Voltamperometric measurements have been carried out with a Potensiostat/Galvanostat Autolab (PGSTAT 101) purchased from Metrohm. Integrated software (Nova 1.13) was used for analysis control and data processing. The electrochemical polypropylene (FLWCL-P) circulation cell and the screen-printed-electrodes (SPE-110GPH) were commercially obtained from DropSens (Figure 1). The screen-printed electrode integrates on the same ceramic support the carbon working electrode modified by a graphene layer, the silver reference electrode and the carbon auxiliary electrode. A HPLC pump (Waters) was used to deliver a stable solution flow that can be handled by the circulation cell. A homemade support was used to maintain a mini-cell serving as a tank for the electrochemical solution in circulation (Figure 2).

Bisphenol A (BPA), 4-nonylphenol (4-NP), 4-octylphenol (4-OP) and 4-tert-octylphenol (4-tert-OP) were purchased from Sigma-Aldrich (high purity grade). Working alkylphenol solutions were prepared in demineralized water. Phosphate-buffered solution was used as the supporting electrolyte. Demineralized water was obtained in our laboratory by an appropriate production system (Millipore). Other solvents and chemicals used were of analytical reagent grade. All the prepared solutions were stored in the dark at 4°C when they were not in use. All the measurements were carried out at lab temperature.

The electrochemical behavior of the alkylphenols at the SPE-110GPH electrode was investigated by cyclic voltammetry. At a scan rate of 0.05 V/s, an anodic peak localized at 0.3 V was observed on the voltammogram (Figure 3) for 4-nonylphenol. However, this peak can move slightly to higher potential toward 0.4 V, depending on the alkylphenol and its concentration in solution, as well as the flow rate. In all cases, no reduction peak was observed in the reverse scan. This shows that oxidation of alkylphenols at the graphene modified screen-printed electrode is a totally irreversible process. On the other hand, the effect of changing the scan rate potential was studied from 0.01 V/s to 0.35 V/s in order to determine the behavior of the alkylphenols on the graphene modified screen-printed electrode. A slope of 1 was observed for all alkylphenols (log I_p versus log ʋ) indicating that the alkylphenol oxidation process on the sensor surface is kinetically limited by adsorption and not by diffusion.

In order to study the effect of modification of the graphene layer at the working electrode sensor, a comparison between the response of the unmodified working carbon electrode and the graphene modified working carbon electrode was made in the same solution and under the same experimental conditions (Figure 3). Results show that the graphene modification layer improves the capacitive current and also the intensity of the oxidation peak current of the alkylphenol. The use of the graphene-modified electrode enhances by a factor of 6× the oxidation peak current, compared to the unmodified carbon working electrode, which results an enhancement of the electrode sensitivity. For this reason, we chose the graphene-modified screen-printed electrodes for alkylphenol detection.

In order to improve the sensitivity of the proposed sensor, some experimental parameters were investigated and optimized. It was found that alkylphenol oxidation on the graphene-modified electrode requires reactivation of the working electrode surface before every new measurement. This reactivation is needed to eliminate the oxidation products formed on the working electrode surface. The second step involves accumulation of the alkylphenols in circulation on the electrode surface, since the oxidation process is limited by adsorption. The behavior of this sensor in a circulation cell was optimized to maintain the dual steps consecutively. An optimized time of four minutes was fixed between two consecutive measurements to obtain repeatable current peak intensity.

A series of alkylphenol samples with different concentrations was analyzed in the presence of phosphate buffer as the supporting electrolyte by the graphene-modified screen-printed electrode, to investigate the analytical capabilities of the sensor. The determination of the detection limit was made separately for each alkylphenol. Bisphenol A had the lowest detection limit among the alkylphenols (60 nM). For the other alkylphenols, the calculated detection limit was 0.1 µM for 4-nonylphenol (4-NP), 0.5 µM for 4-octylphenol (4-OP) and 0.1 µM for 4-tert-octylphenol (4-tert-OP).

The cyclic voltammograms obtained with the SPE electrodes as a function of the solution concentration of the alkylphenols are presented in figure 4. The calibration curves were obtained from the oxidation peak current measurements. They showed a linear response for bisphenol A, 4-octylphenol and 4-tert-octylphenol (Table 1) over a sufficiently wide concentration range (2 decades) to envisage the use of this sensor to control process efficiency. However, 4-nonylphenol showed a polynomial response with a good correlation coefficient.

Repeatability of the SPE response was investigated and tested in the same laboratory, by the same analyst, the same equipment (HPLC pump, flow cell and potentiostat) and with the same electrode but at different times. It was calculated as the relative standard deviation from ten replicates (n = 10). The repeatability of bisphenol A, 4-nonylphenol, 4-octylphenol and 4-tert-octylphenol, were respectively: 4.52%, 4.01%, 4.04% and 4.84%. In the other hand, the accuracy of the developed method was studied at a given concentration level by comparing the expected value with the average of the results obtained by extrapolation from the calibration curve of each alkylphenol for ten replicates. The calculated accuracy was between 90% and 95% for the different alkylphenols, indicating that the developed method for alkylphenol detection on the graphene-modified screen-printed electrode has a good repeatability and very high accuracy.