-1330.
RI
[29] R. Arul, R.N. Oosterbeek, J. Robertson, G. Xu, J. Jin, M.C. Simpson, The mechanism of direct laser writing of
SC
graphene features into graphene oxide films involves photoreduction and thermally assisted structural
rearrangement, Carbon 99 (2016) 423-431.
NU
[30] J. Lin, Z. Peng, Y. Liu, F. Ruiz-Zepeda, R. Ye, E.L.G. Samuel, M.J. Yacaman, B.I. Yakobson, J.M.
MA
Tour, Laser-induced porous graphene films from commercial polymers, Nat. Commun. 5 (2014) 5714. [31] R. Ye, Y. Chyan, J. Zhang, Y. Li, X. Han, C. Kittrell, J.M. Tour, Laser-Induced Graphene Formation on Wood,
D
Adv. Mater. 29(37) (2017).
PT E
[32] H. Liu, M. Li, R.B. Kaner, S. Chen, Q. Pei, Monolithically Integrated Self-Charging Power Pack
Consisting of a Silicon Nanowire Array/Conductive Polymer Hybrid Solar Cell and a Laser-Scribed
CE
Graphene Supercapacitor, ACS Appl. Mater. Interfaces 10(18) (2018) 15609-15615.
AC
[33] S. Lin, W. Feng, X. Miao, X. Zhang, S. Chen, Y. Chen, W. Wang, Y. Zhang, A flexible and highly
sensitive nonenzymatic glucose sensor based on DVD-laser scribed graphene substrate, Biosens. Bioelectron. 110 (2018) 89-96.
[34] R.L. Calabro, D. Yang, D.Y. Kim, Liquid-phase laser ablation synthesis of graphene quantum dots
from carbon nano-onions: Comparison with chemical oxidation, J. Colloid Interface Sci. 527 (2018) 132-140. [35] X. Lin, Z. Lu, Y. Zhang, B. Liu, G. Mo, J. Li, J. Ye, A glassy carbon electrode modified with a bismuth film
26
ACCEPTED MANUSCRIPT
and laser etched graphene for simultaneous voltammetric sensing of Cd(II) and Pb(II), Microchim. Acta 185(9)
(2018) 438.
[36] N. Song, W. Wang, Y. Wu, D. Xiao, Y. Zhao, Fabrication of highly ordered polyaniline nanocone on pristine
graphene for high-performance supercapacitor electrodes, J. Phys. Chem. Solids 115 (2018) 148-155.
RI
Electrodes for Aptamer-Based Biosensing, ACS Sens 2(5) (2017) 616-620.
PT
[37] C. Fenzl, P. Nayak, T. Hirsch, O.S. Wolfbeis, H.N. Alshareef, A.J. Baeumner, Laser-Scribed Graphene
SC
[38] R. Hua, N. Hao, J. Lu, J. Qian, Q. Liu, H. Li, K. Wang, A sensitive Potentiometric resolved
ratiometric Photoelectrochemical aptasensor for Escherichia coli detection fabricated with non-metallic
NU
nanomaterials, Biosens. Bioelectron. 106 (2018) 57-63.
MA
[39] F. Wang, K. Wang, X. Dong, X. Mei, Z. Zhai, B. Zheng, J. Lv, W. Duan, W. Wang, Formation of hierarchical
porous graphene films with defects using a nanosecond laser on polyimide sheet, Appl. Surf. Sci. 419 (2017)
D
893-900.
PT E
[40] S.P. Singh, Y. Li, A. Be'er, Y. Oren, J.M. Tour, C.J. Arnusch, Laser-Induced Graphene Layers and
Electrodes Prevents Microbial Fouling and Exerts Antimicrobial Action, ACS Appl. Mater. Interfaces
CE
9(21) (2017) 18238-18247.
AC
[41] E. Desimoni, B. Brunetti, Presenting Analytical Performances of Electrochemical Sensors. Some Suggestions,
Electroanalysis 25(7) (2013) 1645-1651.
[42] Z. Lu, W. Dai, X. Lin, B. Liu, J. Zhang, J. Ye, J. Ye, Facile one-step fabrication of a novel 3D honeycomb-like
bismuth nanoparticles decorated N-doped carbon nanosheet frameworks: Ultrasensitive electrochemical sensing of
heavy metal ions, Electrochim. Acta 266 (2018) 94-102.
[43] Y. Wu, N.B. Li, H.Q. Luo, Simultaneous measurement of Pb, Cd and Zn using differential pulse anodic
stripping voltammetry at a bismuth/poly(p-aminobenzene sulfonic acid) film electrode, Sens. Actuators, B 133(2)
27
ACCEPTED MANUSCRIPT
(2008) 677-681.
[44] S. Cerovac, V. Guzsvany, Z. Konya, A.M. Ashrafi, I. Svancara, S. Roncevic, A. Kukovecz, B. Dalmacija, K.
Vytras, Trace level voltammetric determination of lead and cadmium in sediment pore water by a
bismuth-oxychloride particle-multiwalled carbon nanotube composite modified glassy carbon electrode, Talanta
PT
134 (2015) 640-649.
RI
[45] P.K. Sahoo, B. Panigrahy, S. Sahoo, A.K. Satpati, D. Li, D. Bahadur, In situ synthesis and properties of
SC
reduced graphene oxide/Bi nanocomposites: As an electroactive material for analysis of heavy metals, Biosens.
Bioelectron. 43 (2013) 293-296.
NU
[46] N. Serrano, A. Gonzalez-Calabuig, M. Del Valle, Crown ether-modified electrodes for the simultaneous
MA
stripping voltammetric determination of Cd(II), Pb(II) and Cu(II), Talanta 138 (2015) 130-137.
[47] L. Shi, Y. Li, X. Rong, Y. Wang, S. Ding, Facile fabrication of a novel 3D graphene framework/Bi
D
nanoparticle film for ultrasensitive electrochemical assays of heavy metal ions, Anal. Chim. Acta 968 (2017)
PT E
21-29.
[48] R. María-Hormigos, M.J. Gismera, J.R. Procopio, M.T. Sevilla, Disposable screen-printed electrode modified
CE
with bismuth–PSS composites as high sensitive sensor for cadmium and lead determination, J. Electroanal. Chem.
AC
767 (2016) 114-122.
[49] K. Crowley, J. Cassidy, Trace Analysis of Lead at a Nafion-Modified Electrode Using
Square-Wave Anodic Stripping Voltammetry, Electroanalysis 14(15-16) (2002) 1077-1082. [50] Y. Cheng, H. Fa, W. Yin, C. Hou, D. Huo, F. Liu, Y. Zhang, C. Chen, A sensitive electrochemical
sensor for lead based on gold nanoparticles/nitrogen-doped graphene composites functionalized with l-cysteine-modified electrode, J. Solid State Electrochem. 20(2) (2015) 327-335. [51] W. Li, X. Yao, Z. Guo, J. Liu, X. Huang, Fe3O4 with novel nanoplate-stacked structure:
28
ACCEPTED MANUSCRIPT
Surfactant-free hydrothermal synthesis and application in detection of heavy metal ions, J. Electroanal. Chem. 749 (2015) 75-82. [52] Y. Sun, W. Chen, W. Li, T. Jiang, J. Liu, Z. Liu, Selective detection toward Cd2+ using
Fe3O4/RGO nanoparticle modified glassy carbon electrode, J. Electroanal. Chem. 714-715 (2014)
AC
CE
PT E
D
MA
NU
SC
RI
PT
97-102.
29
ACCEPTED MANUSCRIPT
PT E
D
MA
NU
SC
RI
PT
Graphical abstract
Schematic illustration of the fabrication process of the nitrogen-doped laser engraved graphene
CE
modified glassy carbon electrode (N@LEG-GCE) for the simultaneous determination of cadmium
AC
(Cd(II)) and lead (Pb(II)) by square wave anodic stripping voltammetry (SWASV).
30
ACCEPTED MANUSCRIPT
Highlights 1. The 3D porous nitrogen-doped laser engraved graphene (N@LEG) was easily fabricated by laser engraving technique.
PT
2. The sensor possessed very wide detection ranges due to the large specific surface areas of 3D
RI
porous stacked graphene sheets structures and the influence of nitrogen-doped graphene.
SC
3. The sensor exhibited quite wide linear ranges varying from 5 to 10 g L-1 and 10 to 380 g L-1 for
AC
CE
PT E
D
MA
NU
Cd(II), and 0.5 to 10 µg L-1 and 10 µg L-1 to 380 µg L-1 for Pb(II), respectively.
31
Xueni Lin, Zhiwei Lu, Wanlin Dai, Baichen Liu, Yuxin Zhang, Junye Li, Jianshan Ye PII: DOI: Reference:
S1572-6657(18)30605-2 doi:10.1016/j.jelechem.2018.09.016 JEAC 12599
To appear in:
Journal of Electroanalytical Chemistry
Received date: Revised date: Accepted date:
22 June 2018 4 September 2018 5 September 2018
Please cite this article as: Xueni Lin, Zhiwei Lu, Wanlin Dai, Baichen Liu, Yuxin Zhang, Junye Li, Jianshan Ye , Laser engraved nitrogen-doped graphene sensor for the simultaneous determination of Cd(II) and Pb(II). Jeac (2018), doi:10.1016/ j.jelechem.2018.09.016
This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
ACCEPTED MANUSCRIPT Laser engraved nitrogen-doped graphene sensor for the simultaneous determination of Cd(II) and Pb(II)
College of Chemistry and Chemical Engineering, South China University of
RI
a
PT
Xueni Lina, Zhiwei Lua, Wanlin Daia, Baichen Liua, Yuxin Zhanga, Junye Lib, Jianshan Yea,*
b
SC
Technology, Guangzhou 510641, P.R. China
The Affiliated High School of South China Normal University, Guangzhou 510630,
AC
CE
PT E
D
MA
NU
P.R. China
Corresponding author at: College of Chemistry and Chemical Engineering, South China University of Technology, Guangzhou 510641, P.R. China. Tel.: +86 20 87113241. E-mail: [email protected] (J. Ye)
ACCEPTED MANUSCRIPT Abstract Recently, graphene-based nanomaterials have attracted widespread attention as new electrode-modified materials for different electrochemical sensing platforms. However, graphene-based nanomaterials modified heavy metal sensors often have the disadvantages in that
PT
their detection ranges are not wide enough. To solve this problem, an easy and feasible approach
RI
derived from laser engraving technique to fabricate a high-quality 3D porous graphene-based
SC
heavy metal sensor with a quite wide detection range was established. The nitrogen-doped laser
NU
engraved graphene (N@LEG) was synthesized via introducing polyaniline (PANI) and polyvinylpyrrolidone (PVP) as N-dopant. Herein, by coupling the unique electrochemical
MA
properties and the 3D porous structure framework with large electrochemical active surface areas of LEG with the strong metal ions affinity of N atoms, N@LEG modified glassy carbon electrode
D
(N@LEG/GCE) with in-situ bismuth film modification has been successfully utilized for the
PT E
simultaneous determination of Cd(II) and Pb(II) using square wave anodic stripping voltammetry (SWASV). After optimizing conditions, the proposed sensor exhibits quite wide linear ranges
CE
varying from 5 to 10 g L-1 and 10 to 380 g L-1 for Cd(II), and 0.5 to 10 µg L-1 and 10 µg L-1 to 380
AC
µg L-1 for Pb(II), respectively. In addition, the detection limits are calculated to be 1.08 g L-1 (S/N = 3) for Cd(II) and 0.16 g L-1 (S/N = 3) for Pb(II), which are nearly 3 times and 60 times less than the guideline values of the drinking water presented by the World Health Organization (WHO), for Cd(II) and Pb(II), respectively. Furthermore, the results describe satisfactory advantages of remarkable sensitivity, selectivity, anti-interference, repeatability, reproducibility and stability. Besides, the fabricated sensor is proved to be a potential perspective to detect Cd(II) and Pb(II) in actual water samples.
ACCEPTED MANUSCRIPT
Keywords: Electrochemical determination; Modified electrode; Electrochemical impedance
AC
CE
PT E
D
MA
NU
SC
RI
PT
spectroscopy (EIS); Cyclic voltammetry (CV); Raman; Heavy metal.
ACCEPTED MANUSCRIPT 1. Introduction At present, due to the toxicity, stability and non-biodegradability of heavy metal ions (HMI) even trace amounts, which have a harmful impact on various environmental components, involving terrestrial and aquatic biota, the effective determination of them is of great significant[1].
PT
The routine techniques used widely for the HMI determination, including atomic absorption
RI
spectroscopy (AAS) and inductively coupled plasma mass spectrometry (ICP-MS), etc., have
SC
several defects such as time-consuming, high-cost, requirement for cumbersome instrumentation
NU
and in particular unsuitability for on-spot monitoring[2, 3]. Compared with spectroscopic methods, electrochemical methods, especially anodic stripping voltammetry (ASV) have been generally
MA
regarded as a simple and efficient tool to detect HMI owing to their superiority of low-cost, satisfactory sensitivity, fast response, portable instruments, easy to operate and the possibility of
D
on-site analysis[2, 4-7]. ASV measurements often contain a pre-concentration step and a stripping
PT E
step on working electrode surface[8]. Therefore, the choice of good performance working electrode modified materials makes contributions to improving the electrochemical analysis.
CE
Graphene, a kind of carbon nanomaterials with a unique 2D hexagonal structure of
AC
sp2-hybridized carbon, has caused extensive attention recently due to its high specific area, unique electrical conductivity, self-assembly behavior and mechanical flexibility[9, 10]. Studies have shown that the porous structure of graphene could possess a large specific area as well as have access to an effective multidimensional pathway for mass transfer and electron transport[11]. Graphene-based sensors have been widely applied to the detection of glucose, dopamine and heavy metal ions. Although most graphene-based heavy metal sensors have low detection limits,[5, 12-14] there are few reports on graphene-based heavy metal sensors with fairly wide linear 1
ACCEPTED MANUSCRIPT ranges[15]. So it is an urgent requirement to find a method for the preparation of graphene-based heavy metal sensors with considerable wide detection ranges. On the other hand, functionalization or edge/basal plane doping plays a vital role in the electrical properties of graphene and its derivatives. Thus, various doped graphene-based nanomaterials, especially doped with
PT
heteroatoms (e.g., N, B, S and Cl), have been greatly expanded the applications of battery[16],
RI
supercapacitor[17, 18], non-metal electrocatalysis[19] and electrochemical sensing[20, 21].
SC
Among them, N-doping has attracted wide concern on account of N atoms comparatively strong electron affinity to improve the electrochemical activity and excellent compatibility with the
NU
carbon matrix[1]. Besides, N-doping could lead to defect sites by replacing C atoms, which
MA
allowed potential active sites to ameliorate electrochemical activities of graphene-based nanomaterials[22, 23]. In addition, PANI, one of the most vital conducting polymers, has been
D
utilized for the application of electrochemical sensors owing to its satisfactory conductivity, ease
PT E
of synthesis and fairly non-poisonous[24]. So far, the nitrogen-containing polymer, polyvinylpyrrolidone (PVP), also has been considered as N-dopant[1]. Moreover, PVP can prevent
CE
the nanoparticle aggregation during the synthesis.[15] Up to now, N-doped graphene-based
AC
electrochemical sensors have been reported for the determination of heavy metals, but their detection range is narrower.[14, 25] In this work, an N-doped graphene-based heavy metal sensor was prepared by introducing PANI and PVP as N-dopant to improve the detection ranges. Although there are many strategies for the synthesis of graphene, they require either high temperature treatments or complex and time-consuming chemical preparation routes,[26, 27] which hinder their application due to the poor efficiency and time-consuming operations. Hence, it is an urgent need to develop a method capable of fabricating graphene at low-cost, high-efficiency, 2
ACCEPTED MANUSCRIPT and large-scale to meet actual demand. In recent years, LEG technique has achieved rapid development and the LEG has opened up a new horizon for electrochemical applications. With a standard Light Scribe DVD drive, El-Kady et al.[28] have produced the reduced graphene oxide patterns via direct laser scribing graphene oxide, which opened up a new direction for the direct
PT
on-chip manufacture of micro supercapacitors. Arul et al.[29] have also investigated the
RI
mechanism of forming graphene features by scribing with a variety of laser sources. Lin et al.[30]
SC
has successfully simplified the preparation of graphene via a one-step laser scribing on a flexible commercial-available PI sheet with a CO2 infrared laser. The resultant sheets were named as laser
NU
scribed graphene (LSG) with remarkable electron conductivity and large surface area and could be
MA
directly used as supercapacitor electrodes without any additives. Using the process similar to that reported previously using CO2 laser, the graphene layer could be formed on the pinewood, a
D
natural and renewable material[31]. With the advantages of a 3D mesoporous framework,
PT E
outstanding conductivity and electroactivity, LEG has been applied to supercapacitors[32], sensors[33], and so on[34]. Therefore, an easy and rapid method, laser engraving technique, was
CE
adopted to prepare a graphene-based heavy metal sensing platform with 3D porous structures. It
AC
was because of the 3D porous structure framework with such a large electrochemical active surface area of LEG that made contributions on the rather wide detection range. Our group have reported a glassy carbon electrode modified with a bismuth film and laser etched graphene for simultaneous voltammetric sensing of Cd(II) and Pb(II)[35]. Besides, to the best of our knowledge, there is no report on the application of laser engraving technique to prepare N-doped graphene-based electrodes for the detection of HIM in real water samples.
In this paper, we fabricated 3D porous graphene-based electrode matrices by the simple and 3
ACCEPTED MANUSCRIPT rapid laser engraving technique, and then synthesized N@LEG via introducing PANI and PVP as N-dopant. Consequently, by combining the unique electrochemical properties and large electrochemical active surface area of LEG with the strong metal ions affinity of N atoms, newly-designed N@LEG/GCE shows excellent responses for the simultaneous determination of
PT
Cd(II) and Pb(II) with such a wide detection range in virtue of square wave anodic stripping
RI
voltammetry (SWASV). Moreover, the facile and fast preparation and the extremely wide linear
SC
range indicate that the sensor is promising and ideal for the applications of HMI sensing. Additionally, the acquisition of 3D porous N@LEG sheds light on the preparation of graphene and
AC
CE
PT E
D
MA
ranges based on laser engraving technique.
NU
graphene-based heavy metal sensors with comparable detection limits and fairly wide linear
Scheme.1 Schematic illustration of the fabrication process of N@LEG electrodes for the electrochemical
simultaneous detection of Cd(II) and Pb(II).
4
ACCEPTED MANUSCRIPT 2. Experimental 2.1 Materials and Reagents
Commercial PI sheets (thickness: 0.125 mm) were purchased from Shenzhen Golden Green
PT
Leaf Technology Co., Ltd. Potassium ferricyanide (K3[Fe(CN)6]), Potassium ferrocyanide (K4Fe(CN)6·3H2O), potassium chloride (KCl), acetic acid (CH3COOH, HAc), sodium acetate
RI
(CH3COONa, NaAc) and hydrochloric acid (HCl) were purchased from Sinopharm Chemical
SC
Reagent Co., Ltd. 0.1 M NaAc/HAc buffer with different pH was prepared by NaAc and HAc.
NU
Nafion (5%), aniline, PVP, and ammonium persulfate (APS) were from Sigma-Aldrich. Nafion (5%) was diluted to 0.125% with alcohol. Standard stock solutions of Cd(II), Pb(II) and Bi(III)
MA
were obtained from Aladdin Industrial Corporation. Ultra-pure water from a water purification
2.2 Instrumentations
PT E
were of analytical grade.
D
system GWA-UN1-10 (18.25 MΩ cm) was used throughout all the experiments. All chemicals
CE
The SEM images were conducted by a Zeiss LEO1530VP scanning electron microscopy.
AC
XRD patterns were executed with a Bruker D8 Advance diffractometer with a Cuκα radiation. Raman spectra were implemented with a Jobin Yvon LabRam Aramis spectrometer. XPS measurements were accomplished on an ESCALAB 250Xi spectrometer. Laser engraving was carried out on a laser engraving machine (K3020) with glass sealed off CO2 laser. Fourier transform infrared (FTIR) spectral studies were performed with traditional KBr pellet method on a Bruker VERTEX 70 spectrometer.
5
ACCEPTED MANUSCRIPT 2.3 Laser engraving and fabrication of nanocomposite
Firstly, the PI sheets were cleaned by rinsing with alcohol and ultra-pure water and then dried in an oven at 60 °C before laser irradiation. Then, laser engraving was executed on PI sheets by the design software at a power of 5 W and a scanning speed of 50 mm/s in atmospheric conditions
PT
to form a black carbonized layer on PI films. In the meanwhile, in order to compound PANI on the
RI
once-etched PI films, 12.4 g APS and 10.0 g PVP were dissolved in 70.0 mL ultra-pure water and
SC
then cooled in an ice water bath for about 30 min (solution I). After that,the once-etched PI films
NU
were moved to a 500ml beaker. Then 2 mol/L HCl was added until the black carbonized area was submerged and 5ml aniline was added. The mixture was placed in an ice water bath under
MA
continuous stirring with the solution I added dropwise and then left overnight. The resulting product was named as once-etched PI films compounded with polyaniline (OE-PI@PANI).
D
Afterwards, the OE-PI@PANI was cleaned by ultra-pure water and then dried in an oven. Finally,
PT E
the OE-PI@PANI was laser engraved again with a larger power (6.2 W) in the same area to make graphitization more sufficiently. The fully graphitized material which had been broken away from
CE
the PI film was scraped off to obtain the desired product. Since the PANI combined on the
AC
once-etched PI film was decomposed by the instantaneous high temperature generated during the laser engraving process[11], the obtained nanomaterials were defined as N@LEG. The direct twice-etched graphene (TE-LEG) was prepared in the similar ways except the procedure of combining with the PANI. The PANI was prepared using the method above aside from integrating with the PI sheets.
6
ACCEPTED MANUSCRIPT
2.4 Preparation of modified electrode
Before the modification, 4 mg N@LEG was ultrasonically dispersed in 2 mL 0.125% Nafion-alcohol solution (V:V=1:1) for more than 2 hours to acquire a homogeneous suspension.
PT
The bare GCE was polished with alumina powder and then sonicated with alcohol and ultra-pure water in turns for 2 minutes. Then the treated GCE was dried under an infrared lamp. After that, 4
RI
µL of N@LEG suspension was dropped onto the surface of GCE and then dried under an infrared
SC
lamp to acquire the N@LEG/GCE. Moreover, PANI-GCE and TE-LEG-GCE were obtained by
NU
the process mentioned above for comparison.
MA
2.5 Electrochemical measurements
Electrochemical measurements were implemented on an IGS6030 electrochemical
D
workstation (Guangzhou ingsens sensor technology Co., Ltd, China) with a conventional
PT E
three-electrode system consisting of a GCE working electrode, an Ag/AgCl saturated KCl reference electrode, and a platinum counter electrode. The CVs were implemented with the
CE
potential varied from -0.2 V to 0.6 V at a scan rate of 100 mV s-1. And the EIS measurements were
AC
carried out with the frequency from 0.1 Hz to 106 Hz and the amplitude of 5 mV. Both of them were executed in 5.0 mM Fe(CN)63-/4- solution containing 0.1 M KCl. Furthermore, SWASV was employed for the simultaneous determination of Cd(II) and Pb(II) with a deposition potential at -1.3 V for 210 s and a potential from -1.0 V to 0 V with 25 mV amplitude, 10 Hz frequency and 5 mV increment potential in 0.1 M NaAc/HAc buffer (pH=4.5) in the presence of 200 µg L-1 Bi(III). Prior to every experiment, a cleaning step by polarizing at 0.5 V for 60 s was adopted.
2.6 Preparation of samples 7
ACCEPTED MANUSCRIPT Real lake water samples were filtered twice through a 0.22 µm filter membrane before the measurements. Generally, 5.0 mL of lake water sample was mixed with 5.0 mL of 0.1 M NaAc/HAc buffer (pH 4.5) with 200 µg L-1 Bi(III)and then analyzed under the optimized SWASV.
PT
3. Results and discussion
RI
3.1 Surface characterization of N@LEG
SC
The surface morphologies of N@LEG were characterized by SEM. As shown in Fig. 1(a), it is clearly observed that there are rather compact 3D porous structures with different sizes on the
NU
surface of N@LEG. At higher magnification (Fig. 1(b)), there are typical 3D graphene
MA
frameworks of the stacked graphene sheets caused by laser scanning on PI films. This is due to the fact that the focused laser beams generated the instantaneous high temperature that causes the PI
D
decomposed into gaseous products so that the momentary gas spray resulted in the formation of
PT E
porous structures during the decomposition and graphitization processes.[11] It is because of the presence of the 3D porous stacked graphene sheets structures which provide such large specific
CE
surface areas and abundant reactive sites that facilitate the accumulation of metal ions and make
AC
contributions on the very wide detection range.
Fig. 1 (a) SEM image of N@LEG; (b) magnified SEM image of N@LEG.
8
ACCEPTED MANUSCRIPT In addition, the structure information of N@LEG was further analyzed by Raman spectroscopy. As exhibited in Fig. 2(a), the peaks of OE-PI@PANI are quite different from pure PANI or TE-LEG in peak numbers. As for the pure PANI, four prominent peaks located at 1163 cm-1, 1338 cm-1 and 1480 cm-1, which derive from the stretching vibration of C=C, C–N and C–H
PT
[36]. Besides, the Raman spectrum of the TE-LEG depicts three representative peaks of graphene,
RI
i.e. a D peak at 1350 cm-1, a G peak at 1585 cm-1 and 2D peak at 2700 cm-1 approximately[37].
SC
Since all of the above characteristic peaks appear in the Raman spectra of the OE-PI@PANI nanocomposite, it is certain that PANI was successfully combined with PI films after once laser
NU
engraved. Furthermore, just as the graphene obtained by directly laser etching PI sheets
MA
twice-TE-LEG, N@LEG also exhibits the D-band (at 1350 cm-1) corresponding to defects in disordered graphene flakes, the G-band (at 1585 cm-1) related to the hexagonal clamping mode of
D
graphite carbon, and 2D-band (at 2700 cm-1) deriving from the layer stacking pattern of carbon
PT E
atoms[38]. Additionally, the intensity ratio ID/IG, which is employed to evaluate the degree of defects and disorder in the sp2 hybridized graphitic carbon, are about 0.71 for N@LEG and 0.27
CE
for LEG, revealing the crystal defect and disorder degree ascended after compounding with PANI
AC
[39]. Despite that, the distinct 2D peak further illustrates the generation of 3D multilayer graphene [37], which is in accordance to with the SEM results. Nevertheless, the characteristic peaks of PANI does not appear in N@LEG, which might be due to the pyrolysis of PANI caused by the instantaneous high temperature generated during laser engraving[11]. The successful synthesis of 3D multilayer graphene with porous frameworks plays an important role in the very wide detection range of heavy metal sensors.
9
MA
NU
SC
RI
PT
ACCEPTED MANUSCRIPT
Fig. 2 (a) Raman spectra of PANI, OE-PI@PANI, TE-LEG and N@LEG; (b) XRD patterns of N@LEG; (c) XPS
PT E
D
survey spectra of TE-LEG and (d) N@LEG.
Furthermore, the structural information of N@LEG was also investigated by XRD. As shown
CE
in Fig. 2(b), N@LEG presents a distinct peak at 2θ =25.83° consistent with the typical C (002) plane of crystalline graphene, while the peak at 42.20° for the 100 plane is corresponding to an
AC
in-plane structure[40]. The XRD results are in agreement with Raman, which further proves the production of graphene.
To analyze the surface properties and the variation of the components of the TE-LEG and N@LEG nanocomposite, XPS was also performed. The XPS survey spectra of TE-LEG and N@LEG (Fig. 2(c) and Fig. 2(d)) reveal that both of them consist of C, N, O elements. The N element contents on the surface of TE-LEG and N@LEG are 0.09 at.% and 2.15 at.%, respectively. 10
ACCEPTED MANUSCRIPT Compared with TE-LEG, the N content of N@LEG increases, which is ascribed to the fact that the transient high temperature generated during the laser engraving process causes the PANI on the OE-PI@PANI film to be thermally decomposed[11]. The presence of N-doped graphene has a significant effect on the considerable wide detection range. The high-resolution curve-fitted XPS
PT
spectra and related analysis of TE-LEG and N@LEG in the C 1s, O 1s and N 1s regions are
RI
shown in Fig. S1(a-d) in Electronic Supplementary Materials (ESM). Moreover, the FTIR spectra
SC
of PANI, TE-LEG and N@LEG are displayed in Fig. S2. The FTIR results further justify the
3.2 Electrochemical behaviors of N@LEG.
NU
material as nitrogen-doped graphene. The specific graph and explanation are exhibited in ESM.
MA
Electrochemical characterizations of N@LEG were first studied by adopting [Fe(CN)6]3-/4- as electrochemical redox probes. Fig. 3(a) show the CVs of bare-GCE (curve a), PANI-GCE (curve
PT E
D
b), TE-LEG/GCE (curve c) and N@LEG/GCE (curve d) modified electrodes in 5.0 mM Fe(CN)63-/4- containing 0.1 M KCl. A pair of well-defined reversible redox peaks is exhibited at
CE
the bare GCE (curve a). Compared with the bare GCE (48.58 µA), modification with the PANI (61.68 µA) onto GCE surface will increase the anodic peak current of [Fe(CN)6]3-/4-, resulting
AC
from the good electrical conductivity of PANI which accelerates the electron transfer rate[24]. In addition, a larger peak current of [Fe(CN)6]3-/4- also attains with the modification of TE-LEG (60.66 µA) onto GCE, on account of the porous 3D graphene nanosheets that provide large specific areas for electrochemical reactions. Nevertheless, it is worth noting that N@LEG/GCE presents the highest peak currents (139.6 µA), which are more than 2-fold higher than other electrodes. This phenomenon indicates the fact that N@LEG has the best ability to facilitate the electron transfer as well as makes the fastest response to redox reactions. 11
ACCEPTED MANUSCRIPT Besides, the Nyquist plots are shown in Fig. S3. The resistance of 300 Ω on bare-GCE (curve a), 270 Ω PANI-GCE (curve b), and 260 Ω on TE-LEG/GCE (curve c) and 165 Ω on N@LEG/GCE (curve d) are observed respectively. The resistances change of these modified electrodes are consistent with the CV results, which not only verify that N@LEG was successfully
PT
modified on the GCE surface but also indicate the excellent electrical conductivity of N@LEG. In
RI
addition, the electrochemical surface area study (ESCA) related graphs and explanations are
SC
shown in Fig. S4 (ESM). The effective area was calculated to be 0.03 cm2 of bare-GCE and 0.06 cm2 of LEGCNs-GCE, respectively. The increased electrochemical activity surface area of
NU
LEGCNs-GCE (twice as large as bare-GCE) indicates that LEGCNs are beneficial to the
MA
improvement of the electrochemical performance and the adsorption of heavy metal ions. Moreover, the sensitivity is calculated to be 37.47 µA·µM-1·cm-2 for Cd(II) and
D
224.47µA·µM-1·cm-2 for Pb(II), respectively.
PT E
Furthermore, SWASV was performed for trace heavy metals determination in 0.1 M NaAc/HAc buffer (pH 4.5) accompanied by an in situ-incorporated Bi film with a concentration of
CE
200 µg L-1. The stripping voltammograms of 200µg L-1 Cd(II) and Pb(II) at different film-coated
AC
GCEs and bare GCE are presented in Fig. 3(b) (Bare-GCE: short dot line; PANI: dash dot line; TE-LEG: dash line; N@LEG: solid line). At the PANI modified GCE, the smallest stripping peaks of Cd(II) and Pb(II) are observed, suggesting that the PANI has a worst detection sensitivity of Cd(II) and Pb(II) so that it had better not be used to electrochemically detect them when compared to other electrodes. In contrast, at TE-LEG modified GCE, the stripping responses of Cd(II) and Pb(II) are much higher than bare GCE result from the large effective specific surface area which is beneficial to the adsorption of the probe metal ions. Most importantly, comparison with other 12
ACCEPTED MANUSCRIPT electrodes, N@LEG/GCE possesses not only the distinguishable and completely separated stripping peaks at almost -0.80 V (Cd(II)) and -0.55V (Pb(II)) but also the highest stripping signals, which revealed that N@LEG has wonderful affinity as well as excellent SWASV performance towards Cd(II) and Pb(II) due to the synergistic effect of LEG and N-doped. The analyses above
PT
certify that there are some merits at N@LEG/GCE: (1) 3D porous stacked graphene nanosheets
RI
structure provide a considerable large specific area to accelerate the electron transfer at interfaces;
SC
(2) multilayer stacked graphene nanosheets facilitate electron transfer and improve the conductivity; (3) The presence of N heteroatoms contributes to the structural stability and the
NU
affinity of metal ions. Thus, N@LEG is considered as a potential electrochemical sensor platform
CE
PT E
D
MA
for the simultaneous detection of Cd(II) and Pb(II).
AC
Fig. 3 (a) CVs of bare GCE (curve a), PANI (curve b), TE-LEG (curve c) and N@LEG (curve d) modified electrodes in 5 mM Fe(CN)63-/4- solution with 0.1 M KCl. Scan rate: 100 mV s-1; (b) SWASV responses of 200 µg L-1 Cd(II) and Pb(II) in 0.1 M NaAc/HAc buffer (pH 4.5) on the N@LEG (curve a), TE-LEG (curve b), bare GCE
(curve c) and PANI (curve d) modified electrodes. Deposition potential: -1.3 V. Deposition time: 210s. Bi(III) concentration: 200 µg L-1.
13
ACCEPTED MANUSCRIPT 3.3 Optimization of the determination conditions.
In order to improve the sensitivity of N@LEG/GCE in the determination of Cd(II) and Pb(II), several correlative factors were optimized via SWASV, such as (a) deposition potential; (b) deposition time; (c) pH; (d) the concentration of Bi(III). The optimal experimental conditions were
PT
listed as follows: (a) Deposition potential: -1.3 V; (b) Deposition time: 210 s; (c) Optimal pH: 4.5;
RI
(e) Bi(III) concentration: 200 µg·L-1. The specific charts and explanations are shown in Fig. S5 in
SC
Electronic Supplementary Materials (ESM)).
NU
3.4 Electrochemical determination of Cd(II) and Pb(II) using SWASV
MA
SWASV was employed to discuss the limit of detection and linear range of the N@LEG/GCE for the simultaneous determination of Cd(II) and Pb(II) under the optimized experimental
D
conditions. Fig. 4(a) depicts the SWASV curves of different concentrations of Cd(II) and Pb(II) in
PT E
0.1 M NaAc/HAc buffer (pH 4.5) containing 200 µg L-1 Bi(III) at N@LEG/GCE. The stripping peaks of Cd(II) and Pb(II) increase accompanied by the successive enhancement in probe metal
CE
ions concentration. And well-defined response peaks are observed at around -0.55 V and -0.80 V belonging to Cd(II) and Pb(II), respectively. The corresponding regression equations of Cd(II) and
AC
Pb(II) contain two wide linear ranges (Fig. 4(b)):
For Cd(II):
Ip (µA) = 0.04C (µg·L-1) + 1.64; (5 to 10 µg·L-1, R2 = 0.996) Ip (µA) = 0.14C (µg·L-1) +0.33; (10 to 380 µg·L-1, R2 = 0.991)
For Pb(II):
14
(1)
(2)
ACCEPTED MANUSCRIPT Ip (µA) = 0.13C (µg·L-1) + 1.86; (0.5 to 10 µg·L-1, R2 = 0.999)
(3)
Ip (µA) = 0.20C (µg·L-1) + 1.06; (10 to 380 µg·L-1, R2 = 0.997)
(4)
The reason for such wide linear ranges is due to the 3D porous stacked graphene sheets
PT
structures of N@LEG which provide large specific surface areas and abundant reactive sites that facilitate the accumulation of metal ions and the influence of N-doped graphene. Moreover, the
RI
limits of detection (LOD) (based on S/N = 3) is calculated according to the following formula:
SC
LOD =3 σB/b, in which σB is the standard deviation of the population of the blank responses and b
NU
is the slope of the regression line[1, 41, 42]. The LOD are 1.08 µg L-1 for Cd(II) and 0.16 µg L-1 for Pb(II), which are nearly 3 times and 60 times less than the guideline values of the drinking
MA
water presented by the World Health Organization (WHO), for Cd(II) and Pb(II), respectively. A comparison with the previously reported modified electrodes is given in Table 1. Apparently, the
PT E
D
new-designed N@LEG/GCE demonstrates lower or comparable detection limits and much wider linear ranges. In addition, N@LEG/GCE requires neither expensive instruments nor complicated
CE
and tedious processes. Thus, the fabricated sensor is applicable for sensitive and rapid determination of Cd(II) and Pb(II) with the merits of simple fabrication, easy operation and
AC
low-cost.
15
MA
NU
SC
RI
PT
ACCEPTED MANUSCRIPT
Fig. 4 (a) SWASV curves of Cd(II) and Pb(II) at 0.5, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 12.5, 15, 20, 40, 60, 80, 100, 120,
PT E
D
140,180, 220, 260, 300, 340 and 380 µg L-1 and (b) Corresponding calibration plots for Cd(II) at 6, 7, 8, 9, 10, 12.5, 15, 20, 40, 60, 80, 100, 120, 140,180, 220, 260, 300, 340 and 380 µg L-1 and Pb(II) at 0.5, 1, 2, 3, 4, 5, 6, 7, 8, 9,
CE
10, 12.5, 15, 20, 40, 60, 80, 100, 120, 140,180, 220, 260, 300, 340 and 380 µg L-1, respectively. (c-d) SWASV
responses and the corresponding calibration plots on N@LEG/GCE for the individual determination of Cd(II) at
AC
10, 50, 100, 150, 200 and 250 µg L-1, respectively. (e-f) SWASV responses and the corresponding calibration plots on N@LEG/GCE for the individual determination of Pb(II) at 10, 50, 100, 150, 200 and 250 µg L-1, respectively. Deposition potential: -1.3 V. Deposition time: 210s. Bi(III) concentration: 200 µg·L-1. Supporting electrolyte: 0.1
M acetate buffer (pH 4.5).
16
ACCEPTED MANUSCRIPT
Table 1 Comparison of our designed electrode for the determination of Cd(II) and Pb(II) with other modified
electrodes.
Linear range(µg L-1) Methods
References Pb(Ⅱ)
Cd(Ⅱ)
Pb(Ⅱ)
PT
Cd(Ⅱ)
Bi/Nafion/RGO-GNPs-GCE
SWASV
1–90
1–90
0.08
0.12
[13]
Bi/poly(p-ABSA)-GCE
DPASV
1–110
1–130
0.63
0.80
[43]
BiOCl/MWCNT-GCE
SWASV
5–50
RI
Electrodes
LOD(µg L-1)
1.20
0.57
[44]
RGO/Bi-CPE
DPASV
20–120
2.80
0.55
[45]
CB-15-crown-5-GCE
DPASV
15.7–191.9
10.9–186.5
4.70
3.30
[46]
Nafion/Bi/NMC-GCE
DPASV
2–10,10–100
0.5–10,10–100
1.50
0.05
[1]
Bi/Au-GN-Cys-GCE
SWASV
0.5-40
0.10
0.05
[12]
N@LEG/GCE
SWASV
1.08
0.16
This work
SC
5–50
MA
NU
20–120
D
0.5-40
0.5–10,10–380
PT E
5–10,10–380
RGO: reduced graphene oxide; GNPs: gold nanoparticles; Poly(p-ABSA): poly(p-aminobenzene sulfonic acid; DPASV: differential pulse
4-carboxybenzo-15-crown-5;
NMC:
nitrogen
doped
microporous
carbon
(NMC);
Au-GN-Cys:
gold
AC
CB-15-crown-5:
CE
anodic stripping voltammetry; BiOCl: bismuth-oxychloride; MWCNTs: multiwalled carbon nanotubes; CPE: carbon paste electrode;
nanoparticle-graphene-cysteine composite
3.5 Interference, repeatability, reproducibility and stability of N@LEG/GCE
Since the mutual interference between Cd(II) and Pb(II) during the simultaneous determination is so crucial for practical applications, an individual detection of Cd(II) or Pb(II) was conducted by altering one’s concentration whereas the concentration of another one was kept constant in the meanwhile. As seen in Fig. 4(c) and Fig. 4(d), the stripping signals of Cd(II) 17
ACCEPTED MANUSCRIPT ascend linearly over the range from 10 to 250 µg L-1 while the concentration of Pb(II) is kept at 50 µg L-1. However, the responses of Pb(II) fundamentally remain changeless at the same time. Analogous results are observed with the enhancement of the concentration of Pb(II) from 10 to 250 µg L-1 but fixing the concentration of Cd(II) in the meanwhile (Fig. 4(e) and Fig. 4(f)). As
PT
similar detection sensitivities of Cd(II) and Pb(II) are obtained (0.09 versus 0.04 for Cd(II) and
RI
0.19 versus 0.13 for Pb(II)) when compared with the results found in simultaneous determination,
SC
the results suggest that there is little mutual interference between Cd(II) and Pb(II).
NU
Aside from the mutual interference, the presence of non-target metal ions also disturbs the SWASV determination of target metal ions. To evaluate the anti-interference performance of the
MA
proposed sensor, various interfering metal ions (including Zn(II), Co(II), Ni(II), Cu(II), Mg(II), Cr(II), Fe(III), Mn(II), As(II), Hg(II) and Al(II)) were added to 0.1 M NaAc/HAc buffer (pH 4.5)
D
containing 50 µg L-1 Cd(II) and Pb(II) by SWASV under the optimum conditions. Fig. 5(a) shows
PT E
that 50-fold Zn(II), Co(II), Ni(II), Mg(II), Cr(II), Fe(III), Mn(II), As(II) and Al(II) have no distinct influences on response signals and the tolerance ratio was measured to be 4.15% at most. However,
CE
10-fold Cu(II) results in less than 30.33% peak current decrease, while 10-fold Hg(II) is calculated
AC
to be less than 26.90% peak current increase. This suppression effect is likely due to the formation of intermetallic compounds as well as competition for active sites on the surface of the electrode, reported previously[47-49]. Since the Cu2[Fe(CN)6] has a larger pKsp valueand is therefore more insoluble. And the hexacyanoferrate(II) was not found to have any effect on the Cd(II) and Pb(II) peaks except at concentrations above 0.1 M when a small drop in response was noted. Therefore, the Cu(II) interference can be reduced by the addition of 0.1 mM ferrocyanide to the sample extract solutions before analysis to form an insoluble and stable copper-ferrocyanide complex with 18
ACCEPTED MANUSCRIPT the help of a ligand[49]. In addition, it is obvious that the stripping peak currents of Cd(II) and Pb(II) are significantly increased when Hg(II) coexist, which is attributed to competition the formation of an amalgam as well as the competition between electrodeposited bismuth and Hg for surface sites on the electrode[47, 50]. Actually, in order to improve the sensitivity, the hanging
PT
mercury drop electrode (HMDE) and the mercury film electrode have been widely used in the
RI
electrochemical determination of heavy metal ions[48, 51]. Thus, the formation of mercury film
SC
and followed by the Metal-Hg intermetallic compound formation on the surface of the electrode increase the peak current for heavy metal ions. Overall, the presence of Hg strengthens the
NU
sensitivity in the detection of heavy metal ions[52]. Thus, the above results indicated the
MA
N@LEG/GCE had satisfactory anti-interference ability.
In addition, in the interference experiments, we also studied the effects of several organic
D
substances with 300-fold concentration. The 300-fold concentration of testing substances was
PT E
introduced into the sample which contained 50 µg·L-1 Cd(II) and Pb(II) and 200 µg·L-1 Bi(III). As shown in Fig. 5(b), the presence of chloroform (CH3Cl) has almost no effect on the response
CE
signals, the tolerance ratio of which is 1.3%. However, the complexing agents such as
AC
ethylenediaminetetraacetic acid disodium salt (EDTA-2Na) and citric acid, have an inhibitory effect on the test results, which will weaken or even eliminate the stripping signals of Cd(II) and Pb(II), especially the EDTA, whose presence causes the signals to almost disappear). On the contrary, the surface active substances such as sodium dodecyl benzene sulfonate (SDBS) and sodium laurylsulfonate (SDS) have an increased effect on the detection signal, whose tolerance ratio is 12.6% and 15.8%. As for formaldehyde (CH3CHO), both of the stripping signals of Cd(II) and Pb(II) weaken and the tolerance ratio is 16.6%. Therefore, this sensor is not suitable for 19
ACCEPTED MANUSCRIPT systems containing complexing agents or complex organic substances.
The repeatability was appraised by the relative standard deviation (RSD %) of ten repetitive experiments of SWASV (Fig. S6). The RSDs are 3.85% and 3.47% of each of Cd(II) and Pb(II), which manifest the wonderful repeatability performance of the N@LEG/GCE. The reproducibility
PT
was next judged with five different N@LEG/GCE and the RSDs are 7.12% for Cd(II) and 6.87%
RI
for Pb(II). The results indicate that the preparation procedures are reliable and the prepared sensor
SC
has excellent reproducibility. The stability was evaluated after two weeks of storage at room
NU
temperature. The RSDs are 5.54% for Cd(II) and 6.15% for Pb(II), so the prepared sensor
CE
PT E
D
MA
possesses long-time stability.
Fig. 5 (a-b) Selectivity of N@LEG/GCE for simultaneous detection of Cd(II) and Pb(II). Deposition potential: -1.3
AC
V. Deposition time: 210s. Cd(II) and Pb(II) concentration: 50 µg·L-1. Bi(III) concentration: 200 µg·L-1. Supporting
electrolyte: 0.1 M acetate buffer (pH 4.5).
3.6 Real sample analysis
To quantify of Cd(II) and Pb(II) in real samples and estimate the applicability of N@LEG/GCE, standard addition method was carried out in real lake water sample. The lake 20
ACCEPTED MANUSCRIPT water was treated by diluting with 0.1 M acetate buffer (pH 4.5) containing 200 µg L-1 Bi(III) (v:v=1:1). The results are listed in Table 2 and the recoveries of Cd(II) and Pb(II) vary from 97.80% to 113.65%. Furthermore, the results obtained are in accordance with the AAS method. Hence, N@LEG/GCE sensor has excellent accuracy and recovery, indicating the promising
RI
PT
application for the determination of Cd(II) and Pb(II) in practical samples.
Found by AAS(µg L-1)
Sample Cd(Ⅱ)
Pb(Ⅱ)
Cd(Ⅱ)
Pb(Ⅱ)
5.58
6.12
/
/
5.82
10
10
10.35
20
20
18.90
30
30
Pb(Ⅱ)
4.85
/
/
10.62
9.78
106.20
97.80
19.87
22.73
21.07
113.65
105.35
31.32
29.55
33.73
98.50
112.43
10.11
PT E
D
Lake water
CE
29.76
Recovery/%
Cd(Ⅱ)
MA
Cd(Ⅱ) Pb(Ⅱ)
Found by proposed method(µg L-1)
NU
Added (µg L-1)
SC
Table 2 Recovery for the determination of Cd(II) and Pb(II) in lake water (n = 3) .
AC
4. Conclusions
In the present work, the laser engraving technique provides a facile and novel method for efficient and large-scale fabrication of high-quality 3D porous graphene-based electrode matrices. By introducing PANI as N-dopant after once laser engraving PI sheets, the resulting OE-PI@PANI was subjected to the secondary etching so that the surface PANI was decomposed by the instantaneous high temperature generated during the laser engraving process[11], thereby synthesizing the N@LEG. The N@LEG possesses 3D porous stacked graphene morphologies 21
ACCEPTED MANUSCRIPT with large specific surface areas and the unique metal ions affinity of N atoms, which are conducive to the accumulation of HMI and the improvement of the quite wide detection ranges. Moreover, the simultaneous detection of Cd(II) and Pb(II) is achieved in terms of SWASV with high selectivity, extremely wide linear range and low detection limit. The quite wide linear ranges
PT
vary from 5 to 380 g L-1 for Cd(II), and 0.5 to 380 µg L-1 for Pb(II), respectively. In addition, the
RI
detection limits were calculated to be 1.08 g L-1 (S/N = 3) for Cd(II) and 0.16 g L-1 (S/N = 3) for
SC
Pb(II), which were nearly 3 times and 60 times less than the guideline values of the drinking water presented by the World Health Organization (WHO), for Cd(II) and Pb(II), respectively. In the
sensitivity is
calculated
to be 37.47 µA·µM-1·cm-2
NU
addition,
for
Cd(II)
and
MA
224.47µA·µM-1·cm-2 for Pb(II), respectively. The facile preparation process and satisfactory analytical performance of the proposed sensor indicate a promising application towards detection
D
of Cd(II) and Pb(II) in real water. In the future, abundant electrochemical sensors with such wide
PT E
detection ranges can be fabricated according to the above proposed method as well as expand
CE
in-field miniaturized or wearable sensing platforms.
AC
Acknowledgments
This work was supported by National Natural Science Foundation of China (NSFC, No. 21875070), Guangdong Nature Science Foundation (Project No. 2017A030312005), and Guangzhou Science Technology and Innovation Commission (No. 201508020010). We also wish to thank the engineer Qian Liu from Shiyanjia lab for help with the XPS analysis.
22
ACCEPTED MANUSCRIPT References [1] L. Xiao, H. Xu, S. Zhou, T. Song, H. Wang, S. Li, W. Gan, Q. Yuan, Simultaneous detection of Cd(II) and Pb(II)
by differential pulse anodic stripping voltammetry at a nitrogen-doped microporous carbon/Nafion/bismuth-film
electrode, Electrochim. Acta 143 (2014) 143-151.
PT
[2] X. Zhang, Y. Zhang, D. Ding, J. Zhao, J. Liu, W. Yang, K. Qu, On-site determination of Pb 2+ and Cd 2+ in
RI
seawater by double stripping voltammetry with bismuth-modified working electrodes, Microchem. J. 126 (2016)
SC
280-286.
NU
[3] R.O. Kadara, I.E. Tothill, Stripping chronopotentiometric measurements of lead(II) and cadmium(II) in soils
extracts and wastewaters using a bismuth film screen-printed electrode assembly, Anal. Bioanal. Chem. 378(3)
MA
(2004) 770-5.
[4] Z. Bi, C.S. Chapman, P. Salaün, C.M.G. van den Berg, Determination of Lead and Cadmium in Sea- and
D
Freshwater by Anodic Stripping Voltammetry with a Vibrating Bismuth Electrode, Electroanalysis 22(24) (2010)
PT E
2897-2907.
[5] Z. Wang, H. Wang, Z. Zhang, G. Liu, Electrochemical determination of lead and cadmium in rice by a
CE
disposable bismuth/electrochemically reduced graphene/ionic liquid composite modified screen-printed electrode,
AC
Sens. Actuators, B 199 (2014) 7-14.
[6] Z. Lu, J. Zhang, W. Dai, X. Lin, J. Ye, J. Ye, A screen-printed carbon electrode modified with a bismuth film
and gold nanoparticles for simultaneous stripping voltammetric determination of Zn(II), Pb(II) and Cu(II),
Microchim. Acta 184(12) (2017) 4731-4740.
[7] Z. Lu, W. Dai, B. Liu, G. Mo, J. Zhang, J. Ye, J. Ye, One pot synthesis of dandelion-like polyaniline coated gold
nanoparticles composites for electrochemical sensing applications, J. Colloid Interface Sci. 525 (2018) 86-96.
[8] C. Gao, X.-J. Huang, Voltammetric determination of mercury(II), TrAC, Trends Anal. Chem. 51 (2013) 1-12.
23
ACCEPTED MANUSCRIPT
[9] A.K.G.K.S. Novoselov, The rise of graphene, Nat. Mater. 6 (2007) 183–191.
[10] K.T. Paula, G. Gaál, G.F.B. Almeida, M.B. Andrade, M.H.M. Facure, D.S. Correa, A. Riul, V. Rodrigues, C.R.
Mendonça, Femtosecond laser micromachining of polylactic acid/graphene composites for designing interdigitated
microelectrodes for sensor applications, Opt. Laser Technol. 101 (2018) 74-79.
PT
[11] Z. Zhang, M. Song, J. Hao, K. Wu, C. Li, C. Hu, Visible light laser-induced graphene from phenolic resin: A
RI
new approach for directly writing graphene-based electrochemical devices on various substrates, Carbon 127
SC
(2018) 287-296.
[12] L. Zhu, L. Xu, B. Huang, N. Jia, L. Tan, S. Yao, Simultaneous determination of Cd(II) and Pb(II) using square
MA
electrode, Electrochim. Acta 115 (2014) 471-477.
NU
wave anodic stripping voltammetry at a gold nanoparticle-graphene-cysteine composite modified bismuth film
[13] G. Zhao, H. Wang, G. Liu, Z. Wang, J. Cheng, Simultaneous determination of trace Cd(II) and Pb(II) based on
D
Bi/Nafion/reduced graphene oxide-gold nanoparticle nanocomposite film-modified glassy carbon electrode by
PT E
one-step electrodeposition, Ionics 23(3) (2016) 767-777.
[14] J. Li, S. Guo, Y. Zhai, E. Wang, High-sensitivity determination of lead and cadmium based on the
CE
Nafion-graphene composite film, Anal. Chim. Acta 649(2) (2009) 196-201.
AC
[15] N. Ruecha, N. Rodthongkum, D.M. Cate, J. Volckens, O. Chailapakul, C.S. Henry, Sensitive electrochemical
sensor using a graphene-polyaniline nanocomposite for simultaneous detection of Zn(II), Cd(II), and Pb(II), Anal.
Chim. Acta 874 (2015) 40-8.
[16] H. Tao, X. Yang, L. Zhang, S. Ni, One-step synthesis of nickel sulfide/N-doped graphene
composite as anode materials for lithium ion batteries, J. Electroanal. Chem. 739 (2015) 36-42. [17] X. Lv, G. Li, H. Zhou, D. Li, J. Zhang, Z. Pang, P. Lv, Y. Cai, F. Huang, Q. Wei, Novel freestanding
N-doped carbon coated Fe3O4 nanocomposites with 3D carbon fibers network derived from bacterial
24
ACCEPTED MANUSCRIPT
cellulose for supercapacitor application, J. Electroanal. Chem. 810 (2018) 18-26. [18] Y. Luan, Y. Huang, L. Wang, M. Li, R. Wang, B. Jiang, Porous carbon@MnO2 and nitrogen-doped porous
carbon from carbonized loofah sponge for asymmetric supercapacitor with high energy and power density, J.
Electroanal. Chem. 763 (2016) 90-96.
PT
[19] X. Zhou, Q. Liao, J. Tang, T. Bai, F. Chen, J. Yang, A high-level N-doped porous carbon nanowire modified
RI
separator for long-life lithium–sulfur batteries, J. Electroanal. Chem. 768 (2016) 55-61.
SC
[20] F. Cao, L. Zhang, Y. Tian, A novel N-doped carbon nanotube fiber for selective and reliable electrochemical
determination of ascorbic acid in rat brain microdialysates, J. Electroanal. Chem. 781 (2016) 278-283.
NU
[21] H. Xing, J. Xu, X. Zhu, X. Duan, L. Lu, W. Wang, Y. Zhang, T. Yang, Highly sensitive simultaneous
MA
determination of cadmium (II), lead (II), copper (II), and mercury (II) ions on N-doped graphene modified
electrode, J. Electroanal. Chem. 760 (2016) 52-58.
D
[22] M. Li, Z. Wu, W. Ren, H. Cheng, N. Tang, W. Wu, W. Zhong, Y. Du, The doping of reduced graphene oxide
PT E
with nitrogen and its effect on the quenching of the material’s photoluminescence, Carbon 50(14) (2012)
5286-5291.
CE
[23] Y. Liu, X. Gong, W. Dong, R. Zhou, S. Shuang, C. Dong, Nitrogen and phosphorus dual-doped carbon dots as
AC
a label-free sensor for Curcumin determination in real sample and cellular imaging, Talanta 183 (2018) 61-69.
[24] L. Wang, X. Lu, S. Lei, Y. Song, Graphene-based polyaniline nanocomposites: preparation, properties and
applications, J. Mater. Chem. A 2(13) (2014) 4491-4509.
[25] C. Lei, Synthesis of N-doped Graphene for Simultaneous Electrochemical Detection of Lead and Copper in
Water, International Journal of Electrochemical Science
(2017) 4856-4866.
[26] S. Barg, F.M. Perez, N. Ni, P.V. Pereira, R.C. Maher, E. Garcia-Tunon, S. Eslava, S. Agnoli, C.
Mattevi, E. Saiz, Mesoscale assembly of chemically modified graphene into complex cellular networks,
25
ACCEPTED MANUSCRIPT
Nat. Commun. 5 (2014) 4328. [27] Y. Xu, K. Sheng, C. Li, G. Shi, Self-Assembled Graphene Hydrogel via a One-Step Hydrothermal
Process, ACS. Nano. 4(7) (2010) 4324-4330. [28] M.F. El-Kady, V. Strong, S. Dubin, R.B. Kaner, Laser Scribing of High-Performance and Flexible
PT
Graphene-Based Electrochemical Capacitors, Science 335(6074) (2012) 1326-1330.
RI
[29] R. Arul, R.N. Oosterbeek, J. Robertson, G. Xu, J. Jin, M.C. Simpson, The mechanism of direct laser writing of
SC
graphene features into graphene oxide films involves photoreduction and thermally assisted structural
rearrangement, Carbon 99 (2016) 423-431.
NU
[30] J. Lin, Z. Peng, Y. Liu, F. Ruiz-Zepeda, R. Ye, E.L.G. Samuel, M.J. Yacaman, B.I. Yakobson, J.M.
MA
Tour, Laser-induced porous graphene films from commercial polymers, Nat. Commun. 5 (2014) 5714. [31] R. Ye, Y. Chyan, J. Zhang, Y. Li, X. Han, C. Kittrell, J.M. Tour, Laser-Induced Graphene Formation on Wood,
D
Adv. Mater. 29(37) (2017).
PT E
[32] H. Liu, M. Li, R.B. Kaner, S. Chen, Q. Pei, Monolithically Integrated Self-Charging Power Pack
Consisting of a Silicon Nanowire Array/Conductive Polymer Hybrid Solar Cell and a Laser-Scribed
CE
Graphene Supercapacitor, ACS Appl. Mater. Interfaces 10(18) (2018) 15609-15615.
AC
[33] S. Lin, W. Feng, X. Miao, X. Zhang, S. Chen, Y. Chen, W. Wang, Y. Zhang, A flexible and highly
sensitive nonenzymatic glucose sensor based on DVD-laser scribed graphene substrate, Biosens. Bioelectron. 110 (2018) 89-96.
[34] R.L. Calabro, D. Yang, D.Y. Kim, Liquid-phase laser ablation synthesis of graphene quantum dots
from carbon nano-onions: Comparison with chemical oxidation, J. Colloid Interface Sci. 527 (2018) 132-140. [35] X. Lin, Z. Lu, Y. Zhang, B. Liu, G. Mo, J. Li, J. Ye, A glassy carbon electrode modified with a bismuth film
26
ACCEPTED MANUSCRIPT
and laser etched graphene for simultaneous voltammetric sensing of Cd(II) and Pb(II), Microchim. Acta 185(9)
(2018) 438.
[36] N. Song, W. Wang, Y. Wu, D. Xiao, Y. Zhao, Fabrication of highly ordered polyaniline nanocone on pristine
graphene for high-performance supercapacitor electrodes, J. Phys. Chem. Solids 115 (2018) 148-155.
RI
Electrodes for Aptamer-Based Biosensing, ACS Sens 2(5) (2017) 616-620.
PT
[37] C. Fenzl, P. Nayak, T. Hirsch, O.S. Wolfbeis, H.N. Alshareef, A.J. Baeumner, Laser-Scribed Graphene
SC
[38] R. Hua, N. Hao, J. Lu, J. Qian, Q. Liu, H. Li, K. Wang, A sensitive Potentiometric resolved
ratiometric Photoelectrochemical aptasensor for Escherichia coli detection fabricated with non-metallic
NU
nanomaterials, Biosens. Bioelectron. 106 (2018) 57-63.
MA
[39] F. Wang, K. Wang, X. Dong, X. Mei, Z. Zhai, B. Zheng, J. Lv, W. Duan, W. Wang, Formation of hierarchical
porous graphene films with defects using a nanosecond laser on polyimide sheet, Appl. Surf. Sci. 419 (2017)
D
893-900.
PT E
[40] S.P. Singh, Y. Li, A. Be'er, Y. Oren, J.M. Tour, C.J. Arnusch, Laser-Induced Graphene Layers and
Electrodes Prevents Microbial Fouling and Exerts Antimicrobial Action, ACS Appl. Mater. Interfaces
CE
9(21) (2017) 18238-18247.
AC
[41] E. Desimoni, B. Brunetti, Presenting Analytical Performances of Electrochemical Sensors. Some Suggestions,
Electroanalysis 25(7) (2013) 1645-1651.
[42] Z. Lu, W. Dai, X. Lin, B. Liu, J. Zhang, J. Ye, J. Ye, Facile one-step fabrication of a novel 3D honeycomb-like
bismuth nanoparticles decorated N-doped carbon nanosheet frameworks: Ultrasensitive electrochemical sensing of
heavy metal ions, Electrochim. Acta 266 (2018) 94-102.
[43] Y. Wu, N.B. Li, H.Q. Luo, Simultaneous measurement of Pb, Cd and Zn using differential pulse anodic
stripping voltammetry at a bismuth/poly(p-aminobenzene sulfonic acid) film electrode, Sens. Actuators, B 133(2)
27
ACCEPTED MANUSCRIPT
(2008) 677-681.
[44] S. Cerovac, V. Guzsvany, Z. Konya, A.M. Ashrafi, I. Svancara, S. Roncevic, A. Kukovecz, B. Dalmacija, K.
Vytras, Trace level voltammetric determination of lead and cadmium in sediment pore water by a
bismuth-oxychloride particle-multiwalled carbon nanotube composite modified glassy carbon electrode, Talanta
PT
134 (2015) 640-649.
RI
[45] P.K. Sahoo, B. Panigrahy, S. Sahoo, A.K. Satpati, D. Li, D. Bahadur, In situ synthesis and properties of
SC
reduced graphene oxide/Bi nanocomposites: As an electroactive material for analysis of heavy metals, Biosens.
Bioelectron. 43 (2013) 293-296.
NU
[46] N. Serrano, A. Gonzalez-Calabuig, M. Del Valle, Crown ether-modified electrodes for the simultaneous
MA
stripping voltammetric determination of Cd(II), Pb(II) and Cu(II), Talanta 138 (2015) 130-137.
[47] L. Shi, Y. Li, X. Rong, Y. Wang, S. Ding, Facile fabrication of a novel 3D graphene framework/Bi
D
nanoparticle film for ultrasensitive electrochemical assays of heavy metal ions, Anal. Chim. Acta 968 (2017)
PT E
21-29.
[48] R. María-Hormigos, M.J. Gismera, J.R. Procopio, M.T. Sevilla, Disposable screen-printed electrode modified
CE
with bismuth–PSS composites as high sensitive sensor for cadmium and lead determination, J. Electroanal. Chem.
AC
767 (2016) 114-122.
[49] K. Crowley, J. Cassidy, Trace Analysis of Lead at a Nafion-Modified Electrode Using
Square-Wave Anodic Stripping Voltammetry, Electroanalysis 14(15-16) (2002) 1077-1082. [50] Y. Cheng, H. Fa, W. Yin, C. Hou, D. Huo, F. Liu, Y. Zhang, C. Chen, A sensitive electrochemical
sensor for lead based on gold nanoparticles/nitrogen-doped graphene composites functionalized with l-cysteine-modified electrode, J. Solid State Electrochem. 20(2) (2015) 327-335. [51] W. Li, X. Yao, Z. Guo, J. Liu, X. Huang, Fe3O4 with novel nanoplate-stacked structure:
28
ACCEPTED MANUSCRIPT
Surfactant-free hydrothermal synthesis and application in detection of heavy metal ions, J. Electroanal. Chem. 749 (2015) 75-82. [52] Y. Sun, W. Chen, W. Li, T. Jiang, J. Liu, Z. Liu, Selective detection toward Cd2+ using
Fe3O4/RGO nanoparticle modified glassy carbon electrode, J. Electroanal. Chem. 714-715 (2014)
AC
CE
PT E
D
MA
NU
SC
RI
PT
97-102.
29
ACCEPTED MANUSCRIPT
PT E
D
MA
NU
SC
RI
PT
Graphical abstract
Schematic illustration of the fabrication process of the nitrogen-doped laser engraved graphene
CE
modified glassy carbon electrode (N@LEG-GCE) for the simultaneous determination of cadmium
AC
(Cd(II)) and lead (Pb(II)) by square wave anodic stripping voltammetry (SWASV).
30
ACCEPTED MANUSCRIPT
Highlights 1. The 3D porous nitrogen-doped laser engraved graphene (N@LEG) was easily fabricated by laser engraving technique.
PT
2. The sensor possessed very wide detection ranges due to the large specific surface areas of 3D
RI
porous stacked graphene sheets structures and the influence of nitrogen-doped graphene.
SC
3. The sensor exhibited quite wide linear ranges varying from 5 to 10 g L-1 and 10 to 380 g L-1 for
AC
CE
PT E
D
MA
NU
Cd(II), and 0.5 to 10 µg L-1 and 10 µg L-1 to 380 µg L-1 for Pb(II), respectively.
31