Abstracts

ARTICLE

Electroanalytical determination of the herbicide picloram in natural waters by square wave voltammetry

Marli R. C. Massaroppi; Sergio A. S. Machado; Luis A. Avaca

Instituto de Química de São Carlos, Universidade de São Paulo, CP 780, 13560-970 São Carlos, SP, Brazil

^{Address to correspondence} Address to correspondence Sergio A. S. Machado E-mail: sasmach@iqsc.sc.usp.br

RESUMO

O uso da voltametria de onda quadrada para a determinação eletroanalítica do picloram em meio aquoso é discutido neste trabalho. Encontrou-se que a reação ocorre por um mecanismo irreversível, envolvendo a transferência de quatro elétrons, com o reagente adsorvido na superfície do eletrodo. Uma aplicação prática foi levada a efeito, com amostras de águas contaminadas artificialmente com o herbicida. Estas amostras consistiam de água pura e de três diferentes amostras, coletadas em três diferentes riachos da região, dois dos quais eram altamente poluídos com efluentes domésticos e industriais. Os limites de detecção calculados variaram entre 11 (para a água pura) e 39 ppb para a amostra mais contaminada. Estes valores são suficientemente baixos para indicar a metodologia em aplicações de análise de traços.

ABSTRACT

This paper describes the use of square wave voltammetry for the electroanalytical determination of picloram in aqueous media. The reaction was found to occur via an irreversible mechanism involving the transference of four electrons, with the reagent adsorbed in the electrode surface. The practical application was carried out with spiked water samples originated from purified water and from three different local creeks, two of which are highly polluted with industrial and domestic effluents. The calculated detection limits ranged from 11 (for pure and unpolluted waters) to 39 ppb for the most contaminated sample. These low values indicate that such methodology can be conveniently applied in trace analysis.

Keywords: picloram, square wave voltammetry, pesticides, electroanalysis

Introduction

In modern agricultural practices, the most common method for protection against plagues has been the use of the so-called pesticides. Such chemical substances promote indirect benefits by minimising crops lost due to the attack of prejudicial organisms. However, a major problem arising mainly in developing countries has been the use of such products in prophylactic treatments, without much care on the question of if or when such applications are justified. The consequences of these attitudes are the widespread contamination of soils and waters with toxic substances as well as the induction for the appearance of more resistant plagues, which in turn demand greater doses of pesticides.

After application, the pesticide molecules may undergo different pathways in the environment, depending on the types of interaction with the soil components.^1,2 In soils rich in organic matter or/and clay, pesticide molecules may become immobilised by strong absorption^3,4 that facilitates their degradation by sunlight, microorganisms or chemical reactions. In these cases, the degradation products may be toxic or not. In mineral soils, where the interaction is commonly very weak, they may be leached by rain or irrigation waters reaching rivers, dams or under-ground waters. Under such circumstances, the risk of contamination of potable sources is quite serious.

Picloram (4-amino-3,5,6-trichloro picolinic acid) is a selective herbicide, commonly used in association with other herbicides in the annual control of some grasses and broadleaf weeds in corn, sorghum, sugar cane, pineapple, pinus and other cultures.⁵ The maximum level of picloram contamination in drinking water is 0.5 mg L^-1, as proposed by the EPA (Environmental Protection Agency, USA). Human exposure to higher levels of the pesticide can cause damages to the central nervous system, loss of weight, diarrhoea and weakness. Moreover, picloram is the most persistent herbicides of the chlorobenzoic acid family and ca. 10-30% of the original amount of herbicide was detected one year after its application in some cultures in Canada.⁶

Due to the continuous increase in the application of such pesticide, the necessity of water analysis is always growing. The traditional techniques used for such purpose are liquid chromatography and gas chromatography with electron capture detection, which is one of the most adequate due to the very low value obtainable for the detection limit. However, the extensive sample manipulation, through extractions and purification procedures, makes these techniques very expensive and demanding well-equipped laboratory installations and a well-trained analysis team. On the other hand, electroanalytical procedures can overcome many of such difficulties by analysing environmental samples without extractions and purification steps, thus shortening and undervaluing the pesticide analysis.

Amongst several voltammetric procedures available for this type of analysis, square wave voltammetry (SWV)^7-9 appears as the most interesting one. The main advantage of SWV is the fast scan rate that can be applied, often of the order of 1 V s^-1 instead of the 1-10 mV s^-1 used in other pulse techniques. As the peak current is the sum of forward and backward contributions and is proportional to the scan rate, the sensitivity of SWV is usually larger than for the other techniques, particularly for reversible or quasi-reversible systems.⁸ Moreover, the mathematical interpretation of SWV data provides several important parameters that are useful for the discussion of the reduction mechanism at the electrode surface of such complex molecules. This is an important and almost unique feature of this electrochemical technique.

The aim of this work is to study the electrochemical behaviour of the herbicide picloram in aqueous solution by square wave voltammetry and to establish the initial steps in the development of an electroanalytical procedure to analyse picloram in spiked waters, either pure from the laboratory or polluted from local urban creeks.

Experimental

Reagents

Picloram (99% pure) was purchased from Dow Chemical Corporation. Stock solutions were prepared using a mixture of ethanol and water (5% v/v) to increase the solubility of the organic compound and kept at ca. 5 ^oC protected from light. All other chemical reagents were Merck PA and used without any further purification. Water was purified in a Milli-Q system from Millipore Inc.

Apparatus

SWV experiments were performed with a potentiostat/galvanostat model 273 and a polarographic analyser model 384 both from EG&G PARC. The electrochemical equipment was connected to a IBM PC type Pentium 100 MHz microcomputer and controlled by the electrochemical software M270 from EG&G PARC. The electrolyte pH was adjusted prior to each electrochemical measurement with a model 682 Metrohm Titroprocessor. All analyses were conducted at room temperature (25 ± 2 ^oC).

Electrolytic cell and electrodes

A 10 mL, three-electrode Pyrex^® glass, cell with a saturated Ag/AgCl as the reference and a platinum wire as the auxiliary electrode were employed. The working electrode was the model 303 Static Mercury Drop Electrode, from EG&G PARC, operating with medium drop size (0.0218 cm² electrode area).

Experimental methodologies

Samples of natural waters were collected from three different creeks in the region of São Carlos city, Brazil. The collecting points presented different characteristics with regard to water pollution. The first one, at the Santa Maria do Viterbo creek, was located outside the city and is relatively free from urban or industrial pollution. The second point was at the Gregorio creek that is mainly polluted with domestic sewerage without industrial rejects while the third point was at the Monjolinho creek after crossing the city thus collecting a heavy load of industrial and domestic discharges. All samples were collected in amber glass flasks with 1 L capacity that were initially washed with water and sulfonitric solution (50% v/v HNO₃ and H₂SO₄), cleansed thoroughly with Milli-Q water and dried in an oven at 120 ^oC. The collected water samples had their pH adjusted to 1 by the addition of the required amount of a 0.1 mol L^-1 H₂SO₄ solution and were kept in a refrigerator for a maximum of 5 days prior to use.

The analytical curves were obtained using the standard addition method from a 10^-3 mol L^-1 stock solution of picloram in a mixture of 5% v/v of ethanol in water. Even for the highest picloram concentration, the final content of ethanol in the cell was very low.

Results and discussion

Optimisation of voltammetric parameters

Figure 1 presents preliminary cyclic voltammetric experiments carried out on the mercury drop electrode in a 1.05 x 10^-5 mol L^-1 picloram solution in H₂SO₄ (pH 1) electrolyte at several sweep rates showed two reduction peaks. As already proposed for the reduction of organochloride pesticides,¹⁰ the first peak (at -0.90 V) is associated with the totally protonated molecule, while the other one, at -0.95 V is related with unprotonated specie. These peaks were better defined when the sweep rate increased and there was no evidence of an anodic process in the reverse sweep thus suggesting an irreversible electrode process. The linear dependence of the peak current for the first process with the sweep rate shown in the insert of that Figure points to a reduction mechanism with the reagent adsorbed on the electrode surface. The slope value of the log I_pvs. log v plot (0.9) is close to unity as expected for adsorption control.¹¹

To evaluate the electrochemical response of picloram, experiments were performed using several voltammetric techniques such as DC polarography, cyclic voltammetry, differential pulse polarography and square wave voltammetry. The different responses recorded for the same solution (i.e., 4.1 x 10^-6 mol L^-1 picloram in 0.5 mol L^-1 H₂SO₄) are shown in Figure 2 together with the corresponding experimental parameters used in each case. It is clear that square wave voltammetry provides the highest peak current and the best sensitivity among the four techniques. Moreover, the use of that technique allows experiments to be carried out at high sweep rates thus shortening the time spent with the analysis. These characteristics of SWV are quite convenient for analytical purposes.

The potential program imposed to the working electrode in SWV experiments consists of a symmetrical square wave (amplitude a) superimposed to the basic staircase modulation (amplitude DE), being the complete period of the SWV equal to that of the staircase (t). The pulse height, or t/2, is called t_p and the frequency, 1/t, is designed by f. This potential program combination creates a series of potential pulses in the forward and backward direction that are synchronised with the current sampling in the last portion of each half-period of the square wave, with negligible contribution from the capacitive current. The resulting current values are, therefore, the combination of the direct (forward) and reverse (backward) contribution.

For an adsorption-controlled process, the electrode reaction can be represented by the following scheme:

that has been already analysed in terms of square wave voltammetric boundary conditions by several authors, as cited in the next sections. It should be observed that the totally irreversible equation 2 has a standard potential E^o that is experimentally inaccessible.

To account for the mathematical interpretation of the experimental data resulting from the reactions above, Lovric et al.¹² developed three empirical expressions for peak height, position and width, as follows:

In these equations, DI_p is the peak current, A the electrode area, n the number of electrons transferred, a the SW amplitude, f the SW frequency, DE the SW potential step, G the surface concentration of the adsorbed reagent, k_o the standard rate constant, t_p the pulse width and W_1/2 the half-peak width.

As shown in Figure 2 (C), the SWV response for picloram presents two very well defined peaks at approximately –0.85 V (peak I) and at –1.0 V (peak II). Peak (I) is more adequate for analytical purposes due to the considerable larger current value. A similar response, for a 1.05 x 10^-5 mol L^-1 picloram solution, is decomposed in the direct, reverse and total components in Figure 3. The irreversibility of the reduction reaction is, once more, evidenced by the lack of response in the reverse component.

To optimise the experimental set-up used for picloram determination, the dependence of the SWV responses with several parameters was analysed. Figure 4 shows the effect of the square wave amplitude (a) on the voltammograms obtained for a 1.05 x 10^-5 mol L^-1 picloram solution with f = 100 Hz and DE = 0.002 V. The peak current increases linearly with amplitude up to approximately 0.05 V and then stabilise, in accordance with the theory.¹¹ This is shown in Figure 5 where the slope of the linear portion is 186.3 ± 0.007 mA V^-1, with r = 0.996 and N = 9. Therefore, increasing the amplitude to values higher than 0.05 V fails to further improve the sensitivity of the technique. However, that variation of the amplitude also results in a peak potential shift towards more positive values and this may be useful for solutions with more than one component. As this highly irreversible electrode process does not have any appreciable contribution from backward currents, the increase in square wave amplitude must result in a linear variation of peak potential, as shown in Figure 6. However, this latest plot has a slope of 1.02 that is quite different from the 0.7 value predicted by equation 4. Meanwhile, other authors¹³ claim that this should have a unitary value, as found here.

Another experimental parameter that exerts an important influence in the square wave response is the frequency. In this work, frequency values have been changed from 10 to 1000 Hz. The results are illustrated in Figure 7 in the form of two sets of voltammograms, the first one with frequency values varying from 10 to 100 Hz and the other from 100 to 1000 Hz. The peak currents showed a linear variation within the whole frequency range, with R = 0.997, N = 77 and d DI_p / df = 4.38 x 10^-8 A s. This linear relationship is typical for an electrochemical process controlled by the adsorption of reagent or product, as it is the case for picloram reduction. The relationship between peak potential and the logarithm of frequency provides a manner to calculate the number of electrons transferred in the reduction reaction. Figure 8 shows the straight line with a slope of 1.83 obtained within the experimentally useful frequency range. Considering a = 0.5, the number of electrons transferred in the electrochemical reduction process should be equal to 4.

Analytical application

The application of the previously optimised methodology for the analysis of picloram in pure and natural waters without any pre-purification step will be now presented. Samples were collected directly from the creeks described in the Experimental section, had their pH adjusted to 1 by the addition of H₂SO₄ and used as the electrolyte without any further physicochemical characterisation

SWV responses were obtained for the four types of electrolyte, i.e., purified water, water from Santa Maria do Viterbo creek, from Gregorio creek and from Monjolinho creek. The results are displayed in Figure 9 for the different electrolytes spiked with several concentrations of picloram, in the ppb range. From the pure water responses it is evident that, as the level of organic contamination increases, the baseline shows higher currents. This effect diminishes the peaks resolution particularly at the lowest picloram concentrations.

A comparative set of analytical curves, for the four types of waters, is presented in Figure 10. In all cases, data is reported as the average of 5 voltammograms per concentration, in the range of 1.6 x 10^-7 to 2.1 x 10^-6 mol L^-1 (40 and 500 ppb).. The corresponding detection limits (DL) were calculated considering the average of ten voltammograms for the blank solutions and the equation:

where S_B holds for the standard deviation for the blank solution, at a potential equal to the peak potential for picloram reduction, and B is the angular coefficient of the straight lines, the sensitivity value. The calculated DL values are collected in Table 1 together with B and the other parameters of the linear relationships. The DL values obtained with the present methodology are close to those previously published for Picloram, i.e., 14 mg L^-1 (as calculated by differential pulse polarography)¹⁴ and also to some results obtained using high performance liquid chromatography (HPLC), i.e., 8 ppb.¹⁵

A comparison of the several values obtained for the detection limit in the four different waters indicates that the impurities contained by the Santa Maria do Viterbo creek (which is not polluted) do not interfere with the final analytical result. Apparently, the lower slope value compared to pure water is compensated by a smaller variation for the blank responses. This is an important finding since no clean-up step was included in the present study, which should be necessary for a chromatographic determination. The lack of necessity of sample manipulation yields an overall fast and cheap analytical methodology. However, industrial and/or domestic pollutants present in the other two creeks clearly diminish the sensitivity of the method, as revealed by the increase in the detection limit values. Nevertheless, all the detection limit values obtained in this work using the square wave voltammetry are sufficiently small to indicate this technique to be used in trace analysis.

Conclusions

The electrochemical reduction of picloram in aqueous media was successfully studied by square wave voltammetry. Several voltammetric parameters were optimised and their influence in the peak currents or peak potentials were adequately described by theoretical models involving an irreversible electrode process, with the reagent strongly adsorbed on the surface and the transference of 4 electrons per picloram molecule.

In the analytical application, SWV showed to be a very fast and sensitive technique that allows reaching detection limits in the range of trace analysis, i. e., between 11 and 39 ppb, even in highly polluted natural water samples collected from urban creeks. The natural components of creek waters do not seem to interfere with the electroanalytical determination since the detection limits of pure and non-polluted waters are practically the same. The lowering of sensitivity due to the organic components in contaminated waters is a characteristic of mercury, the working electrode on which picloram molecules undergo strong adsorption.

Contrary to several other analytical techniques commonly used for the determination of pesticides, no purification or extraction steps are necessary before obtaining the analytical curve by SWV. This is one major advantages of this electroanalytical technique since it allows an economy of time and money in the environmental monitoring of pesticide contamination.

Acknowledgements

The authors wish to thank the Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) and the Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP, proc. No. 00/03540-6), Brazil, for financial support.

Received: October 10, 2001

Published on the web: January 17, 2003

FAPESP helped in meeting the publication costs of this article.

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