RSC Advances View Article Online Open Access Article. Published on 05 November 2021. Downloaded on 11/6/2021 2:04:38 PM. This article is licensed under a Creative Commons Attribution 3.0 Unported Licence. PAPER Cite this: RSC Adv., 2021, 11, 35783 View Journal | View Issue Phenolic water toxins: redox mechanism and method of their detection in water and wastewater† Tayyaba Kokab,a Afzal Shah, *a Jan Nisar, b Muhammad Naeem Ashiq,c M. Abdullah Khan,d Sher Bahadar Khan e and Esraa M. Bakhshe Phenolic pollutants are highly toxic and persistent in the environment. Their efficient detection is a pressing social demand. In this regard we introduce a novel ultrasensitive electroanalytical platform for the individual and synchronized detection of three phenolic isomers commonly known as hydroquinone (HQ), resorcinol (RC), and catechol (CC). The sensing device consists of a glassy carbon electrode (GCE) modified with functionalized carbon nanotubes (fCNTs) and gold–silver (Au–Ag NPs) bimetallic nanoparticles. The sandwiched scaffold represented as fCNTs/Au–Ag NPs/fCNTs/GCE efficiently senses HQ, RC, and CC with detection limits of 28.6 fM, 36.5 fM and 42.8 fM respectively. The designed sensor is more Received 24th July 2021 Accepted 15th October 2021 promising than reported sensors for phenolic toxins in the context of high sensitivity, selectivity, and rapid responsiveness. The designed sensor also shows the qualities of stability, reproducibility, reliability, and selective recognition capacity for target analytes in multiple real water samples. Moreover, DOI: 10.1039/d1ra05669g rsc.li/rsc-advances computational calculations explain the function of the electrode modifier in facilitating charge transfer between the transducer and analytes. 1. Introduction Hydroquinone (HQ), resorcinol (RC), and catechol (CC) are extensively used in tanning, metallurgy, petrochemicals, and cosmetics.1–4 Ingestion of these isomeric compounds even at a miniscule level is detrimental owing to their genotoxicity, carcinogenicity and poor degradability.5 A literature survey revealed the involvement of HQ, CC, and RC in causing headaches, fatigue, acute myeloid leukemia, gastrointestinal tract a Department of Chemistry, Quaid-i-Azam University, Islamabad, 45320, Pakistan. E-mail: afzals_qau@yahoo.com b National Centre of Excellence in Physical Chemistry, University of Peshawar, Peshawar 25120, Pakistan c Institute of Chemical Sciences, Bahauddin Zakaryia University, Multan 6100, Pakistan d Renewable Energy Advancement Laboratory, Department of Environmental Sciences, Quaid-i-Azam University, Islamabad, 45320, Pakistan e Department of Chemistry, King Abdulaziz University, P.O. Box 80203, Jeddah 21589, Saudi Arabia † Electronic supplementary information (ESI) available: The development process of fCNTs/Au-Ag NPs/fCNTs nanocomposite sensor (Scheme S1); EIS and CV experimental data (Fig. S1, Table S1); optimization of voltammetric experimental factors; the inuence of the modier amount (Fig. S2); accumulation potential and time (Fig. S3); effect of scan rate (Fig. S4); effect of stripping electrolyte and pH (Fig. S5); gures of merits of the designed sensor (Table S2); interference study for validation of sensor (Fig. S6); tabulated data of real samples analysed by standard addition method for application of methodology (Table S3); computational studies (Table S4 & S5). See DOI: 10.1039/d1ra05669g © 2021 The Author(s). Published by the Royal Society of Chemistry degeneration, liver malfunction, hemolysis, and DNA damage.6 The US Environmental Protection Agency (EPA) and World Health Organization (WHO) have proclaimed these chemicals as primary toxins.7 Hence, it is a social obligation to develop a protocol for the concurrent minute level detection of HQ, CC, and RC in environmental samples. Although a considerable progress for the detection of individual dihydroxybenzene isomers (DHBIs) i.e., HQ, CC, and RC has been made, but simultaneous detection of minute level concentration of these isomers is still a challenging task. To deal with this challenge a number of reports on synchronized micro to nanomolar detection of HQ, RC, and CC are available,2–6,8–15 however, new materials are urgently required for picomolar to femtomolar simultaneous sensing of these isomeric water toxins. In this regard carbon nanotubes (CNTs) are promising materials for electrode modication by virtue of their structure that supports efficient electron transport.16–21 The conducting features of CNTs are further improved by the incorporation of metal nanoparticles (NPs).22–25 Biocompatible nanomaterials such as metal (iron, gold, zinc, copper and silver etc.) nanoparticles (M NPs) bestow unique electrochemical recognition capacity to the electrode for organic analytes.17,18 Precious metal nanoparticles (NPs) in conjunction with CNTs confer the electrode surface with electroactive features.21 Several authors have demonstrated that noble bimetallic alloy nanoparticles owe exceptional affinity for organic analytes than their single-metal analogues.23,24 Electrochemical results of Au–Ag NPs deposited on GCE reveal that Au–Ag NPs (2 : 1) are active for RSC Adv., 2021, 11, 35783–35795 | 35783 View Article Online Open Access Article. Published on 05 November 2021. Downloaded on 11/6/2021 2:04:38 PM. This article is licensed under a Creative Commons Attribution 3.0 Unported Licence. RSC Advances the distinct electrocatalytic oxidation of target isomers. Considering the remarkable electrocatalytic and biocompatibility characteristics, robust adsorption ability and excellent conducting features of noble bimetallic NPs,22–25 we integrated CNTs with gold-silver NPs for the development of a highly sensitive nanosensor. The recognition capacity of the sensing surface was further enhanced by the induction of the Au–Ag NPs between the layers of –COOH functionalized carbon nanotubes CNTs (COOHfCNTs) to form a sandwiched nanocomposite (fCNTs/Au–Ag NPs/fCNTs). The functional groups (–OH, –COOH) of fCNTs offer electrostatic affinity for Au–Ag NPs which in turns prohibit their agglomeration.26,27 Consequently, the distribution of bimetallic NPs onto large active surface of fCNTs network improves the physiochemical features such as conductivity, signal amplication and electrocatalytic performance of the nanosensor for the discrimination of target isomeric analytes. Literature survey2–6,8–15 reveals that the reported sensors for the solo and concurrent detection of DHBIs demand improvement in sensitivity. Our designed sensing platform based on Au–Ag NPs decorated fCNTs present practically superior gures of merit for the target phenolic isomers than a plethora of electrode modiers such as protein units (amino acids), organic compounds (2,5-dimercapto-1,3,4-thiadiazole, 3,5-diamino1,2,4-triazole-CO covalent organic frame work lm, polydiallyldimethylammonium chloride), inorganic conductors (metal NPs, amino functionalized ordered mesoporous silica), and carbonaceous compounds (nitrogen-doped carbon nanobers, porous graphene, graphene sheets embedded carbon).2–15 To the best of our knowledge, this is the rst report about a sensor development that selectively senses the target isomers concurrently with detection limits in the femtomolar range. 2. Experimental 2.1. Chemicals Chemicals of analytical grade procured from Alfa Aesar, Merck Germany, or/and Sigma Aldrich were used in this work. Solutions of HCl, H2SO4, H3BO3, NaOH, KCl, C2H3NaO2, CH3COOH, H3PO4, and Na3PO4 were used for the preparation of different supporting electrolytes. Doubly deionized water (ddw) was used to prepare analyte's solutions, phosphate buffer solution (PBS), Britton–Robinson buffer (BRB), acetate buffer solution (ABS), and solutions of interfering agents. Moreover, the glass kits were used aer cleaning with conc. HNO3 and double distilled water to avoid chances of contamination. 2.2. Synthesis of bimetallic nanoparticles and functionalization of CNTs Au–Ag NPs (2 : 1) were prepared via our reported coprecipitation procedure.28 The growth of the synthesized NPs was conrmed by UV-Vis spectroscopy and XRD analysis as shown in Fig. 1A and B. The NPs were obtained by centrifugation subsequently puried with acetone and ethanol. The Au–Ag NPs (2 : 1) 1 mg mL 1 dispersion was made in ethanol by ultrasonic agitation for 30 minutes. Commercially procured 35784 | RSC Adv., 2021, 11, 35783–35795 Paper pristine CNTs were rened and functionalized under harsh oxidative conditions. For this purpose, 0.2 L of 1 : 3 v/v of 2 M HNO3 and 2 M H2SO4 solution was added with 1 g CNTs. The resulting solution was reuxed at 140  C for 2 h to speed up the oxidation process. Then, the mixture was separated by 0.25 mm cellulose membrane and the precipitates were washed continuously with ddw until neutral pH of the ltrate. The precipitates were dehydrated at 100  C for 3 hours in a curing oven and the resultant product designated as COOH-fCNTs was characterized via FTIR and XRD as shown in Fig. 1C and D.29 2.3. Modication of GCE with fCNTs/Au–Ag NPs/fCNTs Before modication physiochemical cleaning steps were performed to upgrade the O/C ratio of the GCE surface.30 The electrode surface was rst gently scrubbed on a nylon cushion with g-Al2O3 paste until the appearance of a polished surface. It was then rinsed with ddw, ethanol, and aq. HNO3 (1 : 1, v/v) followed by drying with a drier at room temperature. Aerwards, the chemical cleaning of GCE was performed in the potential window of 0.2 V to + 1.8 V, vs. Ag/AgCl (3 M KCl) reference electrode, to obtain multiple reversible cyclic voltammograms in 0.1 M HClO4 until the attainment of a reproducible surface. The GCE fabrication was done by drop coating of fCNTs and Au–Ag NPs via layer-by-layer (LBL) and mixing methods.31 For LBL, a 4 mL droplet of COOH-fCNTs (1 mg mL 1) black suspension was carefully casted on a pre-cleaned GCE surface and dried in vacuum oven. Then, 1 mL droplet of Au–Ag NPs (1 mg mL 1) was coated on the already prepared fCNTs/GCE. Aer that, a 4 mL droplet of COOH-fCNTs solution was placed and dried on the Au–Ag NPs/fCNTs/GCE to develop fCNTs/Au– Ag NPs/fCNTs/GCE. While in the mixing method of electrode modication, one mg of Au–Ag NPs was added in 5 mL of 1 mg mL 1 fCNTs dispersion and mixed under ultra-sonication for 30 min. A 5 mL droplet of the prepared mixture was casted and dried on the GCE surface to prepare Au–Ag NPs/fCNTs/GCE. For comparison purpose, Ag NPs/GCE, Au–Ag (1 : 1)/GCE, Au NPs/ GCE, Au–Ag (2 : 1)/GCE, Au–Ag (1 : 2)/GCE, Au–Cu (1 : 1)/GCE, Au–Cu (1 : 2)/GCE, Au–Cu (1 : 3)/GCE, Au–Cu (3 : 1)/GCE, Au– Cu (2 : 1)/GCE, Ag–Cu (1 : 1)/GCE, COOH-fCNTs/GCE, pristine CNTs/GCE, and NH2-fCNTs/GCE were also devised. Before use all the fabricated GCEs were thoroughly rinsed with ddws and PBS to strip off any loosely attached modier molecules.16 Fabrication steps for the preparation of fCNTs/Au–Ag NPs/ fCNTs/GCE can be seen in Scheme S1.† 2.4. Instruments for characterization and design of experiment The synthesized nanomaterials, crystallographic conguration and structural properties were analysed at XRD (model # Panalytical 3040/60 X pert PRO diffractometer) having beam source CuKa at 40 kV/40 mA voltage/current. The spectrum was obtained at a scan rate of 0.01 s 1 from 10 to 70 (2q). Likewise, the optical behaviour of the synthesized materials was studied at UV-Visible spectrophotometer (model # Shimadzu 1601) in the wavelength range of 200–1100 nm and path length of 1 cm. © 2021 The Author(s). Published by the Royal Society of Chemistry View Article Online RSC Advances Open Access Article. Published on 05 November 2021. Downloaded on 11/6/2021 2:04:38 PM. This article is licensed under a Creative Commons Attribution 3.0 Unported Licence. Paper Structural characterization: (A) The XRD of Au–Ag NPs (B) UV-Vis spectrum of Au–Ag NPs (C) FTIR spectrum of pristine and functionalized CNT (D) XRD pattern of pristine and functionalized CNT (E) XRD pattern of COOH-fCNTs/Au–Ag NPs/COOH-fCNTs, Au–Ag NPs and COOHfCNTs (F) UV-Visible spectra of COOH-fCNTs/Au–Ag NPs/COOH-fCNTs and Au–Ag NPs. Fig. 1 Further, the functionalization of the as-synthesized products was conrmed through Fourier transform infrared spectroscopy (model # Thermo Scientic Nicolet 6700 FTIR spectrometer) at 400–4000 cm 1 wavelength region. Moreover, the chemical composition and morphological features of the as-synthesized products were probed through scanning electron microscopy © 2021 The Author(s). Published by the Royal Society of Chemistry (SEM) and energy-dispersive X-ray spectroscopy (EDX) (model # ZEISS EVO 40 Merlin, Carl Zeiss). Electrochemical characterization was performed on Metrohm Auto lab PGSTAT302N Switzerland. A 3-electrode convectional system was used which consisted of working electrode bare and modied glassy carbon electrode; Ag/AgCl (conc. KCl) reference electrode; and counter RSC Adv., 2021, 11, 35783–35795 | 35785 View Article Online RSC Advances Paper electrode (CE) made of platinum wire. All electrochemical experiments were operated under an inert environment. Open Access Article. Published on 05 November 2021. Downloaded on 11/6/2021 2:04:38 PM. This article is licensed under a Creative Commons Attribution 3.0 Unported Licence. To test the viability of the designed fCNTs/Au–Ag NPs/fCNTs/GCE sensor for the synchronized evaluation of the HQ, CC, and RC, multiple real-time water samples consisting of drinking, tap, spring, rain, lake, river, and sea water samples were used. The target analytes were also investigated in complex matrixes such as articial wastewater and vegetable juices (spinach and onion juice). Before use all water samples were ltered several times by Whatman lter paper of pore size 8 mm to eliminate impurities and diluted with 1 : 1 PBS buffer of pH 6. Articial wastewater samples containing 5 mM industrial pollutants such as metal ions, organic toxins other than the target analytes, surfactants etc. were also prepared. Moreover, before SWASV analysis, onion and spinach samples were crushed into juices, then centrifuged for 15 min at 5000 RPM and the resultant supernatants were diluted twenty times with ddw. Aer voltammetric analysis of all the real samples, % recoveries of the stated isomers were determined by a usual spiking method to authenticate the precision and antiinterferent ability of the proposed procedure. 2.6. Computational calculations Theoretical studies of the phenolic isomers and their intermolecular interactions with the designed fCNTs/Au–Ag NPs/fCNTs nanocomposite were performed by DFT, and M06-2X calculations on Gaussian 09 soware to nd relationship between chemical descriptors and experimental data. Molecular geometries of the isomers and their oxidized products were optimized by using DFT (B3LYP) with basis set 6-311G++ (d, p) and the obtained data were used for calculations of the quantum molecular descriptors.32 Then, the catalytic role of the sensor was probed by M06-2X functional that indirectly accounts the dispersion interactions (hydrogen bonding and van der Waals forces) of sensor/dihydroxybenzene isomers (DHBIs) in aqueous media. Firstly, the geometries of Au–Ag NPs (triatomic Au(2)– Ag(1) system) and COOH-fCNTs (4 COOH groups on armchair (5, 5)) were optimized through function M06-2X with LaNL2DZ, and 6-311G++ (d, p) basis sets respectively and then their quantum features were estimated. Aerwards, the optimization of the blended systems (optimized DHBIs on the Au–Ag NPs surface) was carried out at function M06-2X and basis set LANL2DZ and the quantum descriptors were calculated for their reactivities and binding energies. Similarly, the optimization of the merged systems (optimized DHBIs at Au–Ag NPs/COOHfCNTs surface) was performed at function M06-2X and basis set LANL2DZ followed by computing their reactivities and binding energies. Notably, the surfaces on which DHBIs molecules congured parallel to Au–Ag NPs/COOH-fCNTs were processed to maximize the p–p stacking interactions in CNTs/ DHBIs structures. From the data, the binding energies DE (eV) were calculated by the following equations; NPs-DHBIs) NPs-DHBIs) (EfCNTs + EAu-Ag NPs + EDHBIs) where, E(Au-Ag NPs-DHBIs) and E(fCNTs-Au-Ag NPs-DHBIs) are the total interaction energies of the blended systems while EfCNTs, EAu-Ag 33 NPs, and EDHBIs are the energy values of the single structures. 2.5. Real water samples DE ¼ E(Au-Ag DE ¼ E(fCNTs-Au-Ag (EAu-Ag 35786 | RSC Adv., 2021, 11, 35783–35795 NPs + EDHBIs) 3. Results and discussion The oxidation response of dihydroxybenzene isomers (DHBIs) was investigated at Ag NPs/GCE, Au NPs/GCE, Au–Ag (1 : 1)/ GCE, Au–Ag (2 : 1)/GCE, Au–Ag (1 : 2)/GCE, Au–Cu (1 : 1)/GCE, Au–Cu (1 : 2)/GCE, Au–Cu (1 : 3)/GCE, Au–Cu(2 : 1)/GCE, Au– Cu (3 : 1)/GCE, and Ag–Cu (1 : 1)/GCE, pristine CNTs/GCE, NH2fCNTs/GCE, COOH-fCNTs/GCE and COOH-fCNTs/Au–Ag (2 : 1) NPs/COOH-fCNTs/GCE. The best response was obtained using COOH-fCNTs/Au–Ag (2 : 1) NPs/COOH-fCNTs as the recognition layer of the nanosensor. Characterization details and electrochemical performance of the designed nanosensor for DBHIs analysis have been presented in the following sections. 3.1. Structural description of the nanocomposite The synthesis of bimetallic Au–Ag NPs, functionalization of CNTs, and development of fCNTs/Au–Ag NPs/fCNTs nanocomposites were veried by XRD, UV-Vis spectroscopy and FTIR analysis. The XRD pattern of Au–Ag NPs demonstrated in Fig. 1A has three distinct diffraction peaks at 38.7 , 44.5 and 64.3 which are indexed as (111), (200), and (220) crystallographic planes of the face centered cubic (FCC) structure. The crystalline nature of Au–Ag NPs corresponds to JCPDS cards 00-0011174 & 00-004-0783. Owing to analogous lattice constants of Au and Ag metals, their d spacing and 2q values are very close to each other. This makes precise assignment of individual reections of bimetallic Au–Ag NPs virtually difficult. The relatively broad high intensity diffraction peaks of Au–Ag bimetallic NPs encompassing 2q positions of monometallic peaks suggest the development of Au–Ag alloy structure. The mean size of Au– Ag NPs was calculated as 32 nm. In addition, the presence of characteristic (002) and (100) planes at 25.8 and 44.1 ensures the crystalline graphitic CNTs (Fig. 1D). The decrease in intensities and broadening of the peaks corresponding to loss of crystallinity in COOH-fCNTs pattern compared to pristine CNTs conrm functionalization that leads to disruption of the CNTs' wall.29 Whereas, all individual peaks with a small loss in intensities and slight broadening are present in the XRD pattern of the composite NPs/COOH-fCNTs. Fig. 1E shows the XRD pattern of COOH-fCNTs/Au–Ag NPs/COOH-fCNTs nanocomposite that conrms the presence of the FCC nature of Au– Ag NPs decorated onto the COOH-fCNTs matrix. The diffraction peak at 25.3 corresponds to COOH-fCNTs while other diffraction peaks at 39 , 44.9 and 64.8 can be assigned to the presence of FCC Au–Ag NPs in the nanocomposite. The XRD pattern endorses the synthesis of COOH-fCNTs/Au–Ag NPs/COOHfCNTs nanocomposite. Moreover, investigation of the optical behaviour of Au–Ag NPs using UV-visible spectroscopy demonstrates surface plasmon resonance (SPR) range centred at 468 nm (Fig. 1B and F). This signal of Au–Ag alloy appearing © 2021 The Author(s). Published by the Royal Society of Chemistry View Article Online Open Access Article. Published on 05 November 2021. Downloaded on 11/6/2021 2:04:38 PM. This article is licensed under a Creative Commons Attribution 3.0 Unported Licence. Paper between the characteristic SPR bands of Au and Ag NPs further validates the creation of Au–Ag alloy NPs.28 FTIR analysis shows the representative peaks of pristine and fCNTs. The signal matching to the C–H elongating vibration of methylene at 2900– 2850 cm 1, broad –OH band in –COOH functionalized fCNTs at 3458 cm 1 and the peak of carbonyl (–C]O) group of carboxylic acid at 1740 cm 1 (Fig. 1C) conrms the successful functionalization of pristine CNTs by HNO3 and H2SO4 acids treatment. The peaks within 1675 cm 1 to 1496 cm 1 can be related to different acetyl/ketone/quinone (–C]O) groups and the C–C vibrations of benzene rings. The bands in the range of 1450 cm 1 to 650 cm 1 corresponding to C–H deformation (1439 cm 1), COO-stretch (1410 cm 1), C–O deformation (1386 cm 1), C–H symmetric stretching (1254 cm 1), C–O stretching vibrations (1151 cm 1), C–O–C vibrations (1093 cm 1), C–H in-plane deformation (1062 cm 1), C–C stretching (954 cm 1) and O–C]O bending (659 cm 1) infers effective acidication of CNTs.29 3.2. Morphological characterization of designed sensor The morphology of layer by layer (LBL) modied electrochemical nanosensor was examined by SEM coupled with EDX. Fig. 2 illustrates the SEM of bare GCE, fCNTs/GCE, Au–Ag NPs/ fCNTs/GCE, and fCNTs/Au–Ag NPs/fCNTs nanocomposite modied GCE. Physiochemically cleaned bare GCE has a smooth surface (Fig. 2A) while threads of fCNTs are observable in fCNTs/GCE (Fig. 2B). The surface structure and surface area of fCNTs/GCE are noticeably altered by the addition of Au–Ag NPs (Fig. 2C). Spherical Au–Ag NPs are homogeneously RSC Advances dispersed at the densely packed tubular prole of fCNTs. The average size of 30 nm of the Au–Ag NPs validates the size estimated from their XRD (Fig. 1A). A complete pattern of fCNTs/Au–Ag NPs/fCNTs/GCE presents a porous microstructure (Fig. 2D) as required for effective absorption of the analytes. EDX analysis of the fCNTs/Au–Ag NPs/fCNTs conrms the carbon, oxygen, gold, and silver elements presence (Fig. 2E). Moreover, the EDX spectrum Au/Ag ratio (2 : 1) veries successful synthesis of the nanospheres. 3.3. Electrochemical characterization of the designed nanosensor The designed nanosensor was rst characterized by CV and EIS techniques. The key performance metrics about electron transduction mechanism, active surface area, extent of immobilization of the electrode modier, and impedance variation at the bare and modied electrodes surfaces were obtained according to the reported method.34 The noticeable amplied and shied reversible signals of the standard redox reporter (K3[Fe(CN)6]) at fCNTs/Au–Ag NPs/fCNTs/GCE propose exceptional electrocatalytic behavior of the nanocomposite that facilitates faster charge transport between the analyte and transducer (Fig. S1A†). An observation of Table S1† reveals that the working surface area of the electrodes as determined by Randles–Sevcik equation2 are 0.02 cm2 (bare GCE), 0.04 cm2 (Au–Ag NPs GCE), 0.07 cm2 (Au–Ag NPs/fCNTs/GCE) and 0.11 cm2 (fCNTs/Au–Ag NPs/fCNTs/GCE) respectively. Likewise, EIS analysis was performed and the corresponding Nyquist plots for the data obtained at bare GCE, Au–Ag NPs/GCE, Au–Ag NPs/ Fig. 2 The SEM images of (A) bare GCE, (B) fCNTs fabricated GCE, (C) Au–Ag NPs/fCNTs/GCE, (D) fCNTs/Au–Ag NPs/fCNTs/GCE and (E) EDX spectra of fCNTs/Au–Ag NPs/fCNTs/GCE (F). © 2021 The Author(s). Published by the Royal Society of Chemistry RSC Adv., 2021, 11, 35783–35795 | 35787 View Article Online RSC Advances Open Access Article. Published on 05 November 2021. Downloaded on 11/6/2021 2:04:38 PM. This article is licensed under a Creative Commons Attribution 3.0 Unported Licence. fCNTs/GCE and fCNTs/Au–Ag NPs/fCNTs/GCE can be seen in Fig. S1B and Table S1.† The signicantly smaller charge transfer resistance Rct (1.5  10 5 U) of the nanosensor as compared to Rct (6450 U) at bare GCE points to improved charge transduction through the modied electrode represented as fCNTs/Au–Ag NPs/fCNTs/GCE. EIS results also validate immobilization of the recognition layer of fCNTs/Au–Ag NPs/fCNTs at the GCE with a uniform surface (supported from CPE and n values).34–36 3.4. Voltammetric analysis for examining the nanosensor performance Cyclic and square wave anodic stripping voltammetric analysis of the HQ, RC, and CC mixture were performed at the bare and modied GCEs. At bare GCE, the HQ-CC overlapped oxidation band came to sight around 378 mV while the oxidation signal of RC emerged at 695 mV. In contrast, well-distinguished signals of the three DHBIs appeared at all modied GCEs with signicantly higher currents at the fCNTs/Au–Ag NPs/fCNTs/GCE (Fig. 3A). Both the Ipc and Ipa peaks of HQ and CC appeared at fCNTs/Au–Ag NPs/fCNTs/GCE. The smaller reduction peak currents than the oxidation signals suggests quasireversible processes that involve charge transfer reaction aer that chemical reaction (EC mechanism).5 However, the cyclic voltammograms display a small oxidation peak current of RC at 649 mV with no corresponding reduction peak suggesting the instability of the oxidized product of RC at the designed sensor surface. In addition, the SW voltammograms of the DHBIs show a more clear difference in the response at the bare and modied GCEs (Fig. 3B). The signals of the DHBIs are fused resulting in a broad wave at the bare GCE while well resolved signals are observable at the modied nanosensors. Moreover, a signicant shi in the signals of DHBIs at fCNTs/Au–Ag NPs/fCNTs/GCE than the other modied GCEs endorses its highest electrocatalytic activity. The gradual decrease of overpotential from RC Paper to CC to HQ can be related to the increase in their electronic densities that lead to increase in electroactivity of these isomers.14,37 The shiing of peaks of HQ (92 mV), CC (192 mV), and RC (671 mV) to low positive potentials at the fCNTs/Au–Ag NPs/fCNTs/GCE suggests the absence of CC interference in HQ oxidation which excludes the fouling of the electrode surface by their oxidized products. Interestingly the difference of peak potentials DEp(HQ-CC) (100 mV) and DEp(CC-RC) (479 mV) is large enough to ensure synchronized sensing of HQ, CC, and RC at the designed fCNTs/Au–Ag NPs/fCNTs/GCE. Hence, SWASV was applied for the simultaneous sensing of the three isomers. 3.5. Optimization of conditions and working principle of the nanosensor The modier amount and pre-concentration (deposition potential, and time) step were tested to get optimized conditions for intense signals of DHBIs (Fig. S2–S3†). The scan rate effect (Fig. S4†) and inuence of the pH of the medium (Fig. 4) were also studied for probing the redox mechanism of DHBIs at the fCNTs/ZnO/fCNTs/GCE surface. The nature of stripping electrolytes and their pH values critically affect the redox signals of analytes and their deposition process at the sensor surface. In this regard, a series of acidic, basic, neutral, and buffered stripping electrolytes mentioned in Fig. 4A were studied for HQ (10 mM), CC (12.5 mM) and RC (15 mM) analysis at the fCNTs/Au– Ag NPs/fCNTs/GCE. Intense and reproducible signals of the isomers were observed in a solution buffered with PBS (pH 6). Therefore, it was chosen as the working medium for the synchronized analysis of the DHBIs. The pH value can uctuate the position and current amplitude of the signals. Variation in peak position suggests the involvement of protons during electrooxidation of HQ, CC, and RC at the electrode surface. For the DHBIs, the peak currents variations with the increase of pH from 3.0 to 7.6 are shown in Fig. 3 (A) Cyclic voltammograms of HQ (12.5 mM), CC (15 mM), and RC (17.5 mM) mixture at bare GCE, Au–Ag NPs/GCE, Au–Ag NPs/fCNTs/GCE, fCNTs/GC electrode and fCNTs/Au–Ag NPs/fCNTs/GCE in PBS of pH 6 at a sweep rate of 100 mV s 1. (B) The SWASV of HQ (10 mM), CC (12.5 mM), and RC (15 mM) mixture attained at (i) bare GCE (ii) Au–Ag NPs/GCE (iii) CNTs/GCE (d) fCNTs/GCE (iv) Au–Ag NPs/fCNTs/GCE, and (v) fCNTs/ Au–Ag NPs/fCNTs/GCE (vi) fCNTs/Au–Ag NPs/fCNTs/GCE in 1 : 1 aq. solvent and PBS (pH 6) stripping solvent at a sweep rate 100 mV s 1 keeping deposition potential of 0 V and accumulation time of 200 s. 35788 | RSC Adv., 2021, 11, 35783–35795 © 2021 The Author(s). Published by the Royal Society of Chemistry View Article Online Open Access Article. Published on 05 November 2021. Downloaded on 11/6/2021 2:04:38 PM. This article is licensed under a Creative Commons Attribution 3.0 Unported Licence. Paper RSC Advances Fig. 4 (A) Bar graph showing the influence of various supporting media such as 0.1 M H2SO4, 0.1 M NaOH, 0.1 M HCl, 0.1 M KCl, PBS (pH 6), ABS (pH 5.6), and BRB (pH 3) on the SWASV peak currents of HQ (10 mM), CC (12.5 mM), and RC (15 mM) mixture at deposition potential of 0 V and deposition time of 5 s at 100 mV s 1 scan rate using LBL modified GCE with 4 mL fCNTs/1 mL Au–Ag NPs/4 mL fCNTs. (B) The SWASVs as a function of pH obtained under the same conditions (C) plots of Ip of HQ, CC, and RC vs. pH (D) plots of Ep of HQ, CC, and RC vs. pH along with regression equations. Fig. 4B. The gradual increase of DHBIs signals till pH 6 indicates the existence of isomers (pKa ¼ 9.0) in acid–base equilibrium (Fig. 4C). At higher pH, the decrease in signals height can be attributed to the likely deprotonation of DHBIs and oxygen functionalities of fCNTs. Consequently, the kinetically unfavourable oxidation reactions related to the electrostatic repulsion at the sensor/electrolyte interface may lead to unstable and inefficient adsorption of DHBIs in alkaline media. Thus, to achieve excellent sensitivity and well resolved DHBIs peaks at fCNTs/Au–Ag NPs/ fCNTs/GCE, the PBS of pH 6 was used. The linear plots of Ep vs. pH are nearly parallel showing a steady peak to peak difference in the studied pH range as illustrated in Fig. 4D. Moreover, the slope of Ep vs. pH plots (Nernstian slope 58.5 mV pH 1)1 suggests the involvement of equal number of protons and electrons in the redox reaction of DHBIs at the nanosensor surface. The proposed pH dependent electro-oxidation mechanism of DHBIs can be seen in Scheme 1. The superior performance of the designed nanosensor for the electrooxidation of HQ, RC, and CC can be credited to the © 2021 The Author(s). Published by the Royal Society of Chemistry synergistic role of fCNTs and Au–Ag NPs (Scheme 2).38 The fCNTs facilitate electron transfer rate due to their conductive nature and support adsorption of DHBIs during the preconcentration step of SWASV.39–41 Likewise, the fCNTs have different space resistances for different DHBIs, thereby improving the voltammetric discrimination between the isomers by lowering their overpotentials.16,41 Moreover, the oxygen functionalities of the fCNTs can develop hydrogen bonding with the DHBIs hydroxyl groups (H/O–H).27,42 In addition, the hydrogen bonds may also be developed between the surface adsorbed analytes and their aqueous dissolved species.43 The rings of CNTs can offer additional p–p interactions to the benzene unit of DHBIs via solute–sorbent interactions to boost their regional concentration and enhance electrocatalytic redox events (Scheme 2). Moreover, metal NPs exert their electrocatalytic role for the oxidation of the DHBIs via metal nuclei active sites and the mechanism follows conventional heterogeneous catalysis process as reported by the RSC Adv., 2021, 11, 35783–35795 | 35789 View Article Online Open Access Article. Published on 05 November 2021. Downloaded on 11/6/2021 2:04:38 PM. This article is licensed under a Creative Commons Attribution 3.0 Unported Licence. RSC Advances Paper and LOQ ¼ 10s/m), where “s” signies the standard deviation of “n” times repeat of voltammograms of blank experiments (in electrolyte solution only) performed at the nanosensor and calibration plot (conc. vs. Ip) slope “m”. Likewise, the linear concentration ranges (LCRs) relate to the liner segment of the calibration plot. We assessed these parameters for DHBIs under optimized conditions at fCNTs/Au–Ag NPs/fCNTs/GCE by SWASV. The results show a steady rise in Ip of HQ, RC, and CC with continuous addition of their investigated concentrations (Fig. 5A). The corresponding calibration curves shown in Fig. 5B were used for the evaluation of the sensor's performance parameters as listed in Table S2.† The femtomolar LODs of the target analytes demonstrates the superior gures of merit and selectivity of the designed nanosensor. The trend of sensitivity at the sensing scaffold follows the sequence; HQ > CC > RC which is in accordance with the electro-activities of these isomers. 3.7. Reproducibility, reusability, and stability of the designed sensor Scheme 1 Proposed pH dependent redox reactions of HQ, CC, and RC. previous investigators.25,43 The combined effect of all the above mentioned interactions giving rise to a sensitive electrochemical scaffold for the discrimination and concurrent sensing of all the three isomers has been portrayed in Scheme 2. 3.6. Analytical features of the designed nanosensor The detection limit (LOD) and the quantication limit (LOQ) can be evaluated from their typical descriptions (LOD ¼ 3s/m The accuracy and precision of the nanosensor was examined by evaluating its reusability, reproducibility, and stability. For reproducibility test experiments were performed under the same conditions on six GCEs modied with the same nanocomposite (fCNTs/Au–Ag NPs/fCNTs) as illustrated in Fig. S5A,† while stability and reusability characteristics were investigated over a consistent time interval at the same nanosensor as revealed in Fig. S5B.† The fCNTs/Au–Ag NPs/fCNTs/GCE was reserved in a desiccator at RT when not in use during repeatability analysis. The current response of the tri-analytes DHBIs mixture under optimized conditions with variation of less than 2% RSD pointed to the promising reliability of the designed sensing scaffold. An evaluation of the analytical features of the designed sensing platform with the already reported systems for the solo and concurrent detection of the HQ, CC, and RC is specied in Table 1. The calculated gures of merit especially the LOD values are far better than the suggested limits for these toxic hydrophilic isomers.30 Remarkably, the LODs for the target DHBIs attainable by using the stated platform are much better than any sensors reported so far.2–6,8,10–15 Hence, the designed electrochemical nanosensor is novel in the perspective of sensitivity, stability and selectivity. 3.8. Interference study for practical applicability of the sensor Suggested oxidation mechanism of HQ, CC, and RC at the designed nanosensor. Scheme 2 35790 | RSC Adv., 2021, 11, 35783–35795 For examining the effect of interfering agents on the sensing performance of the designed nanosensor, the electrochemical responses of the DHBIs were equated in the absence and presence of the interferents under optimized conditions. The voltammograms and bar plots of the voltammetric response of 0.5 mM HQ, 0.625 mM CC, and 0.75 mM RC mixture in the coexistence of 2 mM amount of each organic/inorganic interferents (details given in Fig. S6† caption) can be seen in Fig. S6A & B.† The tolerance level of the designed sensor was observed as a % RSD <5% for these interferents. These outcomes manifest © 2021 The Author(s). Published by the Royal Society of Chemistry View Article Online Open Access Article. Published on 05 November 2021. Downloaded on 11/6/2021 2:04:38 PM. This article is licensed under a Creative Commons Attribution 3.0 Unported Licence. Paper RSC Advances Fig. 5 (A) The SWASV noted by synchronizing conc. variation of HQ, CC, and RC in PBS of pH 6, keeping sweep rate of 100 mV s 1, deposition potential of 0 V, and accumulation time of 200 s. (B) Calibration plot of voltammetric data of DHBIs presenting linearity segments of concentrations with Ip values along with their regression equations under optimized conditions of fCNTs/Au–Ag NPs/fCNTs/GCE. the exactness of the suggested sensor for the target analytes in the presence of multifold higher amounts of the interferents. 3.9. Investigation of real samples For validity of the fCNTs/Au–Ag NPs/fCNTs/GCE in water resources, HQ, CC, and RC were simultaneously analysed in 3matrixes of each real sample (drinking, tap, spring, rain, lake, river, sea, and articial wastewater, spinach, and onion juices). First, initial amounts of the DHBIs were assessed in all samples by SWASV and then known amounts of the isomers were spiked into the real samples and % recoveries were determined. The signal values of DHBIs in real samples were matched with their calibration plots shown in Fig. 4B. Each reading was triplicated Table 1 and % recoveries in the range of 96% to 105% with % RSD <2.5% were attained as summarized in Table S3.† The data validates the fCNTs/Au–Ag NPs/fCNTs/GCE for workable environmental analysis. 3.10. Computational studies For the perception of a molecular level detection of DHBIs and their respective quinones at the designed sensor, the quantum parameters of the cited toxins were studied theoretically (see Table S4†) to compare their qualitative trends as witnessed in voltammetric analysis. The HOMO (highest occupied molecular orbital) of the HQ, CC, and RC optimized structures and their respective ortho- para- and meta-quinones (Scheme 1) are Assessment of the sensing performance of fCNTs/Au–Ag NPs/fCNTs with reported sensors for HQ, CC, and RC LOD (nM) Sensors HMCCSsa/GCE Au/lys/OMC-Au/Tyr/GCE SiO2/C/Nb2O5 p-DMcT/GCE Co-SnO2 NPs DAT-COF/GCE NH2-SBA 15-silica/CPE PDDA-G-GCE NCNF/GCE P-rGO/GCE NaOH/GCE GSEC fCNTs/Au–Ag NPs/fCNTs/GCE Measurement technique DPV DPV DPV DPV SWV DPV DPV DPV DPV SWV SWV SWASV HQ CC RC Ref. 120 50 1200 100 450 130 300 250 300 80 10 100 28.6 fM 190 25 800 100 94 70 500 200 400 180 10 100 36.5 fM 1100 N.M N.M 300 N.M 80 800 N.M 800 2620 90 50 42.8 fM 2 3 4 5 6 8 10 11 12 13 14 15 This work a HMCCSs ¼ hollow molybdenum-dopamine spheres; lys ¼ lysine; Tyr ¼ tyrosinase; Au NPs ¼ gold nanoparticles; p-DMcT ¼ 2,5-dimercapto-1,3,4thiadiazole; DAT-COF ¼ 3,5-diamino-1,2,4-triazole-CO covalent organic framework lm; NH2-SBA 15-silica/CPE ¼ amino functionalized ordered mesoporous silica/carbon paste electrode; PDDA-G ¼ poly(diallyldimethylammonium chloride) functionalized graphene; NCNFs ¼ nitrogendoped carbon nanobers; P-rGO: porous graphene; GSEC ¼ graphene sheets embedded carbon. b N.M ¼ not measured. © 2021 The Author(s). Published by the Royal Society of Chemistry RSC Adv., 2021, 11, 35783–35795 | 35791 View Article Online Open Access Article. Published on 05 November 2021. Downloaded on 11/6/2021 2:04:38 PM. This article is licensed under a Creative Commons Attribution 3.0 Unported Licence. RSC Advances Paper Pictorial picture of HOMO of optimized structures of HQ, CC, RC, PQ, OQ and MQ by DFT on Gaussian 09 software B3YLP/6-311G + + (d, p) in water solvent. Fig. 6 portrayed in Fig. 6. The chemical reactivity of DHBIs related to their bandgap energy (Eg) shows minimum Eg of HQ (0.191 Hartree) which can be ascribed to its ease electrochemical oxidation than CC (0.199 Hartree) and RC (0.213 Hartree) (see Fig. 3). Likewise, other chemical descriptors of DHBIs listed in Table S4† also verify the experimental observation that HQ oxidizes before CC and RC and hence easily detectable owing to its kinetically more polarizable molecular structure.32 Conversely RC is difficult to oxidize (as witnessed by its peak potential value in CV and SWAS voltammograms shown in Fig. 3) owing to its highest ionization energy (IE). The higher electron affinity (EA) and lower IE values of HQ and CC indicate the formation of thermodynamically stable oxidized products, as witnessed by the reversibility of HQ and CC in CV proles (Fig. 3A). On the contrary, lower EA and higher ELUMO value of RC infer release of small amount of energy on the reduction of meta-quinone (quinone formed from RC oxidation) at CV reduction scan, which disfavours the reduction of RC to MQ due to instability of the product.4 Meanwhile, two carbons convert their hybridization state from sp2 to sp3 to generate MQ which is thermodynamically unstable, accordingly no reversibility of RC is observed in cyclic voltammograms (Fig. 3A). Thus, these analyzed theoretical values strongly support the qualitative electrochemical aspects of the DHBIs at the designed nanosensor. 35792 | RSC Adv., 2021, 11, 35783–35795 The key steps included in the sensing mechanism at the modied electrode involve adsorption of DHBIs molecules at the sensor surface and the synergistic role of the components of nanocomposite in facilitating charge transfer host (transducer) and guest (analyte). The catalytic mechanism at the designed sensor can be proposed on the basis of quantum descriptors of the DHBIs/Au–Ag NPs and DHBIs/fCNTs/Au–Ag NPs (Fig. 7 & Table S5†). The negative binding energies (DE(HQ) 0.15 Hartree, DE(CC) 0.09 Hartree and DE(RC) 0.03 Hartree) of DHBIs at the Au–Ag NPs surface indicate activation of the O–H functionalities of the DHBIs on interaction with Milliken charges of the Au–Ag NPs.32 Thereby, elongation of O–H bond, increase of polarizability (a) and reduction in energy gap (Eg) of DHBIs at Au–Ag NPs lead to their easier oxidation than free molecules. The calculated quantum properties listed in Table S5† reveals more stable adsorption and facile oxidation of HQ than CC and RC at Au–Ag NPs. The negative DE values of the COOH-fCNTs/Au–Ag NPs/ DHBIs merged system (DE(HQ) 5.6 Hartree, DE(CC) 4.1 Hartree, and DE(RC) 2.3 Hartree) than DHBIs/Au–Ag NPs suggest DHBIs capturing ability of the sensor owing to the synergy of Au–Ag NPs and COOH-fCNTs (Fig. 6, Table 2). Likewise, the decrease in Eg values at sensor surface corresponds to polarizable DHBIs molecules that further support the stable © 2021 The Author(s). Published by the Royal Society of Chemistry View Article Online Open Access Article. Published on 05 November 2021. Downloaded on 11/6/2021 2:04:38 PM. This article is licensed under a Creative Commons Attribution 3.0 Unported Licence. Paper RSC Advances The optimized structures of Au–Ag NPs (single atoms of Au and Ag), fCNTs (4-COOH group on single unit of armchair (5, 5)) and their merged systems with HQ, CC, and RC by M06-2X method on Gaussian 09 software in water solvent. Fig. 7 Table 2 The electronic properties of fCNTs (4-COOH groups on single armchair (5, 5)) and their DHBIs/Au–Ag NPs/fCNTs merged systems (Hartree units) calculated by function M06-2X with 6-311G + + (d, p) and LANL2DZ basis sets, respectively in water solvent Structural parameters fCNTs HQ/Au–Ag NPs/fCNTs CC/Au–Ag NPs/fCNTs RC/Au–Ag NPs/fCNTs E EHOMO 4198.38 4992.36 4993.72 4995.44 0.154 0.127 0.153 0.171 adsorption of DHBIs at the nanocomposite surface via noncovalent interactions (Fig. 3).33 The trend of HQ > CC > RC inferred from DE and reactivity quantities of the DHBIs at Au– Ag NPs/COOH-fCNTs is in accordance with the LOD values of DHBIs (Table S2†). These theoretical ndings not only endorse the authenticity of the experimental conclusions, but also verify the role of fCNTs/Au–Ag NPs/fCNTs as a facilitator of charge transport at the electrode surface through non-covalent host (GCE)-guest (DHBIs) interactions. 4. Conclusion Results of our experiments demonstrate that GCE modied with fCNTs/Au–Ag NPs/fCNTs is an efficient platform for the concurrent © 2021 The Author(s). Published by the Royal Society of Chemistry ELUMO 0.101 0.092 0.111 0.123 Eg IE EA 0.053 0.035 0.042 0.048 0.154 0.127 0.153 0.171 0.101 0.092 0.111 0.123 DE 5.6 4.1 2.3 ultrasensitive detection of dihydroxybenzene isomers (DHBIs) i.e., hydroquinone (HQ), resorcinol (RC) and catechol (CC) isomers. Compared to bare GCE the designed sensing platform shows well resolved signals with amplied peak currents and considerable lowering of over potentials. The improved performance is credited to the greater active surface area and conductivity of the modied electrode surface. The designed senor shows wide LCRs and femtomolar LOD values of DHBIs as compared to any reported sensor for the isomeric phenolic water toxins. The designed sensor also exhibits antifouling properties, stability and reproducibility. Moreover high percentage recoveries in a number of real water samples indicate practical applicability of the sensor for on-site simultaneous detection of the target isomers. DFT results suggest the existence of non-covalent interactions between the Au– RSC Adv., 2021, 11, 35783–35795 | 35793 View Article Online RSC Advances Ag NPs/fCNTs and DHBIs that result in improved electrocatalytic performance of the modied electrode surface. Conflicts of interest Open Access Article. Published on 05 November 2021. Downloaded on 11/6/2021 2:04:38 PM. This article is licensed under a Creative Commons Attribution 3.0 Unported Licence. There are no conicts to declare. Acknowledgements Dr Afzal Shah and Sher Bahadar Khan acknowledge the Deanship of Scientic Research (DSR) at King Abdulaziz University, Jeddah, Saudi Arabia, for supporting this project under grant No. (KEP-32-130-42). Dr Afzal Shah also acknowledges the support of Quaid-i-Azam University and Higher Education Commission of Pakistan. References 1 D. Cheng and X. Kan, Simultaneous determination of dihydroxybenzene isomers based on gold dendritic/pEDOT electrochemical sensor, J. Electroanal. Chem., 2020, 857, 113741–113747. 2 H. Ren, Y. Zhang, L. Liu, Y. Li, D. Wang, R. Zhang, W. Zhang, Y. Li and B. C. Ye, Synthesis of hollow Mo2C/carbon spheres, and their application to simultaneous electrochemical detection of hydroquinone, catechol, and resorcinol, Microchim. Acta, 2019, 186, 306–311. 3 L. Tang, Y. Zhou, G. Zeng, Z. Li, Y. Liu, Y. Zhang, G. Chen, G. Yang, X. Lei and M. Wu, A tyrosinase biosensor based on ordered mesoporous carbon–Au/L-lysine/Au nanoparticles for simultaneous determination of hydroquinone and catechol, RSC Analyst, 2013, 138, 3552– 3560. 4 T. C. Canevari, L. T. Arenas, R. Landers, R. Custodio and Y. Gushikem, Simultaneous electroanalytical determination of hydroquinone and catechol in the presence of resorcinol at an SiO2/C electrode spin-coated with a thin lm of Nb2O5, RSC Analyst, 2013, 138, 315–324. 5 C. Z. Zhao, J. Y. Liang, X. L. Gu and H. Liu, Simultaneous determination of dihydroxybenzene isomers utilizing a thiadiazole lm electrode, Chin. Chem. Lett., 2014, 25, 370–374. 6 N. Lavanya and C. Sekar, Highly sensitive electrochemical sensor for simultaneous determination of dihydroxybenzene isomers based on Co doped SnO2 nanoparticles, RSC Adv., 2016, 6, 68211–68219. 7 M. Velmurugan, N. Karikalan, S. M. Chen, Y. H. Cheng and C. Karuppiah, Electrochemical preparation of activated graphene oxide for the simultaneous determination of hydroquinone and catechol, J. Colloid Interface Sci., 2017, 500, 54–62. 8 P. Arul, E. Narayan amoorthi and S. A. John, Covalent organic framework lm as an effective electrocatalyst for the simultaneous determination of dihydroxybenzene isomers in water samples, Sens. Actuators, B, 2020, 313, 128033– 128039. 35794 | RSC Adv., 2021, 11, 35783–35795 Paper 9 K. Moulaee, M. H. Raza, N. Pinna, N. Donatoa and G. Neri, CNT/Al2O3 core–shell nanostructures for the electrochemical detection of dihydroxybenzene isomers, Phys. Chem. Chem. Phys., 2021, 23, 14064–14074. 10 X. Zhang, S. Duan, X. Xu, S. Xu and C. Zhou, Electrochemical behavior and simultaneous determination of dihydroxybenzene isomers at a functionalized SBA-15 mesoporous silica modied carbon paste electrode, Electrochim. Acta, 2011, 56, 1981–1987. 11 L. Wang, Y. Zhang, Y. Du, D. Lu, Y. Zhang and C. Wang, Simultaneous determination of catechol and hydroquinone based on poly (diallyldimethylammonium chloride) functionalized graphene-modied glassy carbon electrode, J. Solid State Electrochem., 2012, 16, 1323–1331. 12 J. Huang, X. Zhang, L. Zhou and T. You, Simultaneous electrochemical determination of dihydroxybenzene isomers using electrospun nitrogen-doped carbon nanober lm electrode, Sens. Actuators, B, 2016, 224, 568– 576. 13 H. Zhang, X. Bo and L. Guo, Electrochemical preparation of porous graphene and its electrochemical application in the simultaneous determination of hydroquinone, catechol, and resorcinol, Sens. Actuators, B, 2015, 220, 919–926. 14 M. Zhang, J. Ye, P. Fang, Z. Zhang, C. Wang and G. Wu, Facile electrochemical preparation of NaOH nanorods on glassy carbon electrode for ultrasensitive and simultaneous sensing of hydroquinone, catechol and resorcinol, Electrochim. Acta, 2019, 317, 618–627. 15 L. Huang, Y. Cao and D. Diao, Electrochemical activation of graphene sheets embedded carbon lms for high sensitivity simultaneous determination of hydroquinone, catechol and resorcinol, Sens. Actuators, B, 2020, 305, 127495. 16 V. Schroeder, S. Savagatrup, M. He, S. Lin and T. M. Swager, Carbon nanotube chemical sensors, Med. Chem. Rev., 2018, 119, 599–663. 17 E. Asadian, M. Ghalkhani and S. Shahrokhian, Electrochemical sensing based on carbon nanoparticles: A review, Sens. Actuators, B, 2019, 293, 183–209. 18 E. Flampouri, S. Imar, K. OConnell and B. Singh, Spheroid3D and monolayer-2D intestinal electrochemical biosensor for toxicity/viability testing: Applications in drug screening, food safety, and environmental pollutant analysis, ACS Sens., 2019, 4, 660–669. 19 X. Wang, M. Wu, H. Li, Q. Wang, P. He and Y. Fang, Simultaneous electrochemical determination of hydroquinone and catechol based on three-dimensional graphene/MWCNTs/BMIMPF6 nanocomposite modied electrode, Sens. Actuators, B, 2014, 192, 452–458. 20 H. S. Han, J. M. You, H. Seol, H. Jeong and S. Jeon, Electrochemical sensor for hydroquinone and catechol based on electrochemically reduced GO–terthiophene– CNT, Sens. Actuators, B, 2014, 194, 460–469. 21 T. Kokab, A. Munir, A. Shah, S. Kurbanoglu, M. A. Zia and S. A. Ozkan, The Effect of Nanomaterials on the Drug Analysis Performance of Nanosensors, in New Developments in Nanosensors for Pharmaceutical Analysis, Elsevier, 1st edn, 2019, vol. 1, pp. 79–118. © 2021 The Author(s). Published by the Royal Society of Chemistry View Article Online Open Access Article. Published on 05 November 2021. Downloaded on 11/6/2021 2:04:38 PM. This article is licensed under a Creative Commons Attribution 3.0 Unported Licence. Paper 22 J. M. George, A. Antony and B. Mathew, Metal oxide nanoparticles in electrochemical sensing and biosensing: a review, Microchim. Acta, 2018, 185, 358–366. 23 N. K. Bakirhan, A. Shah and S. A. Ozkan, Noble Metal Nanoparticles in Electrochemical Analysis of Drugs, in New Developments in Nanosensors for Pharmaceutical Analysis, Elsevier, 1st edn, 2019, pp. 171–195. 24 X. Gao, R. Gui, K. Q. Xu, H. Guo, H. Jin and Z. Wang, A bimetallic nanoparticle/graphene oxide/thionine composite-modied glassy carbon electrode used as a facile ratiometric electrochemical sensor for sensitive uric acid determination, J. Chem., 2018, 42, 14796–14804. 25 Y. Zhao, Y. Yang, L. Cui, F. Zheng and Q. Song, Electroactive Au@Ag nanoparticles driven electrochemical sensor for endogenous H2S detection, Biosens. Bioelectron., 2018, 117, 53–59. 26 S. Kurbanoglu and S. A. Ozkan, Electrochemical carbon based nanosensors: A promising tool in pharmaceutical and biomedical analysis, J. Pharm. Biomed. Anal., 2018, 147, 439–457. 27 S. Aab, S. Kurbanoglu, G. Ozcelikay, N. K. Bakirhan, A. Shah and S. A. Ozkan, Carbon quantum dots cocatalyzed with multiwalled carbon nanotubes and silver nanoparticles modied nanosensor for the electrochemical assay of anti-HIV drug Rilpivirine, Sens. Actuators, B, 2019, 285, 571–583. 28 R. Latif ur, A. Shah, S. B. Khan, A. M. Asiri, H. Hussain, C. Han, R. Qureshi, M. N. Ashiq, M. A. Zia, M. Ishaq and H. B. Kraatz, Synthesis, characterization, and application of Au–Ag alloy nanoparticles for the sensing of an environmental toxin, pyrene, J. Appl. Electrochem., 2015, 45, 463–472. 29 S. Wulandari, H. Widiyandari and A. Subagio, Synthesis and characterization carboxyl functionalized Multi-Walled Carbon Nanotubes (MWCNT-COOH) and NH2 functionalized Multi-Walled Carbon Nanotubes (MWCNTNH2), J Pharm. Health Serv. Res., 2018, 1025, 012005–012008. 30 J. Xu, Y. Yokota, R. A. Wong, Y. Kim and Y. Einaga, Unusual electrochemical properties of low-doped boron-doped diamond electrodes containing sp2 carbon, J. Am. Chem. Soc., 2020, 142, 2310–2316. 31 S. W. Lee, B. S. Kim, S. Chen, Y. Shao-Horn and P. T. Hammond, Layer-by-layer assembly of all carbon nanotube ultrathin lms for electrochemical applications, J. Am. Chem. Soc., 2009, 131, 671–679. 32 S. Esmaielzadeh and G. Mashhadiagha, Formation constants and thermodynamic parameters of bivalent Co, Ni, Cu and Zn complexes with Schiff base ligand: experimental and DFT calculations, Bull. Chem. Soc. Ethiop., 2017, 31, 159–170. 33 M. Sadaqat, L. Nisar, N. U. A. Babar, F. Hussain, M. N. Ashiq, A. Shah, M. F. Ehsan, M. Najam-Ul-Haq and K. S. Joya, Zinctelluride nanospheres as an efficient water oxidation © 2021 The Author(s). Published by the Royal Society of Chemistry RSC Advances 34 35 36 37 38 39 40 41 42 43 electrocatalyst displaying a low overpotential for oxygen evolution, J. Mater. Chem. A, 2019, 7, 26410–26420. J. M. Gurrentz and M. J. Rose, Non-catalytic benets of Ni(II) binding to an Si(111)-PNP construct for photoelectrochemical hydrogen evolution reaction: metal ion induced at band potential modulation, J. Am. Chem. Soc., 2020, 142, 5657–5667. S. Yang, M. Yang, X. Yao, H. Fa, Y. Wang and C. Hou, A zeolitic imidazolate framework/carbon nanober nanocomposite based electrochemical sensor for simultaneous detection of co-existing dihydroxybenzene isomers, Sens. Actuators, B, 2020, 320, 128294–128300. Y. Song, F. Duan, S. Zhang, J. Y. Tian, Z. Zhang, Z. W. Wang, C. S. Liu, W. M. Xu and M. Du, Iron oxide@mesoporous carbon architectures derived from an Fe(II)-based metal organic framework for highly sensitive oxytetracycline determination, J. Mater. Chem. A, 2017, 5, 19378–19389. T. S. Zeleke, M. C. Tsai, M. A. Weret, C. J. Huang, M. K. Birhanu, T. C. Liu, C. P. Huang, Y. L. Soo, Y. W. Yang and W. N. Su, Immobilized single molecular molybdenum disulde on carbonized polyacrylonitrile for hydrogen evolution reaction, ACS Nano, 2019, 1, 23434– 23441. H. Daneshinejad, M. A. Chamjangali, N. Goudarzi and A. H. Amin, Modication of glassy carbon electrode with poly(hydroxynaphthol blue)/multi-walled carbon nanotubes composite and construction a new voltammetric sensor for the simultaneous determination of hydroquinone, catechol, and resorcinol, Mater. Res. Express, 2018, 5, 035307–035313. K. Wang, C. Wu, F. Wang, N. Jing and G. Jiang, Co/Co3O4 nanoparticles coupled with hollow nanoporous carbon polyhedrons for the enhanced electrochemical sensing of acetaminophen, ACS Sustain Chem. Eng., 2019, 7, 18582– 18592. K. Jedlińska, R. Porada, J. Lipińska and B. Baś, The bi-band silver microelectrode: Fabrication, characterization, and analytical study, Sens. Actuators, B, 2020, 302, 127152– 127160. N. Yang, X. Chen, T. Ren, P. Zhang and D. Yang, Carbon nanotube based biosensors, Sens. Actuators, B, 2015, 207, 690–715. J. Huang, A. L. Ng, Y. Piao, C. F. Chen, A. A. Green, C. F. Sun, M. C. Hersam, C. S. Lee and Y. Wang, Covalently functionalized double-walled carbon nanotubes combine high sensitivity and selectivity in the electrical detection of small molecules, J. Am. Chem. Soc., 2013, 135, 2306–2312. N. Dhananjayan, M. Palanisamy, W. Jeyaraj and G. Karuppasamy, Stable and robust nanobiocomposite preparation using aminated guar gum (mimic activity of graphene) with electron beam irradiated polypyrrole and Ce-Ni bimetal: Effective role in simultaneous sensing of environmental pollutants and pseudocapacitor applications, Electrochim. Acta, 2017, 246, 484–496. RSC Adv., 2021, 11, 35783–35795 | 35795