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Effect of scavengers on the photocatalytic digestion of organic matter in water samples assisted by TiO2 in suspension for the voltammetric determination of heavy metals

Abstracts

The influence of electron and hole scavengers in the photocatalytic digestion of organic matter in the presence of suspended particles of TiO2 was investigated. The process, aiming at the electrochemical determination of traces of heavy metals in water samples, was followed through the recovery of the voltammetric wave of Cd(II) in the presence of EDTA, chosen as model ligand that mimics the complexing effect of natural dissolved organic matter. The accelerating power of O2, acting as electron scavenger, was confirmed. In the absence of O2, a similar function is played by nitrate ions but not, as it seems, by the analyte, Cd(II). On the other hand, CH3OH exhibits an antagonist effect as hole scavenger. This observation may explain why the acetate (from the pH buffer), used to control the medium acidity, leads to a certain reduction in the photocatalytic yield.

photodigestion; TiO2; scavengers; voltammetry


A influência de scavengers de elétrons e de lacunas positivas na digestão fotocatalítica de matéria orgânica na presença de partículas de TiO2 em suspensão, foi investigada. O processo, que visa a determinação eletroquímica de traços de metais pesados em amostras de água, foi acompanhado mediante observação da recuperação da onda voltamétrica de Cd(II) em presença de EDTA, escolhido como ligante-modelo na simulação do efeito complexante da matéria orgânica natural. Confirmou-se o poder acelerador de O2, que atua como removedor de elétrons. Na ausência de O2, função análoga é exercida pelo íon nitrato, mas não, ao menos aparentemente, pelo analito Cd(II). Já a adição de CH3OH apresenta efeito antagônico de scavenger de lacunas positivas, o que pode explicar porque a operação na presença de acetato (usado como tampão de pH), ao mesmo tempo em que proporciona um eficaz controle da acidez do meio, provoca uma certa redução do rendimento da fotodegradação.


Article

Effect of Scavengers on the Photocatalytic Digestion of Organic Matter in Water Samples Assisted by TiO2 in Suspension for the Voltammetric Determination of Heavy Metals

Andrea Cavicchioli and Ivano G. R. Gutz* * e-mail: gutz@iq.usp.br

Instituto de Química, Universidade de São Paulo, Avenida Prof. Lineu Prestes 748, Butantã, 05508-900 São Paulo - SP, Brazil

A influência de scavengers de elétrons e de lacunas positivas na digestão fotocatalítica de matéria orgânica na presença de partículas de TiO2 em suspensão, foi investigada. O processo, que visa a determinação eletroquímica de traços de metais pesados em amostras de água, foi acompanhado mediante observação da recuperação da onda voltamétrica de Cd(II) em presença de EDTA, escolhido como ligante-modelo na simulação do efeito complexante da matéria orgânica natural. Confirmou-se o poder acelerador de O2, que atua como removedor de elétrons. Na ausência de O2, função análoga é exercida pelo íon nitrato, mas não, ao menos aparentemente, pelo analito Cd(II). Já a adição de CH3OH apresenta efeito antagônico de scavenger de lacunas positivas, o que pode explicar porque a operação na presença de acetato (usado como tampão de pH), ao mesmo tempo em que proporciona um eficaz controle da acidez do meio, provoca uma certa redução do rendimento da fotodegradação.

The influence of electron and hole scavengers in the photocatalytic digestion of organic matter in the presence of suspended particles of TiO2 was investigated. The process, aiming at the electrochemical determination of traces of heavy metals in water samples, was followed through the recovery of the voltammetric wave of Cd(II) in the presence of EDTA, chosen as model ligand that mimics the complexing effect of natural dissolved organic matter. The accelerating power of O2, acting as electron scavenger, was confirmed. In the absence of O2, a similar function is played by nitrate ions but not, as it seems, by the analyte, Cd(II). On the other hand, CH3OH exhibits an antagonist effect as hole scavenger. This observation may explain why the acetate (from the pH buffer), used to control the medium acidity, leads to a certain reduction in the photocatalytic yield.

Keywords: photodigestion, TiO2,scavengers, voltammetry

Introduction

In recent years, intense investigation has been undertaken on the TiO2-assisted photochemical mineralisation of organic substances by UV radiation, either with the semiconductor catalyst in suspension or immobilized on a solid support.1-26 The method was originally contemplated as a possibility to employ solar radiation as an energy source in water decontamination processes in connection with the treatment of industrial effluents and with water potabilisation.5,11,18,21 At a certain stage, however, studies and trials have markedly shifted towards the use of artificial UV source, mainly mercury vapour lamps, because of the scarce efficacy obtained with the solar radiation, the practical inconvenient of having to rely on the unpredictable availability of a natural light source and, not least, the poor overlapping of the solar spectrum with the TiO2 absorption range.7 Nonetheless, to date, such photocatalytic degradation has been successfully tested on a wide variety of organic substrates,7,16 both at laboratory and industrial ¾ or at least semi-industrial ¾ scale.15,21

This decomposition method has also set foot in the area of analytical chemistry. Initially, in the post-treatment of toxic reagents and products used in or generated by analytical procedures,22 looking at developing clean analytical routines, but still as an effluent treatment process, though at a small-scale. Then, in an attempt to upgrade the conventional UV photolysis in TOC determination devices.24

More notably, the authors of this article have recently proposed and evaluated the use of TiO2 suspensions in the photocatalytic pre-treatment of water samples aiming at the determination of heavy metals by voltammetric detection on mercury drop electrodes (MDE).26 It is well known that the presence of dissolved organic matter, present in natural waters, e.g. as humic substances, impairs the determination of total metal due to formation of stable and inert adducts between organic species and metal ions.27-28 For this reason, to access the total metal concentration, sample digestion is generally required and the UV photodegradation seems to represent a very suitable option when the organic load is not to high.29 This technique is, as a rule, carried out under temperature and pressure conditions closer to ambient, hence it is more easily manageable than the irradiation in microwave ovens. Therefore, the implementation of in-line (e.g. FIA) and in-situ procedures with UV digestion30 is favoured and there is also strictly no need for the addition of concentrated acids and reagents, potential sources of sample contamination. The experiments hitherto conducted with model samples containing Cd(II) (down to concentrations of 30 ppb) and dissodium ethylenediaminotetracetate (at concentrations of 10 to 500 fold in excess the Cd(II) content) have proven the efficacy of the photocatalytic destruction of the ligand and the complete recovery of the voltammetric metal signal, without prior filtration of the TiO2 suspension.

Beside displaying the already mentioned benefits of the conventional UV digestion, the photocatalytic variant yields to the enhancement of the decomposition reaction speed and to widening the effective radiation range towards less short wavelengths, what enables the use of PTFE tubing in the irradiation chamber (instead of the customary quartz ones, more expensive and unpractical) and a likely wider range of light sources.26

Nevertheless, in order to extend the results obtained with a somewhat well-behaved model solution to real samples, it is of primary importance to assess the influence of other species present in the sample in the photocatalytic mechanism. This is centred on the formation of an electron-hole pair on the TiO2 (anatase) surface upon the incidence of a photon with energy equal to or higher than the gap between the valence and the conduction band within the semiconductor crystal (3.23 eV):1-8

An electron is promoted to the conduction band (CB) while a positive hole is formed in the valence band (VB). In order for this process to have a net chemical effect, the recombination of the electron-hole pair has to be precluded so that the energy stored in chemical form is not dissipated as heat.7,8 The natural fate for h+VB and e-CB is the extraction of the electron to an external electric circuit,21,25 as it happens solar cells based on this principle, or the removal of either of them by means of redox reactions involving species present at the semiconductor surface, i.e. in the solid-liquid interface in the case of aqueous suspensions of TiO2.7

As far as the degradation of organic substances is concerned, the process is triggered by the h+VB, either by direct oxidation of the organic substrate or, more likely, via attack of OH• radicals formed, for instance, through the following route:6-8

Nonetheless, it is clear that the rate of the oxidative half reaction involving h+VB is closely related to the effective removal of the partner species, i.e. e-CB, by suitable electron scavengers, that must be present in the solution and available at the semiconductor interface.6 On the other hand, in processes aiming at the oxidative destruction of a target organic substrate, any hole scavengers present in the same environment are potential competitors for the consumption of h+VB.7,8

As far as electron scavenging is concerned, the most common electron scavenger, in aerated aqueous solution, is O2 and its role has been emphasised,1,7 including in the formation of "so-called selective oxygen species, which take part in the process of oxo functionalization of hydrocarbons".31

Upon reacting with photogenerated electrons on the surface of TiO2, O2 molecules form extremely reacting species such as the superoxide radical O2¾• and the singlet oxygen 1O2, which, in turn, trigger radical chain reactions, involving the generation of strong oxidants like H2O2 and O3.29

A number of potential inorganic electron receptors have been pointed out in literature: Cl-, SO42-, NO3-, HCO3- and PO43-,7 peroxides like S2O82-, IO4- and ClO3-,32 C(NO2)4.31 However, what perhaps has not yet been pointed out with clarity is the importance of O2 in the concomitant presence of other electron scavengers.

Metal ions are also involved in the photocatalytic mechanism and their role in photodegradation processes was widely reviewed in a recent paper by Litter.8 In most cases, they tend to enhance the destruction of organic substances, either through heterogeneous or homogeneous (mainly photo-Fenton type reactions) pathways,9 but only when present at low quantities and in the absence of dissolved O2. Among them, the behaviour of Fe, Cu and Ag ions has been thoroughly studied in connection with operating conditions such as pH, counter-ion type, solution composition and O2 content. The same source lists a number of common effective hole scavengers. The more commonly used are: methanol and ethanol,14,20 2-propanol,20 but also acetic acid,14,12 salicylic acid and EDTA.14

The goal of the work accounted in the present article was to show the influence, in the photocatalytic digestion, of species possibly present in solution and capable to trap and consume electrons or positive holes and, thus, to interfere favourably or unfavourably in the oxidation mechanism of organic substrates. Such an investigation, in the first place, intended to incorporate into the previous model system, elements able to turn it a more realistic system, with the possibility of a more reliable prediction of the behaviour of real samples submitted to the analytical treatment. Secondly, it aimed to explore the possibility of using effective electron scavengers in order to optimise the mineralisation process. This study was conducted with O2 and NO3- (at different concentrations) as representative electron scavengers. Some experiments were also carried out with different concentrations of Cd(II), used as target analyte, in order to bring to light any possible effect of this species as an electron scavenger. Methanol was chosen as a hole scavenger. The likely effect of the acetate buffer as a hole scavenger was also checked out in a run carried out in unbuffered medium. In this case the pH was constantly monitored and adjusted by H+ addition (more details in the Results and Discussions section).

Experimental

The photocatalytic process was tested in the absence and in the presence of (different amount of) electron or hole scavengers, on a model system26,34 comprising 1x10-4 mol L-1 Cd(II) (unless otherwise stated) and 1x10-3 mol L-1 sodium ethylenediaminetetraacetate (NaEDTA, present as H2Y2- at pH near 4, hereafter designated as EDTA for brevity), dissolved (unless otherwise stated) in an AcNa/AcH buffer pH 4.0.

The photodigestion of EDTA was followed, at regular interval, through the recovery of the suppressed Cd(II) signal, upon sample exposure to the radiation of a medium pressure mercury lamp. In all results presented, the metal signal was normalised, considering the signal value measured before EDTA addition as 100%.

Chemicals

All solutions were prepared using deionised water (18MW) purified by a Barnstead Nanopure system. All chemicals were of analytical grade: CdSO4, Na2EDTA, glacial acetic acid, sodium acetate, CH3OH. O2 was of standard medical type (Air Liquide). Vacuum-bidistilled mercury was used in polarography.

All samples were prepared daily by dilution of stock 1x10-2 mol L-1 Cd(II) and EDTA solutions. The supporting electrolyte was (unless otherwise stated) an acetate buffer of 1x10-2 mol L-1 NaAc brought to pH 4.0 ± 0.05 by glacial AcH.

Titanium dioxide suspensions (0.1% w/w) were obtained by homogenising, in a mortar, solid TiO2 (Degussa P25 without further purification) with 5 mL of the buffer solution, bringing to the final volume (15 or 20 mL) and sonicating for 30 min in an ultrasound bath. Other reagents (notably Cd(II) and EDTA) were added at this stage to desired portions of this suspension.

Photochemical digestor

The photochemical device used in the experiments of this work was designed and constructed in the authors' laboratory and it was described in detail elsewhere.26 It consists of a mercury vapour lamp (Osram 400 W) and a coiled PTFE reactor tube both placed within a tubular chimney that blocks the radiation and guides a cooling air flux from an electric fan situated at the lower end of the chimney. With the fan constantly turned on, the temperature settles around 30 °C.

The system can be operated in the batch mode, with sample re-circulation from and to an external reservoir, or in FIA mode with the introduction of a single sample plug with a volume equal to or smaller than the coiled tube that functions as irradiation cell.

All experiments were conducted with 15 and 20 mL of sample in the batch/re-circulation mode at a flow rate of 16 mL min-1. Since the internal volume of the tube reactor was 6.1 mL, under these operation conditions, during the treatment only about one third of the sample was being irradiated. This does not change the relative results that will be presented, however, under continuous irradiation conditions, all recovery times would be considerably shortened. For O2 trials, the pure gas was bubbled continuously in the external reservoir. Complete O2 saturation of the solution was assumed but not demonstrated, although in a preliminary test it was confirmed, voltammetrically, that the O2 content in the solution reached a plateau after only 10 s of purging by pure O2.

At regular time intervals, the solution was transferred to the electrochemical cell for Cd(II) determination and then returned to the photochemical system for further treatment. A diagram of the experimental set-up is illustrated in Figure 1.


Electrochemical apparatus

Cd(II) determination was carried out either by normal pulse polarography (NPP) or by differential normal pulse polarography (DNP) (as indicated in the figure captions). In the former case, a EG&G PAR 384B Polarographic analyser coupled with a PARC 303A Stand was used, whereas in the latter, a 646 VA Processor (Metrohm) coupled with a 647 VA Stand (Metrohm) was employed. The operating parameters were: working electrode = SMDE; drop size = "medium" (PAR 303) or "5" (VA-Stand); reference electrode = Ag/AgCl (3 mol L-1 KCl); auxiliary electrode = Pt; onset potential = -0.300 V; final potential = -0.900V; pulse amplitude = 50 mV; step time = 1 s; potential increment = 5 mV; purge time (N2) = 400 s.

Results and Discussion

The effect of O2 as an electron scavenger in the photocatalytic degradation of EDTA is shown in Figure 2. The rate of recovery of the Cd(II) signal was compared with two other runs conducted either bubbling N2¾ for complete O2 removal ¾ or exposing the solution to open air. The advantage of O2-enriched solutions over the other two modes is evident. In particular, the decomposition performed on the air-exposed solution, although more effective than the degradation in a O2-deprived sample and more convenient in practical and economical terms, it is not as profitable as when pure O2 is injected.


The scavenger role of NO3-, at concentrations of 1x10-3 and 1x10-2 mol L-1, is shown in Figures 3A and 3B, in the absence and in the presence of O2, respectively. In the latter case, assuming complete saturation of the solution and considering 760 mmHg atmospheric pressure and 30 °C sample temperature, the dissolved-O2 concentration is approximately 0.2 mmol L-1,35 that is, a value at least 5-fold lower than the NO3- concentration, but still twice larger than the EDTA concentration.



Without O2, the increase in the amounts of NO3- results in a patent enhancement of the degradation process, with a marked reduction of the time required to achieve almost complete recovery. The outcome is in agreement with some earlier literature data showing that the photocatalytic degradation of methyl orange in deareated conditions is faster in the presence of Ag and Cu nitrates, than with the sulphate salts of the same metals. Other researchers have also detected some photocatalytic formation of ammonium ions upon irradiating a Hg(NO3)2 solution at pH 8, likely to be ascribed to the nitrate photochemical reduction.8 On the other hand, in the presence of O2 there seems to be no influence from the nitrate.

It can be speculated that the role of electrons scavenger is entirely fulfilled, at least at this level of TiO2 content, by the molecular oxygen and that, therefore, the presence of nitrate becomes ineffectual. This means, apparently, that O2 is already exerting the whole scavenging activity required by the number of photogenerated electron-hole pairs produced on the semiconductor surface under the present experimental conditions, i.e. with mere O2 sparging the system is operating in optimised conditions of electron scavenging.

As a rule of thumb, it may be noted that the concentration of required electron scavengers is, firstly, related to concentration of species that can undergo oxidation through h+VB via the companion half reaction. Secondly, it is associated with the actual amount of electron-hole pairs generated by the incident photon flux, i.e. to factors such as the content of TiO2, the reactor geometry, light scattering and screening effects. Kinetic aspects, not dealt here, can be also relevant when comparing the efficiency of scavengers (O2, in all probability, has better chances to undergo faster reduction than NO3- on account of the direct uptake of electrons without the necessity of molecular rearrangements).

The effect of the presence Cd(II) is displayed in Figure 4A. This experiment was conducted with and without the metal ions during the photoirradiation. In one of the experiments (curve a), the same mother sample was divided in different portions that were treated for increasing lengths of irradiation time (with O2 purging). Here, Cd(II) was added only before the voltammetric analysis and after that the sample was disposed (the only exception in the general procedure of returning the same solution for further irradiation).


The process is clearly favoured by the absence of Cd(II). Electron scavenging by Cd ions is thermodynamically unviable since the metal redox potential does not match the position of the energy levels of the electron-hole pair on the photocatalyst, a fact that is well documented in literature.8 In contrast, there is a retarding effect of Cd(II) ions on the EDTA degradation, or better, a slower decomposition of the complex CdH2Y. This fact was already reported in literature under similar experimental conditions19 and may be associated with a lower propensity of the adduct to approach the TiO2 surface vicinity where the photochemical reaction takes place, or simply with a lesser degree of interaction of the ligand with the semiconductor which may be required for an effective photocatalytic effect. In support to this deduction, the effect of Cd(II) in the conventional UV photolysis of EDTA, i.e. without TiO2, was tested and reported in Figure 4B. This process does not, of course, involve heterogeneous phase transfer and is not significantly affected by the presence or absence of cadmium ions.


Finally, the question of hole scavenging was approached. The effect of methanol, a recognised hole scavenger, is shown in Figure 5, in which the lines a and c refer to photodegradations carried out without CH3OH (in the presence and absence of O2), while lines b and d correspond to processes conducted with 1% (v/v, i.e. approx. 0.25 mol L-1) of methanol.


Once again, a shift to shorter degradation times for processes carried out in the presence of O2 is observed. In addition to that, it is possible to distinguish two phases: an initial one, in which the presence of methanol seems to delay the process and a second one where the effect is deadened, with no substantial difference in the overall degradation time. It must borne in mind that not only does methanol act as an hole scavenger, as it plays a role in the propagation of the radical chain mechanism with the formation of highly reactive species such as •CH2OH.23 It could be argued that, at an early phase when the direct hole oxidation is predominant, CH3OH competes with EDTA in the consumption of h+VB causing a setback in the degradation of the targeted organic substrate, though with a positive curvature of the recovery curve. Later on, this effect is dampened perhaps because of the lesser importance of this step and the formation of beneficial reactive radicals.

In the light of this outcome, it was expected a similar effect in connection with the acetate buffer used to prevent pH increase associated with the degradation of EDTA and described elsewhere.26 In the experiment whose results are illustrated in Figure 6, two degradation runs were performed and compared: one with the usual buffering system and another without buffer, both with O2 purging. In the latter, HNO3 was used to initially set the acidity of the medium to pH 4.0 and thereafter to correct it in the course of the photodegradation. The pH was read with a portable pH-metre (Corning pH-30) in the external sample reservoir. In accordance with the results observed in the electron scavengers investigation, in this case ¾ with O2 purging ¾ the NO3- effect ought to be negligible.


The presence of acetate hampers the photodegradation process, in agreement with literature data that report the chance of the acetate substrate to behave as a hole scavenger effect via the so-called photo-Kolbe reaction.12 The effect is similar to the case of methanol, although the concentration of the alcohol was about an order of magnitude higher.

Still, a distinct tendency of the solution to shift towards less a acidic status was observed in the absence of buffer, at least in the presence of EDTA as model ligand, and this has to be avoided to prevent analyte losses by hydrolytic precipitation.26

Conclusions

This article is the second part of a series of papers concerning the exploration of the use of photocatalytic processes for analytical purposes, notably in the pre-treatment of water samples aiming at the destruction of natural dissolved organic matter for total metal determination. It has been previously highlighted the effectiveness of this technique for model and real samples, the possibility of integration in a FIA system comprising injection, in-line digestion, degassing and voltammetric detection, and, finally, the advantages of the use of TiO2 in terms of better/faster photochemical yields. Now, the results described in the above section bring a better insight on the factors that can affect the performance of the semiconductor-assisted photomineralisation. In particular, a further confirmation of the accelerating power of O2, acting as electron scavenger, in the photocatalytic degradation of EDTA was shown. A similar function is exercised by nitrate ions but, interestingly enough, this is completely overshadowed by the presence of O2, which makes believe that the electron scavenging role is entirely satisfied by oxygen, at least under the investigated experimental conditions. The analyte so far used, Cd(II), does not have any scavenging effect and therefore is not lost by reduction.

Experiments with model hole scavengers like CH3OH and acetate/acetic acid buffer (convenient to control the medium acidity) presented a visible effect as antagonists of the desired photocatalytic decomposition, more visible at the early stage of the process of Cd(II) release. At relatively high concentrations (above expected ones in most natural matrixes), the effect of such scavengers can somewhat delay the proposed photocatalytic sample treatment method, but does not impair its application.

In short, on the one hand, the increase of O2 concentrations above air saturation is a simple and convenient way to accelerate the TiO2-assisted photodecomposition of molecules like EDTA since it dispenses with the addition of other reagents acting as electron scavengers, a fact that also reduces the risk of contamination. On the other hand, the presence of moderate amounts of hole scavengers like low molecular weight alcohols or carboxylic acids in the samples or the addition of carboxylate buffers is admissible because their effect is very limited.

These results bring more confidence to the use of the novel in-line TiO2-assisted photodegradation system described in the first paper, widen its potential electroanalytical application26 and it is likely to trigger new studies regarding, for example: metal type and concentration, type and concentration of dissolved organic matter, simultaneous determinations and immobilization of the photocatalyst for use with suspension-incompatible detectors.

Acknowledgement

The authors wish to acknowledge fellowship and financial support by the São Paulo State research agency, FAPESP (Fundação de Amparo à Pesquisa do Estado de São Paulo) and by the Brazilian national research council, CNPq (Conselho Nacional de Pesquisa).

References

35. http://water.usgs.gov/owq/FieldManual/Chapter6/6.2_contents.html, accessed in January 2002.

Received: January 17, 2002

Published on the web: June 24, 2002

FAPESP helped in meeting the publication costs of this article.

  • 1. Ollis, D. F.; Pelizzetti, E.; Serpone, E. In Photocatalysis: Fundamentals and Applications; Serpone, N.; Pelizzetti, E.; eds Wiley: New York, 1989, p. 603.
  • 2. Al-Ekabi, H.; Butters, B.; Delany, D.; Ireland, J.; Lewis, N.; Powel, T.; Story, J. In Photocatalytic Purification and Treatment of Water and Air; Ollis D. F.; Al-Ekabi, H.; eds Elsevier: Amsterdam, 1993, p. 321.
  • 3. Peill, N. J.; Hoffmann, M. R.; US pat. 5,875,384 1999 (CA 130:172408h).
  • 4. Carey, J. H; Lawrence, J.; Tosine, H. M.; Bull. Environ. Contam. Toxicol. 1976, 16, 697.
  • 5. Bard, A. J.; Science 1980, 86, 139.
  • 6. Turchi, C. S.; Ollis, D. F.; J. Catalysis 1990, 122, 178.
  • 7. Rajeshwar, K.; J. Applied Electrochem. 1995, 25, 1067.
  • 8. Litter, M. I.; Appl. Catal. B-Environ. 1999, 23, 89.
  • 9. Sykora, J.; Coord. Chem. Chem. Rev. 1997, 159, 95.
  • 10. Fujishima, A.; Rao, T. N.; Tryk, D. A.; Electrochim. Acta 2000, 45, 4683.
  • 11. Matthews, R. W.; Solar Energy 1987, 38, 405.
  • 12. Kraeutler, B.; Bard, A. J.; J. Am. Chem. Soc. 1978, 100, 5985.
  • 13. Lin, W. Y.; Wei, C.; Rajeshwar, K.; J. Electrochem. Soc. 1993, 140, 2477.
  • 14. Prairie, M. R.; Evans, L. R.; Stange, B. M.; Martinez, S. L.; Environ. Sci. Technol.1993, 27, 1776.
  • 15. Barni, B.; Cavicchioli, A.; Riva, E.; Zanoni, L.; Bignoli, F.; Bellobono, I. R.; Gianturco, F.; Degiorgi, A.; Muntau, H.; Montanarella, L.; Facchetti S.; Castellano, L.; Chemosphere 1995, 30, 1861.
  • 16. Malati, M. A.; Environ. Technol. 1995, 16, 1093.
  • 17. Huang, M.; Tso, E.; Datye, A. K.; Prairie, M. R.; Stange, B. M.; Environ. Sci. Technol. 1996, 30, 3084.
  • 18. Nogueira, R. F. P.; Jardim, W. F.; Solar Energy 1996, 56, 471.
  • 19. Madden, T. H.; Datye, A. K.; Fulton, M.; Prairie, M. R.; Majumdar, S. A.; Stange, B. M.; Environ. Sci. Technol. 1997, 31, 3475.
  • 20. Choi, W. Y.; Hoffmann, M. R.; Environ. Sci. Technol. 1997, 31, 89.
  • 21. Fernadez-Ibañez, P.; Malato, S.; Enea, O.; Catalysis Today 1999, 54, 329.
  • 22. Escuriola, M. J.; Morales-Rubio, A.; de la Guardia, M.; Anal. Chim. Acta 1999, 390, 550.
  • 23. Yang, H.; Lin, W. Y.; Rajeshewar, K.; J. Photochem. Photobiol. A 1999, 123, 137.
  • 24. Campanella, L.; Ferri, T.; Sangiorgio, P.; Sammartino, M. P.; Abstracts of the 8th International Conference on Electroanalysis, Bonn, Germany, 2000.
  • 25. Tryk, D. A.; Fujishima, A.; Honda, K; Electrochim. Acta 2000, 45, 2363.
  • 26. Cavicchioli, A.; Gutz, I. G. R.; Anal. Chim. Acta 2001, 445, 127.
  • 27. Florence, T. M.; Trends Anal. Chem. 1983, 2, 162.
  • 28. Buffle, J.; Complexation Reactions in Aquatic Ecosystems: An Analytical Approach, Ellis Horwood: Chichester, 1988, pp. 1-15.
  • 29. Golimowski, J.; Golimowska, K.; Anal. Chim. Acta 1996, 325, 111.
  • 30. Whitworth, D. J.; Achterberg, E. P.; Nimmo, M.; Worsfold, P. J.; Anal. Chim. Acta 1998, 377, 217.
  • 31. Boarini, P.; Carassiti, V.; Maldotti, A.; Amadelli, R.; Langmuir 1998, 14, 2080.
  • 32. Pelizzetti, E.; Carlin, V.; Minero, C.; Graetzel, M.; New J. Chem. 1991, 15, 351.
  • 33. Reiche, H.; Dunn, W.W.; Bard, A. J.; J. Phys. Chem. 1979, 83, 2248.
  • 34. Kolb, M.; Rach, P.; Schäfer J.; Wild, A.; Fresenius J. Anal. Chem. 1992, 342, 341.
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  • Publication Dates

    • Publication in this collection
      06 Sept 2002
    • Date of issue
      Aug 2002

    History

    • Accepted
      24 June 2002
    • Received
      17 Jan 2002
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