Abstract
The development of surface-immobilized molecular redox catalysts is an emerging research field with promising applications in sustainable chemistry. In electrocatalysis, paramagnetic species are often key intermediates in the mechanistic cycle but are inherently difficult to detect and follow by conventional in situ techniques. We report a new method, operando film-electrochemical electron paramagnetic resonance spectroscopy (FE-EPR), which enables mechanistic studies of surface-immobilized electrocatalysts. This technique enables radicals formed during redox reactions to be followed in real time under flow conditions, at room temperature and in aqueous solution. Detailed insight into surface-immobilized catalysts, as exemplified here through alcohol oxidation catalysis by a surface-immobilized nitroxide, is possible by detecting active-site paramagnetic species sensitively and quantitatively operando, thereby enabling resolution of the reaction kinetics. Our finding that the surface electron-transfer rate, which is of the same order of magnitude as the rate of catalysis (accessible from operando FE-EPR), limits catalytic efficiency has implications for the future design of better surface-immobilized catalysts.
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Main
Electron paramagnetic resonance (EPR) spectroscopy is used to investigate both homogeneous and heterogeneous catalysis1,2,3 and helps to guide the development of new catalysts. Although homogeneous catalysts are commonly employed in organic synthesis laboratories due to their high activity, heterogeneous catalysts are attractive as they are more easily recyclable and economic, and dominate in 80% of industrial processes4,5. The need for sustainable, efficient and selective chemical processes is driving the ‘heterogenization’ of homogeneous redox catalysts (Fig. 1), combining the advantages of both catalyst types to develop electrocatalysts for a future net-zero chemical industry4,5,6,7. Electrocatalysis has applications in fuel cells, hydrogenation, CO2 reduction8,9,10, organic electrosynthesis11 and photoelectrosynthesis12. Compared to traditional methods, electrocatalysis promises to be a greener alternative because it produces less metal waste, operates under mild conditions, requires shorter reaction times and is industrially scalable13. Innovating electrocatalysts at a time when green electricity capacity and electrification provide an appealing prospect for a net-zero economy is therefore an important aim towards a sustainable future5,6,10,14,15. The innovation of electrocatalysts requires knowledge of catalytic processes on surfaces and the associated challenges when catalysts are heterogenized, as understanding from catalysts in solution provides only a guide and is not directly transferable.
There is a long, but discontinuous, history of combining electrochemistry with EPR to investigate radical intermediates in catalytic reactions3,16 (Fig. 1). Different spectroelectrochemical (SEC) cells and working electrodes (WEs) have been proposed, and solution-electrochemical EPR has provided insight into homogeneous electrocatalysis3. Combining film electrochemistry with EPR is thus needed to complement the heterogenization of molecular electrocatalysts, and this requires a suitable cell and WE. The most common cells are flat-cells3, with EPR spectra collected using chronoamperometry in conjunction with spin traps17, or freeze-quenching18,19, to detect short-lived intermediates. However, it has not yet been possible to monitor radicals in real time under catalytically relevant conditions, with direct potential control. Given that operando EPR techniques have recently helped to understand battery processes20,21 and heterogeneously catalysed gas-phase reactions22,23, the development of operando electrochemical EPR to obtain kinetic resolution of surface-immobilized electrocatalytic reactions and direct insight into paramagnetic active-site species is timely.
A key bottleneck in the development of operando electrochemical EPR lies in the seemingly incompatible requirements of the two techniques involved: maximizing the conductivity for electrochemistry and minimizing it for EPR measurements, while also maintaining sensitivity. The technical challenges are amplified during catalysis, where mass transport limitations should be avoided, requiring flow conditions. Electrocatalysis in water (an ideal green solvent) poses a further challenge for room-temperature EPR, given its high dielectric constant, and constraints such as geometry, background signals, functionalizability and sensitivity limit the choice of WE3. Our ex situ film-electrochemical EPR (FE-EPR) methodology enables direct potential control of buried redox centres in proteins19, using hierarchical indium tin oxide (ITO) WE materials, which are highly tunable, functionalizable and common substrates for use in a wide range of electrocatalysts24,25,26. However, the capabilities of this method have been limited because it requires frozen samples (to circumvent the high dielectric constant of water) and uses chronoamperometry to hold the potential ex situ before the EPR measurements19,27, thus preventing visualization of active-site species and kinetic resolution of catalytic reactions, which requires an operando method.
In this Article we describe our development of an in situ FE-EPR set-up that detects active-site radical intermediates during electrocatalysis, in real time, under flow conditions and potential control. FE-EPR can selectively and very sensitively detect radical intermediates with kinetic resolution, and complements other operando spectroelectrochemical methods such as infrared25, Raman25,28 and UV–vis29. We use nitroxide-catalysed alcohol oxidation as a model system to demonstrate the insights that can be gained into surface-immobilized catalysts using operando FE-EPR. Nitroxides have been used extensively as electrocatalysts given their environmentally friendly and efficient conversion of alcohols to carbonyls30,31,32,33. Recent work has shifted towards film-electrocatalysis27,34,35 to improve recyclability, although this immobilization brings challenges. The capability to monitor and quantify active-site radical intermediates using operando FE-EPR provides a platform to resolve key challenges introduced by surface anchorage of the catalyst, and paves the way towards understanding and designing surface-immobilized catalysts with enhanced performance.
Results and discussion
Concept and demonstration of operando FE-EPR
The SEC cell (Fig. 2a) was designed to collect EPR spectra synchronously with a suite of common electrochemical techniques, allowing analysis of catalytic systems. The goal was to maximize the quality factor for EPR sensitivity while achieving an electrochemical performance equivalent to a standard three-electrode electrochemical cell, even during operando conditions. The materials to assemble the SEC cell were selected based on the requirements to be EPR-silent, microwave-transparent and electrochemically inert. The cell consists of a conical lower part, which contains the WE and is inserted into the EPR cavity, and a three-dimensionally (3D)-printed upper ‘reservoir’ (see Methods for further details), which contains the counter electrode (CE). The reference electrode (RE) transcends both parts but does not enter the EPR cavity. The conical shape keeps the RE and WE in close proximity and enables effective electrolyte mass transport between electrodes. The inclusion of a RE (as opposed to a pseudo-RE36,37) ensures accurate potential readings. In contrast to our set-up, which also enables cyclic voltammetry (CV), previous electrochemical EPR measurements applied chronoamperometry, followed by acquisition of EPR spectra36,38,39.
To maximize the electrochemical and EPR sensitivity, the surface area of the WE was augmented by assembling a 2.6 µm layer of mesoITO (self-assembled from ITO nanoparticles; Fig. 2c and Supplementary Fig. 1) onto both sides of an ITO-coated (10 nm) flat titanium strip with a total geometric surface area of ~100 mm2 (Fig. 2b). ITO was chosen because of its highly tunable topology compared to other electrodes and its ability to be assembled into hierarchical structures with different pore sizes26. It is compatible with a wide range of redox systems, including small-molecular catalysts27,40,41, enzymes24,42, whole cells43 and bacteria44. This electrode exhibited a much faster current response (0.3 s; Supplementary Fig. 2) than our previous ITO electrodes for SEC (~300 s)19,27 and other electrochemical EPR set-ups39,45, a prerequisite for CV-based SEC. TEMPO (2,2,6,6-tetramethyl-1-piperidinyloxyl) with a silatrane anchoring group (STEMPO) was immobilized onto the mesoITO electrodes27,46 (STEMPO|mesoITO; Fig. 2b) and shown to be surface-bound (Supplementary Fig. 4).
The FE-EPR set-up was evaluated both electrochemically and coupled to EPR. CV scans of STEMPO|mesoITO in the FE-EPR cell at different scan rates exhibit the same electrochemical response as those in a standard electrochemical cell and were unchanged under anaerobic conditions (Extended Data Fig. 1 and Supplementary Section 2). EPR spectra of STEMPO|mesoITO inserted inside the FE-EPR cell in the presence of aqueous buffer solution showed a typical nitroxide signal in the slow-motion regime, consistent with a surface-bound radical (Extended Data Fig. 2). To maximize the signal-to-noise ratio, experiments were performed with the highest non-saturating microwave power and a high (0.4 mT) modulation amplitude. Short sweep times (2.6 s) minimized the potential error of the continuously acquired EPR spectra in the FE-EPR experiments (Supplementary Section 3). Although this allowed the acquisition of 75 EPR spectra per CV scan spanning 800 mV at 5 mV s−1, fast scan rates could face a limitation arising from the time required for a single EPR field sweep (here 2.6 s, resulting in a 21 mV ‘window’ per EPR spectrum).
FE-EPR of STEMPO under non-turnover conditions
The surface-immobilized STEMPO•/STEMPO+ redox reaction was investigated using FE-EPR. The EPR spectra were recorded continuously while sweeping the potential. Figure 3a and Supplementary Video 1 present an example CV scan measured at 5 mV s−1, with a selected set of corresponding EPR spectra shown in Fig. 3b (the complete set is shown in Extended Data Fig. 3). Double integration of the STEMPO radical EPR spectra from the forward and reverse scans, plotted as a function of potential (Fig. 3c), allow deduction of the reduction potential of the reversible STEMPO•/STEMPO+ redox couple (E(non-catalytic, FE-EPR) = +830 mV) by fitting the data to the Nernst equation with the number of electrons transferred (n) equal to 1. The surface electron-transfer rate constant (ks) was determined from Laviron analysis (ks = 0.77 s−1; Supplementary Fig. 4) and agrees with previous work27. The potential derived from EPR measurements was in close agreement with that obtained from the CV scan (Fig. 3 and Supplementary Table 1), demonstrating the excellent performance of the FE-EPR in situ set-up. Multiphysics simulations (COMSOL Multiphysics; Supplementary Section 9) of the FE-EPR data in Fig. 3 enabled us to build a more complete model of electron transfer based on asymmetric Marcus–Hush–Chidsey theory, incorporating intermolecular interactions47,48 (Extended Data Fig. 4), which is fully consistent with the experimental data obtained from FE-EPR experiments across the entire range of scan rates used.
FE-EPR of STEMPO under catalysis
Having successfully established in situ FE-EPR under non-catalytic conditions, we proceeded to investigate STEMPO as an ideal model catalyst, given that nitroxide-catalysed alcohol oxidation has been investigated in detail in solution34 (Extended Data Fig. 5 and Supplementary Section 4) and less extensively in the surface-immobilized form27,35,49,50,51. The surface-immobilized reaction with the substrate 4-methylbenzyl alcohol (MBA) proceeds via a catalytic electrochemical–chemical mechanism (EC′) (based on a catalytic CV scan, Fig. 4a), consistent with previous studies carried out both in solution and when surface-immobilized34,52,53,54. Interestingly, it has been shown using in situ Raman and vibrational spectroscopy that the mechanism of a Co catalyst is different on a surface25 than in solution55, highlighting that not all aspects of solution-based alcohol oxidation by nitroxides will necessarily translate to the surface-immobilized case.
The simultaneously recorded EPR spectra (Fig. 4b; Extended Data Fig. 6 provides a complete set) show the gradual disappearance of STEMPO• as it is transformed to STEMPO+ in the forward scan, then its reappearance in the reverse scan. The flow conditions (Fig. 2a) ensure that mass transport of the MBA is sufficiently high not to be rate-limiting, with minimal substrate depletion at the electrode surface (Supplementary Fig. 26). The same EPR spectrum was regenerated in the reverse scan, suggesting chemical reversibility by reforming a radical species, after catalysis, that is structurally the same as the one present before catalysis, and providing evidence that STEMPO• is a catalytic intermediate. In solution-based studies, TEMPO• has not been detected directly during catalysis due to a lack of suitable techniques, although a radical has been inferred56; this showcases the sensitivity and time resolution possible with FE-EPR. Although FE-EPR is blind to diamagnetic intermediates, in this case STEMPOH and STEMPO+, it has the advantage of being able to selectively detect very low concentrations of key paramagnetic surface-immobilized active-site species (TEMPO•) that are very difficult to access with other SEC methods. In surface-immobilized electrocatalysis, this selectivity is particularly advantageous, given the size and complexity of the system.
Fitting of the double-integral EPR data in Fig. 4c with the Nernst equation provides directly observable metrics from FE-EPR to describe the catalytic system. Under catalysis, the apparent n (napp) decreases successively with increased substrate concentration (napp = 0.3 for 20 mM MBA; Supplementary Table 2) in both the forward and reverse scans. Concomitantly, the catalytic potential (Ecat) becomes more positive with increasing substrate concentration (Fig. 4e and Supplementary Table 2). Similar trends were observed under anaerobic conditions and with the secondary alcohol glycerol as substrate (Supplementary Section 5). Ecatalytic from FE-EPR (Ecatalytic, FE-EPR) and the electrochemistry alone (Ecatalytic, CV) are in near-perfect agreement (Supplementary Table 2) in this case, where ideal sigmoidal catalytic CV scans57 are observed. However, it is noteworthy that FE-EPR provides this useful parameter even when electrochemical data alone cannot.
A set of rate equations was assembled for the possible processes that are taking place (equations (1) to (6)). These form the basis of kinetic investigations where the rates of some components of this scheme can be directly accessed by FE-EPR and used in combination with Multiphysics simulations for mechanistic determinations (see Methods and Supplementary Information section 9):
The observed trend in napp and Ecatalytic can be explained as arising from relatively slow electron transfer, occurring at a comparable rate to catalysis (Extended Data Fig. 7 and Supplementary Section 9). When the rate constant for chemical catalysis (kcat) was fixed and ks was decreased, napp from the modelled STEMPO• concentrations decreased. At high ks (greater than the critical scan rate and higher than kcat), varying ks had little effect on the wave shape. This behaviour is indicative of the interplay between ks and kcat in the STEMPO system, which must be of similar magnitudes (Extended Data Fig. 7), unlike in diffusion-controlled systems due to the surface-immobilized nature of the electron transfer. Although, in contrast to their homogeneous counterparts, immobilization removes diffusional components, a high ks is essential for the performance of surface-immobilized catalysts and necessitates kinetic and mechanistic consideration. Thus, to deconvolute ks and kcat, a direct experimental measurement of kcat is required, highlighting the need to observe surface-immobilized catalysts directly.
Operando FE-EPR provides kinetic resolution
With chronoamperometry-based FE-EPR (FEamp-EPR), kcat can be determined directly from operando measurements (Fig. 5), avoiding the assumptions of foot-of-the-wave analysis (Supplementary Section 10). The STEMPO• EPR signal is monitored at open-circuit potential (OCP) following a high-potential step to generate STEMPO+ exclusively. Online product detection showed that MBA was selectively oxidized to 4-methylbenzaldehyde (Faradaic efficiency of 96%, from HPLC; Supplementary Section 8). In the absence of substrate, the STEMPO• signal intensity returned to its initial levels, with a radical regeneration rate of 7.3 µM s−1 (Fig. 5a). Regeneration of STEMPO• was also observed under anaerobic conditions at the same rate at pH 8.0 and 7.3. STEMPO• regeneration was faster in the presence of MBA and increased with substrate concentration, including under anaerobic conditions. A similar trend was observed with glycerol (Extended Data Fig. 8 and Supplementary Section 6).
Regeneration of the nitroxide at OCP under catalytic conditions provides direct evidence for the formation of STEMPO• as an active-site species during catalysis. The rate of STEMPO• regeneration as a function of MBA or glycerol concentration fits the Michaelis–Menten model (Fig. 5b and Extended Data Fig. 8b). The Michaelis–Menten model, which is a specific case of the more general substrate saturation model (Supplementary Section 7), is based on the formation of an enzyme–substrate (catalyst–substrate) complex58, with binding affinity equal to the inverse of the Michaelis–Menten constant, KM. The Michaelis–Menten model, which is extensively used to characterize enzyme–substrate interactions, has rarely been applied to molecular catalysts59,60,61, but parallels can also be drawn with the Langmuir–Hinshelwood mechanism describing the surface saturation of heterogeneous catalysis62. Quantification of the catalyst–substrate association kinetics is then straightforward. The KM values determined from FE-EPR for STEMPO+–MBA and STEMPO+–glycerol associations are 6.8 ± 1.3 and 1.8 ± 0.9 mM, respectively. The higher binding affinity for glycerol is expected given its three -OH groups (compared to one in MBA). The catalytic rates, kcat, are 0.22 s−1 for MBA and 0.06 s−1 for glycerol at pH 8.0, as quantified from EPR (Supplementary Fig. 10 and Supplementary Table 3). Although oxoammonium-alcohol adduct formation has been studied extensively in solution31,34,63,64,65,66, the substrate binding affinity is rarely quantified67.
kcat is pH-dependent and can be directly observed by FE-EPR, with higher pH increasing kcat and lower pH decreasing kcat (0.09 s−1 at pH 7.3; Extended Data Fig. 9). The pH dependence, which has been extensively studied for different nitroxides in solution under non-catalytic conditions68, alludes to the formation of an oxoammonium hydroxide adduct54, as the rate equation dictates a linear increase with [OH−] (equation (4)), and a less than logarithmic dependence of the directly measured kcat on pH is observed. This indicates a pKa for the formation of the oxoammonium hydroxide adduct of 7.1 (equation (3)), substantially lower than that for solution TEMPO (pKa > 12)69. This can be due to a structural effect from the presence of the silatrane linker54 or due to the effect of surface immobilization on pKa values25,70. The formation of the oxoammonium-hydroxide adduct is consistent with the previously observed plateau in catalytic activity at pH 10 (ref. 27) and can be used to accurately describe the FE-EPR data at OCP for all substrate concentrations and pH with Multiphysics modelling (Supplementary Section 9). STEMPO• is regenerated at OCP, providing evidence of a surface comproportionation reaction (Extended Data Fig. 10 and equation (5)), which would require current to flow. This is consistent with the presence of intermolecular interactions required to describe the non-turnover case. However, comproportionation does not exclude STEMPO• regeneration by Proton coupled electron transfer (PCET), as the non-turnover signal for the STEMPOH/STEMPO• redox couple that has been observed (with ks = 5.7 s−1) is pH-dependent (E0 = 0.386 − 0.059 × pH V versus standard hydrogen electrode (SHE); Supplementary Fig. 23). It is important to emphasize that the rate-determining step is determined by kcat (equation (4)), with comproportionation or PCET steps only influencing the regeneration of STEMPO• and its concentration in the catalytic cycle.
With the availability of a measure for kcat, our electrochemical model can fully explain all trends in the extant FE-EPR data with comparable current magnitudes and wave shapes, coupled to comparable trends with substrate concentration in the EPR-observed STEMPO• concentration (Extended Data Fig. 10). The direct measure of ks, kcat, the order of reactions (as deduced from kcat at pH 8.0 versus pH 7.3) and catalytic site concentrations can be used to fix the rates of some reactions in the catalytic cycle (Supplementary Tables 3 and 6). Different mechanisms for components of the cycle that are not yet accessible directly from experiments (namely possible reactions following the rate-determining step) were then tested with our Multiphysics model. The mechanism of STEMPO• regeneration after the catalytic intermediate is debated in solution-based reactions, with both comproportionation71 and PCET constituting possible pathways34 (Extended Data Fig. 10 and Supplementary Section 9), and insight into the surface-immobilized process is lacking. However, unlike in solution-phase catalysis, there is no requirement for STEMPOH to diffuse to the electrode to enable a PCET pathway. Using the experimentally determined ks and kcat, the observed STEMPO• concentrations under catalysis are more consistent with PCET being the dominant regeneration mechanism (Extended Data Fig. 10). Although this does not preclude a comproportionation mechanism alongside PCET, the PCET pathway is substantially faster in the surface-immobilized case.
Figure 6 summarizes the key findings from operando FE-EPR, made possible by (1) detecting a key active-site species (STEMPO•) during catalysis (Figs. 4 and 5) and (2) determining the timescales on which it is regenerated (Fig. 5). The combined structural information and kinetic resolution have led to a complete electrochemical model that can be interrogated to provide mechanistic insight. Although our investigations were dedicated to a surface-immobilized catalyst, the extensive body of work on solution-based nitroxides mediating alcohol oxidation (Extended Data Fig. 5 and Supplementary Section 4) provided inspiration and guided the elucidation of the mechanism, while omitting the challenges related to surface-immobilized catalysis resolved within. Thus, although further investigations of alcohol oxidation by surface-immobilized TEMPO will provide insights into the detailed mechanism, the kinetic resolution provided by operando FE-EPR made possible by detecting active-site catalytic intermediates has revealed the need to improve ks.
Conclusion
The reported operando FE-EPR set-up enables the identification and kinetic resolution of paramagnetic intermediates formed by surface-immobilized redox catalysts. This economical, easy-to-replicate and user-friendly set-up has several advantages: (1) it is compatible with the widespread super-high-Q EPR cavities, (2) operation is possible at room temperature, with an aqueous solution and under flow conditions, and (3) a ‘true’ reference electrode (with a stable potential) can be used. These advantages make CV-based SEC measurements (FECV-EPR) with excellent potential control possible. Besides exhibiting an electrochemical response on par with ‘pure’ electrochemical set-ups, our SEC experiments enable direct visualization of the electronic state of the catalyst (STEMPO) through in situ EPR measurements both under catalytic and non-catalytic conditions. Operando FE-EPR has enabled the measurement of essential kinetic parameters in this model surface-immobilized electrocatalytic reaction.
By using the experimentally determinable kinetic parameters from FE-EPR (ks, kcat and KM), our electrochemical model could explain the observed trends in the catalytic wave shapes with increasing substrate concentrations (decreasing n and increasing Ecatalytic, as determined reliably with FECV-EPR). This has revealed that the interplay between electron transfer and catalysis is key to the efficiency of the nitroxide catalyst. Although fast electron transfer is often assumed for small-molecular systems on surfaces, this is not the case, and the effect on the concentrations of catalytic intermediates within the catalytic cycle could be resolved. In the future, this experimental insight, combined with Multiphysics modelling to test and compare mechanistic hypotheses to the experimental data, could be extended to include the full toolkit of available electrochemical and EPR techniques. Freeze-quenching16,19 will open the prospect of investigating fast-relaxing radicals formed during catalytic reactions at any applied potential and using pulse EPR. Through the possibility to observe, identify and quantify low-concentration key paramagnetic active-site species and the ensuing kinetic resolution, operando FE-EPR has the potential to contribute to the rational design of catalysts by tuning immobilization strategies and local environments to achieve the transition to sustainable chemistry
Methods
Materials
All chemicals were purchased at analytical grade and used without further purification from Sigma-Aldrich. STEMPO was synthesized as described in ref. 27. ITO nanoparticles for making hierarchical electrodes were purchased from Sigma-Aldrich (nanopowder with particle size of <50 nm). Deionized ultrapure water (18 MΩ cm) was used for all experiments. The sodium carbonate buffer (Na2CO3, 500 mM) was adjusted to pH 8.0 or pH 7.3 with concentrated HCl(aq). Stock solutions of 4-methylbenzyl alcohol (30 mM) and glycerol (5 M) were prepared in the Na2CO3 buffer.
Electrode preparation and functionalization
Titanium strips (Sigma-Aldrich, thickness 0.127 mm, purity 99.7% trace metals) were cut to the dimensions shown in Fig. 2b and sonicated sequentially for 20 min in EtOH, followed by 2-isopropanol and finally acetone. ITO nanoparticles (5 wt%) were suspended in a pure ethanol solution with 5 M acetic acid. The nanoparticle solution was sonicated for 30 min, then 10 µl was drop-cast onto each side of the ITO-sputtered titanium strip. Once air-dried, the electrodes were heated from room temperature to 500 °C at a rate of 1 °C min−1, then annealed at 500 °C for 20 min. Once cooled, the working electrodes (henceforth referred to as mesoITO WEs) were cleaned by submersion in a mixture of 30% NH4OH:H2O:30% H2O2 (1:5:1 vol/vol) at 70 °C for 15 min, then dried in the oven at 180 °C for 1 h. STEMPO was immobilized on the electrode surface as described previously27.
Film-electrochemistry
Electrochemical measurements were carried out using a µAutolabIII potentiostat in combination with NOVA software. Electrochemical experiments were performed using the standard three-electrode configuration, with the mesoITO WE, AgǀAgCl (3 M KCl) as the reference electrode (RE, World Precision Instruments) and a coiled nickel wire (thickness of 50 µm) as the counter electrode (CE). The electrolyte consisted of 500 mM Na2CO3 buffer (pH 8.0 or pH 7.3). Measurements were performed on the bench, open to the laboratory atmosphere, unless otherwise stated. Two electrochemical cells were used in this study: (1) a custom 3D-printed cell for FE-EPR applications (Fig. 2) and (2) a standard glass cell (Southampton University scientific glassblowing service) for validation of the FE-EPR set-up. All potentials were converted to the SHE. The shift of potential due to the iR drop (ohmic drop) was negligible and corrected after data collection (Supplementary Fig. 6).
EPR spectroscopy
Continuous-wave X-band EPR measurements were performed at room temperature with an X-band Super High Sensitivity Probehead ER 4122SHQE unit (Bruker) and an EMX-T-DU/L Bruker spectrometer. To assess the performance of the electrochemical set-up and mesoITO WE before or after FE-EPR measurements, standard field-sweep EPR experiments were performed. The 2D field-delay experiments were carried out during FE-EPR measurements. EPR parameters for 2D field-delay experiments were chosen to minimize the sweep time of a single EPR spectrum while maximizing the resolution (62 mW microwave power, 10 mT sweep width, 2.6-s sweep time, 0.4 mT modulation amplitude, 100 kHz modulation frequency, 30 dB receiver gain and 1,000 points per scan).
In situ FE-EPR cell
The lower canonical part of the FE-EPR cell was made of low-density polyethylene. The upper reservoir was 3D-printed with thermoplastic polylactic acid.
In situ FE-EPR measurements
STEMPO-functionalized mesoITO WEs were rinsed with buffer to remove any unbound STEMPO and air-dried. Dry functionalized WEs were inserted into a standard EPR tube (Wilmad, 4-mm outer diameter clear fused-quartz (CFQ)) and an EPR field sweep was carried out (in the absence of any solvent) before FE measurements.
The FE-EPR set-up was assembled as follows: (1) the electrochemical cell was inserted into the EPR cavity; (2) the mesoITO strip was attached to a Ti wire (thickness, 10 µm) using parafilm; (3) the electrode was placed into the conical part of the FE-EPR cell (Fig. 2c); (4) circulation of 8 ml of Na2CO3 buffer (500 mM, pH 8) was initiated using a peristaltic pump (Pump P-1, General Electrics) operating at a rate of 30 mL h–1; (5) the Ag|AgCl RE was placed into the conical part of the FE-EPR cell as close as possible to the WE; (6) the Ni-wire CE was added to the reservoir of the FE-EPR cell; and (7) the electrodes were connected to the potentiostat. For the catalytic experiments, the substrate was added directly to the solution in the assembled cell inside the EPR cavity, by injecting the stock solution with the appropriate volume to give the final desired substrate concentration.
To perform in situ FE-EPR experiments under flow conditions, plastic tubing (inner diameter of 1 mm) was used to connect (1) the bottom part of the cell to the peristaltic pump and (2) the peristaltic pump to the upper part of the cell, as shown in Fig. 2. The flow direction was from the top to the bottom of the cell, with the flow speed controlled by the peristaltic pump. The part of the plastic tubing inside the EPR cavity was inserted into a 4-mm open-ended quartz tube (Fig. 2) to avoid distortion and prevent any leakage from entering the cavity. Insertion of the mesoITO strip into the SHQE EPR cavity led to a 40% drop in its quality factor Q. Field-delay EPR experiments were launched simultaneously with starting the CV scan and stopped at the end of the electrochemical experiment.
For the FECV-EPR experiments, 2D field-delay EPR was launched with a duration of 4.1 s per EPR spectrum (2.6-s sweep time + 1.5-s processing time) while sweeping the potential at 5 mV s−1, which led to steps of 21 mV per EPR spectrum. Under these conditions, the total duration of the FECV-EPR experiment was ~340 s.
For the FEamp-EPR experiments, the potential was held at +0.6 V such that only the EPR-active species (STEMPO•) was present, then stepped to +1.1 V such that the EPR-silent species (STEMPO+) was generated exclusively. The current was monitored at OCP over time and the experiment was performed with and without substrate. EPR spectra were recorded throughout the chronoamperometry-OCP measurement.
Morphological characterizations
Scanning electron microscopy (SEM) images were collected using a Zeiss LEO Gemini 1525 field-emission-gun scanning electron microscope (FEG-SEM) with an InLens detector, using an accelerating voltage of 5 kV and 30-µm standard aperture. The top surface images of the mesoITO electrode were taken by fixing the electrode to a standard flat SEM specimen stub. The cross-sectional images were taken by fixing the electrode to a 45°-angled SEM specimen stub.
Confocal topography analysis was conducted using a Zeiss LSM 800 laser confocal scanning microscope with ZEN Blue 2.6 software. Confocal reflection-mode image stacks (Z-stack interval of 0.26 µm) were obtained using a 405-nm laser (2.0% power) with a ×20/NA 0.7 objective lens. The collected stacks were then processed using ConfoMap software to obtain the 3D view image and determine the film thickness of the mesoITO electrode.
HPLC for product analysis and quantification
During the stepped chronoamperometry catalytic reaction, a 1-ml aliquot of the solution was taken from the FE-EPR cell at the end of each potential step. The aliquot was then analysed using an Agilent 1260 Infinity II HPLC system and a diode array detector monitoring 254 nm (Supplementary Fig. 20). A 2-µl volume of the sample was injected into a flow of 0.5 ml min−1 through a 50 mm × 2.1 mm Raptor C18 column (particle size, 2.7 µm) purchased from Restek. The temperature was 40 °C and the mobile phase consisted of a mixture of acetonitrile (MeCN) and 5 mM aqueous ammonium formate, with a gradient from 5% MeCN to 95% MeCN over 1 min, followed by a hold at 95% MeCN for 3.5 min. Standard calibration curves for 4-methylbenzaldehyde (Supplementary Fig. 21) were then generated to quantify the product and determine the concentration of species in the reaction aliquot.
Data analysis
CV analysis by the Laviron method
The Laviron analysis was carried out using the following equations:
where ΔEp, a and ΔEp, c are the differences between the potential of the anodic (a) and cathodic (c) peaks to the formal reduction potential (Enon-catalytic, CV) obtained by averaging the anodic and cathodic potentials at 5 mV s−1, n is the number of electrons transferred, α is the electron-transfer coefficient, ν is the scan rate, and kapp is the apparent rate constant for electron transfer. R, T and F are the ideal gas constant, absolute temperature and Faraday constant, respectively.
The Laviron method (Supplementary Fig. 4) was applied by linearly fitting the anodic and cathodic regions of the trumpet plot for values of ΔEp, a, ΔEp, c > 100 mV. (1 − α) and α were determined from the gradients of the anodic and cathodic trends respectively. kapp, a and kapp, c were deduced from the y intercept, and the critical scan rate, υc, was obtained from the x intercept by extrapolating the linear regression of the trumpet plot in both regions to ΔEp = 0.
EPR signal intensity calibration
The concentration of STEMPO radical observed by EPR was determined through calibration with different known concentrations of 4-aminoTEMPO. The same electrode configuration was used in the FE-EPR cell as in Fig. 2a, but instead of attaching STEMPO to the WE surface, 4-aminoTEMPO was added to the solution at different concentrations. The resulting linear dependency (Supplementary Fig. 8) of the 4-aminoTEMPO EPR signal intensity versus concentration was then used to determine the concentration of STEMPO radicals observed in FEamp-EPR measurements. STEMPO• concentrations of 80 and 70 µM were determined on the electrodes used for measurements with MBA and glycerol, respectively.
Michaelis–Menten model
The Michaelis–Menten model was used to fit the catalytic currents and radical regeneration rates, based on the Michaelis–Menten equation:
where v is the rate of the reaction, Vmax is the maximum rate of the reaction, and KM is the Michaels–Menten constant. Vmax and KM were deduced from the plots obtained. The binding affinity is the inverse of the Michaelis–Menten constant. The catalytic rate kcat was calculated using the following equation:
where [Catalyst]i is the initial concentration of catalyst, here STEMPO, quantified from EPR (Supplementary Fig. 8 and Supplementary Section 7).
Nernst fitting of FE-EPR data
The Nernst equation was used to fit the FE-EPR data for the \({{\rm{STEMPO}}}^{+}+n{\rm{e}}^{-}\rightleftharpoons {{\rm{STEMPO}}}^{{\rm{\bullet }}}\) equilibrium reaction:
where E is the potential in the cell, \({E}^{\,^\circ }\) is the standard reduction potential, R is the gas constant, T is the temperature (here room temperature), n is the number of electrons transferred, and F is the Faraday constant.
Knowing that only STEMPO• is EPR-active, and that at low potentials, all STEMPO species are in the STEMPO• form, the total concentration of STEMPO is equal to [STEMPO•]i. Consequently, [STEMPO•]i = [STEMPO+] + [STEMPO•].
[STEMPO•] is equivalent to the double integral of the STEMPO radical EPR signal. At room temperature, this leads to the following equation used to plot FECV-EPR data:
where \({\iint {{\rm{STEMPO}}}^{{\rm{\bullet }}}}\) are the double integrals of the STEMPO• EPR spectra.
CV FE-EPR data analysis
To process the acquired electrochemical and EPR data, we developed a MATLAB-based program. This program plots EPR intensities or spin concentrations as a function of the applied potential with fitting to the Nernst equation. The analysis procedure for the FECV-EPR data is shown in Supplementary Video 2 and summarized here briefly. The EPR and CV data were first plotted independently. If multiple CV scans were performed, one CV scan (with the corresponding EPR data) was selected for the subsequent analysis. Because the time axis is the common basis between the EPR and CV data, the chosen CV scan and the corresponding EPR data were split into forward and reverse datasets. The forward and reverse EPR data were baseline-corrected using the function basecorr in EasySpin77 before double integration. To assign a potential value to each EPR spectrum acquired during the forward CV scan, the potential range corresponding to the forward CV scan was divided by the total number x of EPR spectra of this range. The resulting potential increment was used as a ‘step’ on the forward CV potential axis, resulting in n different points on this axis, with each potential value corresponding to one EPR spectrum. The double integrals of the EPR spectra (y axis) were plotted as a function of potential obtained from the forward CV scan (x axis) and fitted to the Nernst equation. The Nernst fit was optimized directly using the Simplex derivative-free method through the fminsearch MATLAB function. The same process was repeated for the reverse CV scan datasets.
Chronoamperometry-EPR data analysis
Double integrals of the EPR spectra (following baseline correction, as described for the CV-EPR data) were plotted against time. The resulting data, corresponding to the regeneration of the nitroxide radical, were fitted using first-order relaxation:
where y is the EPR double integral or radical concentration, A1 is the amplitude, t is the time, which corresponds to the x axis, k is the rate of regeneration of the radical and y0 is the asymptotic constant reached when t → ∞.
Multiphysics modelling
COMSOL Multiphysics 6.1 with electroanalysis and laminar flow modules was used for Multiphysics modelling to describe the solution (electro)chemical reactions and convection, respectively. This model solves ordinary differential equations corresponding to well-defined analytical expressions of mass transport, (electro)chemical reaction rates and equilibria. Further details are provided in Supplementary Section 9.
Data availability
Data for the main text and Supplementary Information are available from the Imperial Research Data repository (https://doi.org/10.14469/hpc/13519). Source data are provided with this paper.
Code availability
Custom MATLAB-based FE-EPR data analysis programs to accompany the roadmap for data analysis provided in Supplementary Videos 1 and 2 are available from the Imperial Research Data repository (https://doi.org/10.14469/hpc/13517). COMSOL Multiphysics models were built based on the information provided in Supplementary Section 9. Model reports are available from https://doi.org/10.14469/hpc/13517.
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Acknowledgements
This study was supported by the Leverhulme Trust (grant no. RPG-2018-183 to M.M.R. and E.R.), a Leverhulme Early Career Fellowship (ECF-2021-072 to S.J.C.), the Isaac Newton Trust (20.08(r), to S.J.C.), an Imperial College President’s scholarship to Y.D., an EPSRC grant (EP/W005794/1) to M.M.R. and a UKRI Frontiers (ERC Advanced) grant (EP/X030563/1 to E.R.). The EPR measurements were performed at the Centre for Pulse EPR at Imperial College London (PEPR), supported by EPSRC grant no. EP/T031425/1 to M.M.R. We thank J. Eisermann (Imperial College) for using and improving the Laviron method fitting program. A. Collauto (Imperial College) and J. Eisermann are also acknowledged for helpful discussions.
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Contributions
M.S.-E. developed the operando FE-EPR methodology, with input from and based on prior work from K.A. M.S.-E. carried out and developed the analysis programs for all FE-EPR experiments. S.J.C. carried out all electrochemical modelling. Y.D. conducted the product detection experiments and electrode surface characterization. M.A.B. synthesized STEMPO. M.M.R. conceived the project. M.M.R. and E.R. supervised the project. M.S.-E. and M.M.R. wrote the manuscript, with input from S.J.C. and E.R., and contributions from all authors.
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Extended data
Extended Data Fig. 1 Electrochemical characterisation of STEMPO|mesoITO electrode in the FE-EPR cell.
Cyclic voltammograms of STEMPO|mesoITO electrode showing oxidoreduction of the STEMPO•/STEMPO+ redox couple in the FE-EPR cell with 8 ml 500 mM Na2CO3(aq), pH 8.0 at 20 °C. Two CVs are shown for each scan rate to illustrate the stability. See methods for experimental parameters and conditions.
Extended Data Fig. 2 EPR characterisation of STEMPO|mesoITO electrode in the FE-EPR cell.
Long scan (black line, 50 s) and short scan (green line, 2.6 s) EPR spectra of STEMPO• attached to the surface of ITO measured in the FE-EPR cell at open circuit potential in presence of buffer and under flow conditions. See Methods for experimental parameters and conditions.
Extended Data Fig. 3 Complete set of EPR spectra recorded over the course of the FEcv-EPR experiment under non-catalytic conditions.
Complete set of 77 EPR spectra obtained during the FECV-EPR measurements during both forward and reverse CV scans. The sweep time per spectrum was 2.6 s, and around 4 s including processing time. With a scan rate of 5 mVs−1 and a potential range of 800 mV, each EPR spectrum has a potential range of 21 mV. During the forward CV scan, the intensity of the EPR spectra decreases with increasing the potential, reaching a minimum at 900 mV. During the reverse CV scan, the intensity increases back to reach a maximum at 800 mV.
Extended Data Fig. 4 Experimental and simulated non-turnover signals for STEMPO.
a Experimental (dashed) and simulated (solid) cyclic voltammograms of STEMPO on a MesoITO electrode over a range of scan rates (5–400 mV) at pH 8.0. For Experimental details see Methods and for simulation details see Supplementary Information section 9. b Experimental (filled points) and simulated peak potentials for the anodic (red) and cathodic (black) branch. Lines represent linear fits to the region of experimental data where ΔEp > 200 mV for experimental determination of ks = 0.77 s−1 and α = 0.37. c Experimental (filled points) and simulated peak currents for the anodic (red) and cathodic (black) peak potentials as a function of scan rate.
Extended Data Fig. 5 Schematic representation of the mechanism of solution-based electrocatalysis with TEMPO•.
Electrochemical oxidation (step 1), adduct formation (step 2), alcohol oxidation (step 3) and catalyst regeneration (step 4).
Extended Data Fig. 6 Complete set of EPR spectra recorded over the course of the FEcv-EPR experiment under catalytic conditions.
EPR spectra obtained during the FECV-EPR measurements during both forward and reverse CV scans in the presence of 20 mM MBA under catalytic conditions. Similarly, to the non-turnover spectra, each EPR spectrum covers ~21 mV. During the forward CV scan, the intensity of the EPR spectra decreases with increasing the potential, reaching a minimum at 1000 mV. During the reverse CV scan, the intensity increases back to reach a maximum at 700 mV.
Extended Data Fig. 7 Effect of varying kS and kcat on the catalytic response.
CVs with varied ratios of ks to kcat. a, STEMPO• partial surface coverages, demonstrating a STEMPO• concentration dependence that fits an apparent n = 1 Nernst curve at high ks, decreasing as ks < critical scan rate. b, STEMPO• partial surface coverages, demonstrating a STEMPO• concentration dependence that fits an apparent n = 1 Nernst curve at the limits of kcat and an n < 1 apparent Nernst curve at intermediate values. The apparent E1/2 shifts to more positive potentials with increasing kcat. At high kcat the reverse response differs from the forward response due to substrate depletion.
Extended Data Fig. 8 Generation of EPR-active STEMPO• under open circuit potential (OCP) in the absence and presence of glycerol at pH 8.0.
The potential was held at +0.6 V such that only the EPR-active species (STEMPO•) is present, and then stepped to +1.1 V such that EPR-silent (STEMPO + ) is generated exclusively. The current is monitored at OCP over time and the experiment was performed with and without substrate. EPR spectra were recorded throughout the chronoamperometry-OCP measurement. a, Double integrals of EPR spectra showing regeneration of STEMPO• in the absence of substrate (black dots), and in the presence of 1 mM (red dots) and 5 mM (blue dots) glycerol after potential steps at + 0.6 V and + 1.1 V vs SHE, for 100 s each. b, STEMPO• regeneration rates as a function of substrate concentration (0, 1, 5 and 10 mM glycerol), deduced from a 1st order relaxation fit of the variation of STEMPO• concentration over time, as quantified from the EPR data. The solid line shows the fit using the Michaelis-Menten model with KM = 1.8 ± 0.9 mM and kcat = 0.06 s−1.
Extended Data Fig. 9 Generation of EPR-active STEMPO• under open circuit potential (OCP) in the absence and presence of MBA at pH 7.3.
The potential was held at +0.6 V such that only the EPR-active species (STEMPO•) is present, and then stepped to +1.1 V such that EPR-silent (STEMPO + ) is generated exclusively. The current is monitored at OCP over time and the experiment was performed with and without substrate. EPR spectra were recorded throughout the chronoamperometry-OCP measurement. a Double integrals of EPR spectra showing regeneration of STEMPO• in the absence of substrate (black dots), and in the presence of 1 mM (red dots) and 6.8 mM (blue dots) MBA after potential steps at + 0.6 V and + 1.1 V vs SHE, for 100 s each. b STEMPO• regeneration rates as a function of substrate concentration (0, 1, 2.4, 6.8, 10 and 20 mM MBA; the colours of the data points match the data in a and in Supplementary Figure 16), deduced from a 1st order relaxation fit of the variation of STEMPO• concentration over time, as quantified from the EPR data. The solid line shows the fit using the Michaelis-Menten model with KM = 0.96 mM and kcat = 0.09 s−1.
Extended Data Fig. 10 Experimental and simulated FE-EPR experiments for different STEMPO• regeneration pathways.
a, CVs at a range of substrate concentrations ([MBA] = 0–20 mM, pH 8.0) solid lines are experimental data and dash-dot lines simulate a PCET regeneration pathway b, STEMPO• partial surface coverages at a range of substrate concentrations for a PCET regeneration pathway ([MBA] = 0–20 mM, pH 8.0) c, CVs at a range of substrate concentrations ([MBA] = 0–20 mM, pH 8.0) solid lines are experimental data and dash-dot lines simulate a comproportionation regneration pathway d, STEMPO• partial surface coverages at a range of substrate concentrations for a comproportionation pathway([MBA] = 0–20 mM, pH 8.0). For all panels solid lines are fits of experimental data and dash lines are simulated data.
Supplementary information
Supplementary Information
Surface characterization of the mesoITO working electrode, electrochemical and EPR characterization of the FE-EPR cell, the mechanism of solution-based electrocatalytic alcohol oxidation by nitroxides, the general saturation behaviour model, production detection, electrochemical analysis, foot of the wave analysis, Supplementary Figs. 1–28 and Tables 1–6.
Supplementary Video 1
Example CV scan measured at 5 mV s−1, with a selected set of corresponding EPR spectra.
Supplementary Video 2
Analysis procedure of FECV-EPR data.
Source data
Source Data Fig. 2
Unprocessed confocal image.
Source Data Fig. 2
Unprocessed SEM image.
Source Data Fig. 3
Electrochemistry and EPR source data from FE(CV)-EPR experiments.
Source Data Fig. 4
Electrochemistry and EPR source data from FE(CV)-EPR experiments.
Source Data Fig. 5
FEamp-EPR data.
Source Data Extended Data Fig./Table 1
Unprocessed electrochemistry data.
Source Data Extended Data Fig./Table 2
EPR data in Excel format.
Source Data Extended Data Fig./Table 3
EPR data in Excel format.
Source Data Extended Data Fig./Table 4a
Modelling data.
Source Data Extended Data Fig./Table 4a
Modelling data.
Source Data Extended Data Fig./Table 4c
Modelling data.
Source Data Extended Data Fig./Table 6
EPR data in excel format
Source Data Extended Data Fig./Table 7a
Modelling data.
Source Data Extended Data Fig./Table 7b
Modelling data.
Source Data Extended Data Fig./Table 8
FEamp-EPR data.
Source Data Extended Data Fig./Table 9
FEamp-EPR data.
Source Data Extended Data Fig./Table 10
Modelling data.
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Seif-Eddine, M., Cobb, S.J., Dang, Y. et al. Operando film-electrochemical EPR spectroscopy tracks radical intermediates in surface-immobilized catalysts. Nat. Chem. (2024). https://doi.org/10.1038/s41557-024-01450-y
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DOI: https://doi.org/10.1038/s41557-024-01450-y