A Bulk Electrolysis Raman Spectroelectrochemical Cell Using a

Potential control was achieved by a Hi Tek DT2101 potentiostat, and the cell current vs electrolysis time was monitored with an X−Y−T recorder (BD...
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Anal. Chem. 2000, 72, 3233-3235

A Bulk Electrolysis Raman Spectroelectrochemical Cell Using a Rotating Electrode Qiang Hu and A. Scott Hinman*

Department of Chemistry, The University of Calgary, Calgary, Alberta, Canada T2N 1N4

A fast bulk electrolysis Raman spectroelectrochemical cell is described. The cell employs a large-area platinum gauze and disk assembly which can be rotated at speeds up to 5000 rpm. The complete electrolysis of a 5-mL solution can be achieved in less than 6 min using a 2000 rpm rotation rate. The resonance Raman spectrum of (TPP•+)Cu(II) was collected in situ in this cell. There is an increasing interest in the application of Raman spectroscopy for the investigation of redox processes because it can provide direct molecular information about both electrogenerated species in the solution phase and species adsorbed on the surface.1-3 A technique known as surface-enhanced Raman spectroscopy (SERS) has become especially important in studying species adsorbed on the electrode surface (usually on Ag or Au electrodes) due to its high sensitivity.4 For species in the solution phase, the use of resonance Raman (RR) spectroscopy is also becoming popular, especially for the characterization of redox reaction intermediates of porphyrins and related compounds.5 Plieth et al.6 have reviewed in situ spectroelectrochemical techniques, including Raman spectroelectrochemistry, and their applications. The design of Raman electrochemical cells is essential in these applications. Several cell configurations for in situ SERS studies have been described in the literature.7 For solution-phase applications, a three-electrode bulk electrolysis cell is usually employed to ensure an adequate number of species is present in the optical path. The time for achieving complete electrolysis in a bulk solution cell depends on the ratio of the electrode surface area to the solution volume and the efficiency of stirring the solution. In cases * To whom correspondence should be addressed: (e-mail) ashinman@ ucalgary.ca; (fax) 403-289-9488. (1) Birke, R. L.; Lombardi, J. R. In Spectroelectrochemistry: Theory and Application; Gale, R. J., Ed.; Plenum Press: New York, 1988; pp 263-348. (2) Birke, R. L.; Lombardi, J. R. In Electrochemical and Spectrochemical Studies of Biological Redox Components; Advances in Chemistry Series 201; Kadish, K., Ed.; American Chemical Society: Washington DC, 1982; pp 69-107. (3) Furtak, T. E. In Advances in Laser Spectroscopy; Garetz, B., Lombardi, J. R., Eds.; John Wiley and Sons: Chichester, U.K., 1984; Vol. 2, pp 175-205. (4) (a) Fleischmann; M.; Hendra; P. J.; McQuillian, A. J. Chem. Phys. Lett. 1974, 26, 163. (b). Fleischmann, M.; Hill, I. R. In Comprehensive Treatise of Electrochemistry; White, R. E., Bockris, J. O′M., Conway, B. E., Yeager, E., Eds.; Plenum Press: New York, 1984; Vol. 8, pp 373-342. (5) Spiro, T. G.; Li, X.-Y. Biological Applications of Raman Spectroscopy; Wiley: New York, 1988; Vol. III, Chapter 1 and references therein. (6) Plieth, W.; Wilson, Fe De La, G. S.; Gutierrez, C. Pure Appl. Chem. 1998, 70, 1395. (7) (a) McQuillan; A. J.; Hendra, P. J.; Fleischmann, M. J. Electroanal. Chem. 1975, 65, 933. (b) Pemberton, J. E.; Buck, R. P. Appl. Spectrosc. 1981, 35, 571. (c). Thanos, I. C. G. J. Electroanal. Chem. 1986, 200, 231. 10.1021/ac9913098 CCC: $19.00 Published on Web 06/08/2000

© 2000 American Chemical Society

where species are susceptible to photoreactions, the movement of the species in the solution must be fast enough to avoid possible photodecomposition due to the focused laser beam. Czernuszewicz and Macor8 described a small-volume bulk electrolysis Raman spectroelectrochemical cell which used a stationary Pt gauze working electrode and a magnetic stirring bar to stir the solution. The actual electrolysis time was not reported for this type of cell configuration. In this work, a rapid electrolysis Raman spectroelectrochemical cell that employs a large-area, high-speed rotating working electrode was designed and tested. The complete electrolysis of ∼5 mL of the solution can be achieved in less than 6 min. In addition, the high stirring rate makes it possible to collect Raman spectra from highly photosensitive samples. EXPERIMENTAL SECTION The copper complex of tetraphenylporphyrin (TPPCu(II)) had been prepared in previous studies, and no further purification was performed.9 Tetra-n-butylammonium hexafluorophospahte (TBAPF6) was prepared according to a previously reported procedure.10 Dichloromethane was shaken with activated alumina, stirred over CaH2 overnight, and then distilled prior to use. Solution concentrations for Raman spectroelectrochemsitry were 0.1 mM TPPCu(II) in CH2Cl2 containing 0.1 M TBAPF6. A saturated calomel electrode (SCE) was used as the reference electrode. Description of the Cell. The configuration of the Raman spectroelectrochemical cell is illustrated in Figure 1. The working electrode compartment is a long flat-bottomed glass tube (10 cm long, 12 mm i.d.) which has a gas inlet port and a reference electrode port in the lower part and a gas outlet port in the upper part. A Radiometer EDI101 rotating disk electrode was employed as the working electrode. A variety of electrode tips are available for this unit, as well as Teflon blanks which facilitate in-house construction of electrodes. To increase the surface area, a combination of Pt disk (5 mm diameter) and Pt gauze cylinder (10 mm diameter, 12 mm height) electrodes was used. The Pt disk was silver soldered onto a brass plug, and two Pt wires were welded to the Pt disk. This assembly was press fit into a Teflon blank supplied by Radiometer. Pt gauze was wrapped around the Teflon electrode body and secured by bending the Pt wires back onto the gauze as illustrated in the cross section view of the working electrode tip. This working electrode tip is threaded onto the EDI101 rotation motor which is controlled by a CTV 101 speed control unit. The location of the working electrode assembly is (8) Czernuszewicz, R. S.; Macor, K. A. J. Raman Spectrosc. 1989, 19, 553. (9) Hinman, A. S.; Pavelich, B. J.; McGarty, K. Can. J. Chem. 1988, 66, 1589. (10) Jones, D. H.; Hinman, A. S. J. Chem. Soc., Dalton Trans. 1503 1992.

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Figure 1. (A) Structure of the Raman spectroelectrochemical cell. (B) Cross section of the working electrode combination.

Figure 3. (A) Plot of the cell current against time recorded during the electrolysis of 1.0 mM TPPCu(II) in dichloromethane containing 0.1 M TBAPF6. The potential was controlled at 1.10 V vs SCE, and the rotation speed of the working electrode was 2000 rpm. (B) The ln(i) vs time plot was for the same process as (A).

radiation. The laser beam passes between the electrode and the wall of the working electrode compartment. The scattered light was collected from one side of the glass tube through the collecting optics. The scattered radiation was dispersed by a Jarrell Ash double monochromator and detected by a photomultiplier tube (RCA31034) using a photon-counting system (SSR Instruments Co.), under the control of a computer. Figure 2. Optical layout of the in situ Raman spectroelectrochemical experiments.

∼12 mm above the bottom of the glass tube, and the Luggin capillary is located right below the working electrode. Two glass frits separate the working electrode compartment and the counter electrode compartment, which contains a platinum wire helix electrode. The working electrode compartment is filled with ∼5 mL of solution containing electroactive species and supporting electrolyte. The solution can be easily degassed through the degassing ports. The counter electrode compartment and the space between the two frits is filled with the solvent containing the supporting electrolyte only. The working electrode assembly can be rotated at speeds up to 5000 rpm. A typical rotation rate used in our experiments is 2000 rpm. Potential control was achieved by a Hi Tek DT2101 potentiostat, and the cell current vs electrolysis time was monitored with an X-Y-T recorder (BD90, Kipp and Zonen). The optical layout for the collection of the Raman scattered light is shown in Figure 2. The laser beam from an Ar+ laser source (Coherent Innova, 457.9 nm, 50 mW) was directed to the bottom of the working electrode compartment as close to the wall of the working electrode compartment as possible. This is important in minimizing reabsorption of the Raman scattered 3234 Analytical Chemistry, Vol. 72, No. 14, July 15, 2000

RESULTS AND DISCUSSION First, the performance of this cell was tested. The cell current vs electrolysis time was recorded during the controlled potential electrolysis of 1.0 mM TPPCu(II) in 0.1 M TBAPF6/CH2Cl2. TPPCu(II) undergoes two successive one-electron oxidations with half-wave potentials of 1.04 and 1.26 V vs SCE.9.10 The potential was controlled at 1.10 V vs SCE which is ∼60 mV higher than the half-wave potential of the first one-electron oxidation of TPPCu(II). Ar purged the solution through the gas inlet during the electrolysis. Figure 3A shows the cell current vs electrolysis time profile, and Figure 3B displays a plot of ln(i) vs electrolysis time, for electrolysis of an ∼1 mM solution of TPPCu(II) with an electrode rotation rate of 2000 rpm. As expected, the current decays according to i ) ioe-λt,11 where io is the initial current and λ is the electrolysis rate constant. From the slope of the ln(i) vs t plot, λ was determined to be 0.011 s-1, corresponding to a halflife of 63 s. Thus, the electrolysis is calculated to be 98% complete after 6 min. After electrolysis, the solution turned green, and the original red color could be recovered when the green solution was reduced at a potential of 0.2 V vs SCE for ∼5 min. The UVvisible spectrum of the green solution shows typical π-cation (11) Bard, A.; Faulkner, L. R. Electrochemical Methods: Fundamentals and Applications; John Wiley & Sons: New York, 1980; Chapter 10.

radical features (decreased intensity and blue-shift of the Soret band, as well as diminished Q-bands), indicating that the final product is the desired (TPP•+)Cu(II) π-cation radical. The actual in situ resonance Raman spectroelectrochemistry was also performed on the TPPCu(II)/0.1 M TBAPF6-CH2Cl2 system. The excitation laser line (457.9 nm) is close to the Soret band of TPPCu(II) (417 nm); therefore, resonance enhancement can be achieved. Figure 4 shows the RR spectrum of TPPCu(II) and (TPP•+)Cu(II) π-cation radical respectively, in 0.1 M TBAPF6/ CH2Cl2. The actual electrolysis time used was 6 min. To avoid possible photodamage of the product, the electrode was rotating at a speed of 2000 rpm even during the spectral collection. The completion of electrolysis could be monitored by observing the position of the ν2 band (near 1561 cm-1) since this band is very sensitive to porphyrin ring oxidation. As observed in Figure 4, the ν2 band shifted down about -30 cm-1 upon oxidation, and the RR spectrum of the π-cation radical does not show any ν2 signal of unoxidized porphyrin. The original RR spectrum of unoxidized porphyrin can also be fully recovered by reducing the π-cation radical at a potential of 0.2 V vs SCE; indicating the reversibility of this redox reaction and thereby, no complexity of any photoreaction. The RR spectrum of (TPP•+)Cu(II) recorded in our experiment is similar to that observed by Spiro and coworkers.12 In addition to facilitating in situ RR spectral measurements, the very short electrolysis times available with this cell make it very useful for bulk electrolysis experiments in general. We have, for instance, isolated several electrochemically generated metalloporphyrin cation radicals in the solid state by adding chilled pentane to the electrolyzed solutions. We have also used the cell to electrolyze solutions prior to transfer to a quartz tube for measurement of electron paramagnetic resonance spectra. (12) Czernuszewicz; R. S. Macor; K. A.; Li; X.-Y.; Kincaid, J. R.; Spiro, T. G. J. Am. Chem. Soc. 1989, 111, 3860.

Figure 4. RR spectra of 0.1 mM TPPCu(II) and (TPP•+)Cu(II) in 0.1 M TBAPF6/CH2Cl2. Spectra were obtained with 457.9-nm excitation, 50-mW laser power, and 8-cm-1 slit widths. The spectrum of (TPP•+)Cu(II) is an average of four scans. Assignments of bands were taken from ref 12. Asterisks indicate the solvent bands.

ACKNOWLEDGMENT The authors are grateful to the Natural Sciences and Engineering Research Council of Canada for financial support. Received for review November 15, 1999. Accepted April 27, 2000. AC9913098

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