Electrode-electrolyte interactions on oxide surfaces: the crucial role of surface redox chemistry

preprint OA: closed CC-BY-4.0
📄 Open PDF Full text JSON View at publisher

Abstract

Abstract The electric double layer (EDL) formed by ions at the electrode-electrolyte interface is a fundamental component of any electrochemical system, ranging from batteries to fuel cells and electrolyzers1. At the atomic level, the behavior of the EDL varies greatly with the choice of electrode, electrolyte, and conditions2,3. However, it is thought to follow one general rule analogous to a capacitor4,5: low electrode potentials lead to a negative electrode surface charge which attracts cations to the EDL, whereas high potentials lead to a positive surface charge and anion attraction. Here, we show that this most basic rule does not apply for the oxide-electrolyte interface. Using an interface-sensitive X-ray absorption spectroscopy (XAS) approach, we show that increasing the electrode potential attracts cations and repels anions at the IrO2-electrolyte interface. We show that this behavior is driven by the surface redox chemistry of the oxide, which dictates the surface charge of the electrode by modulating the surface electrophilicity. Our findings rationalize the cation-dependent performance trends observed for oxide electrodes6–9, paving the way to exploit them in electrolyte engineering.
Full text 84,677 characters · extracted from preprint-html · click to expand
Electrode-electrolyte interactions on oxide surfaces: the crucial role of surface redox chemistry | Research Square window.SnipcartSettings = { analytics: { enabled: false } }; (function() { var accessVector = localStorage.getItem('access_vector') || ''; window.dataLayer = window.dataLayer || []; if (accessVector) { window.dataLayer.push({ user: { profile: { profileInfo: { snid: accessVector } } } }); } })(); (function(w,d,s,l,i){w[l]=w[l]||[];w[l].push({'gtm.start':new Date().getTime(),event:'gtm.js'});var f=d.getElementsByTagName(s)[0],j=d.createElement(s),dl=l!='dataLayer'?'&l='+l:'';j.async=true;j.src='https://www.googletagmanager.com/gtm.js?id='+i+dl;f.parentNode.insertBefore(j,f);})(window,document,'script','dataLayer','GTM-K279D39R'); Browse Preprints In Review Journals COVID-19 Preprints AJE Video Bytes Research Tools Research Promotion AJE Professional Editing AJE Rubriq About Preprint Platform In Review Editorial Policies Our Team Advisory Board Help Center Sign In Submit a Preprint Cite Share Download PDF Physical Sciences - Article Electrode-electrolyte interactions on oxide surfaces: the crucial role of surface redox chemistry Rik V. Mom, Nipon Deka, Denis Bernsmeier, Travis Jones, Erdem Irtem, and 5 more This is a preprint; it has not been peer reviewed by a journal. https://doi.org/ 10.21203/rs.3.rs-4886343/v1 This work is licensed under a CC BY 4.0 License Status: Posted Version 1 posted You are reading this latest preprint version Abstract The electric double layer (EDL) formed by ions at the electrode-electrolyte interface is a fundamental component of any electrochemical system, ranging from batteries to fuel cells and electrolyzers 1 . At the atomic level, the behavior of the EDL varies greatly with the choice of electrode, electrolyte, and conditions 2,3 . However, it is thought to follow one general rule analogous to a capacitor 4,5 : low electrode potentials lead to a negative electrode surface charge which attracts cations to the EDL, whereas high potentials lead to a positive surface charge and anion attraction. Here, we show that this most basic rule does not apply for the oxide-electrolyte interface. Using an interface-sensitive X-ray absorption spectroscopy (XAS) approach, we show that increasing the electrode potential attracts cations and repels anions at the IrO 2 -electrolyte interface. We show that this behavior is driven by the surface redox chemistry of the oxide, which dictates the surface charge of the electrode by modulating the surface electrophilicity. Our findings rationalize the cation-dependent performance trends observed for oxide electrodes 6–9 , paving the way to exploit them in electrolyte engineering. Physical sciences/Chemistry/Electrochemistry Physical sciences/Chemistry/Catalysis/Electrocatalysis Physical sciences/Chemistry/Surface chemistry Electrode-electrolyte interface Electric double layer (EDL) Electrocatalysis In situ X-ray absorption spectroscopy Figures Figure 1 Figure 2 Figure 3 Figure 4 Main text When a potential is applied to an electrode, this induces a surface charge, which in turn causes a re-arrangement of the ions and water molecules in the near-surface electrolyte 10 . This dynamic interfacial electrolyte structure, the EDL, is part of the reaction environment at the electrode surface and therefore has marked effect on the kinetics of electrochemical reactions. Exploiting this electrolyte effect to optimize the performance of electrocatalytic devices is challenging, however, because the relationship between the parameters that are controlled, such as the electrolyte pH and cation 11–13 /anion 14–16 composition, and the formed EDL structure is not well understood. This is particularly true for metal oxide electrodes, as here not only the interfacial electrolyte structure is highly dependent on the applied conditions, but also the surface structure of the electrode itself 17–19 . In this study, we set out to determine the impact of this dynamic surface structure on the ion-water-electrode interactions and the resulting EDL structure. To gain direct insights into the ion-water-electrode interactions at the metal oxide-electrolyte interface, we have designed an interface-sensitive electrochemical X-ray absorption spectroscopy (EC-XAS) approach (figure 1a). Sensitivity to the electrode-electrolyte interface is created by making use of: 1) a mesoporous IrO 2 electrode with an extremely high electrode-electrolyte interface area (figure 1b and section 1 in the SI) and, 2) soft-tender XAS with a probing depth smaller than the electrode thickness. In this way, only the electrolyte inside the pores is probed, which is in large part in contact with the electrode. This allows us to selectively investigate the behavior of interfacial ions through their K-edge XAS spectra. We employed this methodology to examine the interactions of Na + and ClO 4 - ions with the IrO 2 electrode in both acidic and alkaline electrolyte, and link this to the observed catalytic activity during the oxygen evolution reaction (OER). The differences in the OER activity of iridium oxide in acidic and alkaline electrolytes provide a first indication for ion-electrode interactions. Alkaline electrolytes lead to a lower OER activity (figure 1c). Furthermore, the activity in alkaline media depends on the choice of alkali metal cation (figure 1d). These observations suggest that the cations of the electrolyte interact with the OER intermediates under alkaline conditions, thereby affecting the catalytic activity. On the other hand, no cation dependent activity is observed in acidic electrolytes (figure 1e), thus showing the crucial role of the pH in the cation-IrO 2 interactions. These trends are in line with the literature 6,20,21 . In order to examine more closely how Na + ions behave in the vicinity of an electrified IrO 2 surface, we stepwise polarized our porous IrO 2 electrode in 0.1M NaOH (pH~13) and 0.1 M HClO 4 + 0.1 M NaClO 4 (pH~1) and recorded Na K-edge X-ray absorption spectra at every potential step. Since these soft XAS measurements only probe the electrolyte inside the pores, the absolute intensity of the Na K-edge allows us to track the concentration of the sodium ions inside the porous electrode. At pH 1, the Na K-edge spectrum exhibits only a weak signal, and there is no significant change in intensity when varying the potential (figure 2a). These findings indicate that at pH 1, the Na + ions are not part of the interfacial electrolyte, in line with the absence of a cation dependent OER activity as shown in figure 1e. In alkaline electrolyte, Na + ions are strongly attracted to the IrO 2 electrode, as seen from the high intensity of the Na K-edge spectra (figure 2b). Furthermore, it can be observed that the cation-IrO 2 interaction is potential-dependent. Based on the concept of capacitive charging 22–26 , the traditional view is that when the electrode potential is increased in the positive direction, positively charged cations will be repelled. However, the intensity of the Na K-edge increases when increasing the applied potential. This implies that with the increase in positive potential, more cations are attracted towards the surface. This result shows that the IrO 2 -electrolyte interface does not function as a classical capacitor, indicating that interfacial chemistry beyond basic electrostatics plays an important role in the electrode-electrolyte interactions for oxide electrodes. To obtain a more quantitative view on the Na + ions interacting with the IrO 2 surface in 0.1 M NaOH, we combined the XAS data and BET surface area analysis to calculate the approximate Na + coverage on the electrode. First, we calculated the Na + ion concentration in the porous volume of the catalyst (figure 2c, left axis), utilizing the edge jump intensity of the Na K-edge spectra (calculation in section 5 of SI). We see that the Na + ion concentration surges to 3 times the bulk concentration at around 1.0 V RHE and continues to rise at the onset of OER. By incorporating the BET surface area into our calculations, we determined the Na + coverage on the electrode (figure 2c right axis, calculation in section 5.4 of SI). At 1.4 V RHE the ion coverage reaches 0.8 Na + ion per nm 2 . Comparing this to the area occupied by a hydrated Na + ion (0.2 nm 2 ) 27 , it is clear that a significant fraction of the surface is covered. This high cation coverage near the electrode surface can be linked to the lower OER activity of IrO 2 in alkaline electrolytes: interfacial ions have been proposed to modify electrocatalytic activity through site blocking, interactions with reaction intermediates, and alteration of the interfacial water structure (water transport/pH buffering effect) 8,11,28 . To verify our conclusions from the XAS analysis, and extend them to other cations, we tracked the mass of the mesoporous electrode in situ using electrochemical quartz crystal microbalance (EQCM). When cations are attracted to the catalyst, they enter the pores and thereby contribute to the observed mass of the electrode. Such a mass increase equates to a decrease in the quartz crystal resonance frequency. In line with the XAS analysis, figure 2d shows a decrease in resonance frequency with increasingly positive potential, confirming that cations are attracted at more positive potentials. The decrease in oscillation frequency (increase in mass) is larger for heavier cations (K + , Cs + ) indicating a response based on the choice of cation. Notably, the mass change exhibits two distinct regimes, the first up to 0.6 V RHE and the second from 0.6-1.2V RHE where the latter displays a higher slope. This shows that the cation attraction accelerates at higher potentials, as also confirmed by tracking of the Na K-edge XAS intensity as a function of potential (figure S7b in SI). To probe the nature of the interaction between the cations and the IrO 2 surface in alkaline electrolytes, we analyzed the shape of the normalized Na K-edge spectra (figure 2e). In the porous volume within the catalyst layer, there are two types of Na + ions: those which reside very close to the electrode in the electric double layer and those located at a larger distance from the surface, i.e., bulk electrolyte that is not under the direct influence of the electrode surface and its electric field. A Na + ion in the bulk electrolyte can be identified by a Na K-edge spectrum with an unequal intensity ratio of the peaks at 1078.2 eV and 1081.5 eV (dark-yellow dotted spectrum in figure 2e). This spectrum represents fully hydrated Na + ions 29 . Noticeably, our operando spectra deviate from this bulk spectrum, exhibiting a higher 1078.2 eV to 1081.5 eV peak intensity ratio (blue spectra in figure 2e). This increase in peak intensity ratio of the Na K-edge spectrum is the signature of the distortion and opening of the hydration shell of the Na + ion, as shown both experimentally and theoretically 30–32 . This indicates that upon interaction with the IrO 2 surface, the Na + ions loose part of their hydration shell. Thus, the Na + ions interact directly with the oxide surface and its active OER sites, which will directly impact the stability of the catalytic intermediates. In figure 2e, it can be noted that the 1078.2 eV/1081.5 eV intensity ratio is potential dependent. In part, this can be explained by an increasing Na + concentration in the double layer at more positive potentials, because this increases the contribution of adsorbed Na + with respect to Na + in the bulk electrolyte. However, if we subtract the bulk contribution using the spectrum recorded at pH 1, which only contains the bulk contribution, there is still a steady rise in the 1078.2 eV/1081.5 eV peak intensity ratio (figure 2f and section 7 in SI). This implies that when the electrode surface becomes increasingly crowded with Na + ions at high potentials, the hydration shell of the ions is further distorted. To confirm that these strong hydration shell distortions are the result of Na + adsorption rather than Na + intercalation into the oxide lattice, we monitored the IrO 2 lattice oxygen peak at 530 eV in the O K-edge. We observed no changes as a function of time or potential, indicating that the lattice distortion/break-up required for Na + intercalation into the rutile lattice did not occur. In the following, we will show that the observed strong Na + - IrO 2 interactions and their unexpected potential dependence are intimately linked to the surface chemistry of the IrO­ 2 electrode. To investigate this surface chemistry, we recorded ­ operando O K-edge XAS spectra. The spectral range spanning 527-530 eV in the O K-edge data provides insights into the behavior of surface oxygen atoms in iridium oxide 18 . These surface oxygen atoms fall into three categories: 1) H 2 O/OH/O bound to one Ir atom at the CUS (coordinatively unsaturated sites), which we term e.g., µ 1 -OH, 2) OH/O bound to two Ir atoms at bridge sites, which we term e.g., µ 2 -OH, and 3) O atoms bound to three Ir atoms as in bulk IrO 2 , which we label µ 3 -O. Since the µ 3 -O atoms are inert 18,33 , we focus on the µ 1 - and µ 2 - groups here. These groups strongly differ in their O K-edge spectrum, as shown in previous work 18,33–35 . This can be used to explain the operando data in figure 3(a-b). The low intensity in the 527-530 eV window observed at ≤0.35 V RHE in both acidic and alkaline electrolyte is consistent with µ 1 -OH 2 , µ 1 -OH, and µ 2 -OH surface groups which display almost no intensity in this potential range. The increasing intensity at 529 eV at higher potentials can be attributed to µ 2 -O formation through the deprotonation reaction µ 2 -OH à µ 2 -O + H + + e - in acid and µ 2 -OH + OH - à µ 2 -O + H 2 O + e - in alkaline electrolyte. Above ~1.2 V RHE , a broadening towards lower excitation energies is observed, which is attributed to the formation of µ 1 -O through µ 1 -OH à µ 1 -O + H + + e - in acid and µ 1 -OH + OH - à µ 1 -O + H 2 O + e - in alkaline electrolyte. Note that due to acid-base reactions, µ 1 -O - and µ 2 -O - may also be present in alkaline electrolyte, while e.g., µ 2 -OH + might be formed in acid. This could explain the differences in observed O K-edge spectra in alkaline and acid media. The common denominator, however, is that the surface becomes strongly electrophilic due to the oxidative deprotonation of the surface -OH groups with the increase in potential. To understand the influence of the deprotonation reaction on the IrO 2 electrode at increasingly positive potential, we computed the charge on the electrode surface through DFT-RISM 36,37 calculations (details in section 9 of SI). Specifically, we compared the surface charge on a partially protonated (reduced) surface to a deprotonated surface (oxidized) in acidic and alkaline environment (figure 3c). For both electrolytes, we see that the oxidized surface possesses higher negative charge compared to the reduced surface. Based on this, we conclude that the electrophilic µ 1 -O and µ 2 -O groups at the oxidized surface attract electron density towards the surface (figure 3d). This accumulation of negative charge at the surface is compensated by ions from the electrolyte. In alkaline electrolyte, the overall process is: In agreement with the experiments, this leads to an increased interfacial Na + concentration in alkaline electrolyte. Furthermore, reaction 1 explains why the cyclic voltammogram of iridium oxides shows a super-Nernstian shift of the surface redox features when increasing the pH 20,38 (see section 8 in SI), because the number of transferred electrons (1-n) is smaller than the number of transferred protons (1). According to the calculations, the same deprotonation-induced decrease in surface charge should occur in acidic electrolyte. However, no Na + attraction is observed in the pH 1 experiments. This can be rationalized by considering the acid-base chemistry of the surface, which is not fully captured in the calculations, but was already hinted at by the O K-edge spectra. Such acid-base reactions may generate Ir-O-H + groups in acid, leading to a positive surface charge that repels the Na + ions and instead attracts ClO 4 - ions. If oxidative deprotonation makes this positively charged surface less positive at elevated potential, this should repel the ClO 4 - ions through the reaction: To test this hypothesis, we probed the concentration of perchlorate ions near the IrO 2 surface using Cl K-edge spectra 39,40 and EQCM. Indeed, we see that the Cl K-edge intensity decreases with the increase in applied potential (figure 4a). Similarly, a decrease in mass is observed in EQCM is due to the expulsion of ClO 4 - ions out of the porous electrode at increasingly positive potentials (figure 4b). This confirms our hypothesis and shows the generality of the mechanism uncovered here: whenever the oxide surface is oxidized, this will increase its electrophilicity, drawing negative charge to the surface, attracting or repelling electrolyte ions. Importantly, oxide surface redox is not particular for IrO 2 , it is widely observed for oxide materials used in electrochemistry 6,16,41–45 . Furthermore, the driving force for ion adsorption is essentially purely electrostatic (figure S11 in SI) and will therefore occur for any ion. Therefore, we expect that the surface redox effect on ion-oxide interactions is an omnipresent phenomenon in oxide electrochemistry. Declarations Acknowledgement : R.V.M. and N.D. acknowledge the Dutch Organization for Scientific Research (NWO) for funding under Grant ECCM.TT.ECCM.001. TEJ acknowledges support from the Laboratory Directed Research and Development program of Los Alamos National Laboratory under project number 20240061. Dr. H. T. acknowledges support from the German Federal Ministry of Education and Research in the framework of the project Catlab (03EW0015A/B). The Helmholtz-Zentrum Berlin für Materialien und Energie is acknowledged for the allocation of synchrotron radiation beamtime at the CAT end station of the EMIL beamline with the proposal number 231-11916. We thank Dr. Sören Selve and Dr. Leyla Kotil of TU Berlin for their assistance with TEM and XRD measurements respectively. References Stamenkovic, V. R., Strmcnik, D., Lopes, P. P. & Markovic, N. M. Energy and fuels from electrochemical interfaces. Nature Materials vol. 16 (2016). Haid, R. W., Ding, X., Sarpey, T. K., Bandarenka, A. S. & Garlyyev, B. Exploration of the electrical double-layer structure: Influence of electrolyte components on the double-layer capacitance and potential of maximum entropy. Current Opinion in Electrochemistry vol. 32 (2022). Sebastián-Pascual, P., Shao-Horn, Y. & Escudero-Escribano, M. Toward understanding the role of the electric double layer structure and electrolyte effects on well-defined interfaces for electrocatalysis. Current Opinion in Electrochemistry vol. 32 (2022). Grahame, D. C. The electrical double layer and the theory of electrocapillarity. Chem. Rev. 41 , (1947). Damaskin, B. B. & Petrii, O. A. Historical development of theories of the electrochemical double layer. Journal of Solid State Electrochemistry vol. 15 (2011). Suntivich, J., Perry, E. E., Gasteiger, H. A. & Shao-Horn, Y. The Influence of the Cation on the Oxygen Reduction and Evolution Activities of Oxide Surfaces in Alkaline Electrolyte. Electrocatalysis 4 , (2013). Tymoczko, J., Colic, V., Ganassin, A., Schuhmann, W. & Bandarenka, A. S. Influence of the alkali metal cations on the activity of Pt(1 1 1) towards model electrocatalytic reactions in acidic sulfuric media. Catal. Today 244 , (2015). Huang, J., Li, M., Eslamibidgoli, M. J., Eikerling, M. & Groß, A. Cation Overcrowding Effect on the Oxygen Evolution Reaction. JACS Au 1 , (2021). Görlin, M. et al. Key activity descriptors of nickel-iron oxygen evolution electrocatalysts in the presence of alkali metal cations. Nat. Commun. 11 , (2020). Favaro, M. et al. Unravelling the electrochemical double layer by direct probing of the solid/liquid interface. Nat. Commun. 7 , (2016). Waegele, M. M., Gunathunge, C. M., Li, J. & Li, X. How cations affect the electric double layer and the rates and selectivity of electrocatalytic processes. J. Chem. Phys. 151 , (2019). Khani, H., Puente Santiago, A. R. & He, T. An Interfacial View of Cation Effects on Electrocatalysis Systems. Angewandte Chemie - International Edition vol. 62 (2023). Qin, X., Hansen, H. A., Honkala, K. & Melander, M. M. Cation-induced changes in the inner- and outer-sphere mechanisms of electrocatalytic CO2 reduction. Nat. Commun. 14 , (2023). Kamat, G. A. et al. Acid anion electrolyte effects on platinum for oxygen and hydrogen electrocatalysis. Commun. Chem. 5 , (2022). Arminio-Ravelo, J. A., Jensen, A. W., Jensen, K. D., Quinson, J. & Escudero-Escribano, M. Electrolyte Effects on the Electrocatalytic Performance of Iridium-Based Nanoparticles for Oxygen Evolution in Rotating Disc Electrodes. ChemPhysChem 20 , (2019). Navodye, S. A. K. & Gunasooriya, G. T. K. K. Acid Electrolyte Anions Adsorption Effects on IrO2 Electrocatalysts for Oxygen Evolution Reaction. J. Phys. Chem. C 128 , 6041–6052 (2024). Deka, N. et al. On the Operando Structure of Ruthenium Oxides during the Oxygen Evolution Reaction in Acidic Media. ACS Catal. 13 , (2023). Mom, R. V. et al. Operando Structure-Activity-Stability Relationship of Iridium Oxides during the Oxygen Evolution Reaction. ACS Catal. 12 , 5174–5184 (2022). Görlin, M. et al. Oxygen evolution reaction dynamics, faradaic charge efficiency, and the active metal redox states of Ni-Fe oxide water splitting electrocatalysts. J. Am. Chem. Soc. 138 , 5603–5614 (2016). Kuo, D. Y. et al. Influence of Surface Adsorption on the Oxygen Evolution Reaction on IrO2(110). J. Am. Chem. Soc. 139 , (2017). Michael, J. D. et al. Alkaline electrolyte and fe impurity effects on the performance and active-phase structure of niooh thin films for OER catalysis applications. J. Phys. Chem. C 119 , (2015). Helmholtz, H. Ueber einige Gesetze der Vertheilung elektrischer Ströme in körperlichen Leitern mit Anwendung auf die thierisch‐elektrischen Versuche. Ann. Phys. 165 , (1853). Gouy, M. Sur la constitution de la charge électrique à la surface d’un électrolyte. J. Phys. Théorique Appliquée 9 , (1910). Chapman, D. L. LI. A contribution to the theory of electrocapillarity . London, Edinburgh, Dublin Philos. Mag. J. Sci. 25 , (1913). Stern, O. ZUR THEORIE DER ELEKTROLYTISCHEN DOPPELSCHICHT. Zeitschrift für Elektrochemie und Angew. Phys. Chemie 30 , (1924). Devanathan, M. A. V. & Tilak, B. V. K. S. R. A. The Structure of the Electrical Double Layer at the Metal-Solution Interface. Chem. Rev. 65 , (1965). Mähler, J. & Persson, I. A study of the hydration of the alkali metal ions in aqueous solution. Inorg. Chem. 51 , (2012). del Rosario, J. A. D., Li, G., Labata, M. F. M., Ocon, J. D. & Chuang, P. Y. A. Unravelling the roles of alkali-metal cations for the enhanced oxygen evolution reaction in alkaline media. Appl. Catal. B Environ. 288 , (2021). Aziz, E. F., Zimina, A., Freiwald, M., Eisebitt, S. & Eberhardt, W. Molecular and electronic structure in NaCl electrolytes of varying concentration: Identification of spectral fingerprints. J. Chem. Phys. 124 , (2006). Galib, M. et al. Revisiting the hydration structure of aqueous Na+. J. Chem. Phys. 146 , (2017). Galib, M., Schenter, G. K., Mundy, C. J., Govind, N. & Fulton, J. L. Unraveling the spectral signatures of solvent ordering in K-edge XANES of aqueous Na+. J. Chem. Phys. 149 , (2018). Aziz, E. F., Freiwald, M., Eisebitt, S. & Eberhardt, W. Steric hindrance of ion-ion interaction in electrolytes. Phys. Rev. B - Condens. Matter Mater. Phys. 73 , (2006). Frevel, L. J. et al. In situ X-ray spectroscopy of the electrochemical development of iridium nanoparticles in confined electrolyte. J. Phys. Chem. C 123 , 9146–9152 (2019). Nong, H. N. et al. Key role of chemistry versus bias in electrocatalytic oxygen evolution. Nature 587 , 408–413 (2020). Pfeifer, V. et al. In situ observation of reactive oxygen species forming on oxygen-evolving iridium surfaces. Chem. Sci. 8 , 2143–2149 (2017). Nishihara, S. & Otani, M. Hybrid solvation models for bulk, interface, and membrane: Reference interaction site methods coupled with density functional theory. Phys. Rev. B 96 , (2017). Schmickler, W. Double layer theory. J. Solid State Electrochem. 24 , (2020). Ooka, H., Yamaguchi, A., Takashima, T., Hashimoto, K. & Nakamura, R. Efficiency of Oxygen Evolution on Iridium Oxide Determined from the pH Dependence of Charge Accumulation. J. Phys. Chem. C 121 , (2017). Vaudey, C. E. et al. Chlorine speciation in nuclear graphite studied by X-ray Absorption Near Edge Structure. J. Nucl. Mater. 418 , (2011). Nakanishi, K. & Ohta, T. Verification of the FEFF simulations to K-edge XANES spectra of the third row elements. J. Phys. Condens. Matter 21 , (2009). Strmcnik, D. et al. The role of non-covalent interactions in electrocatalytic fuel-cell reactions on platinum. Nat. Chem. 1 , (2009). Stoerzinger, K. A. et al. The Role of Ru Redox in pH-Dependent Oxygen Evolution on Rutile Ruthenium Dioxide Surfaces. Chem 2 , (2017). Giordano, L. et al. PH dependence of OER activity of oxides: Current and future perspectives. Catalysis Today vol. 262 (2016). Knijff, L., Jia, M. & Zhang, C. Electric double layer at the metal-oxide/electrolyte interface. in Encyclopedia of Solid-Liquid Interfaces vols 1–3 (2023). Jia, M., Zhang, C. & Cheng, J. Origin of Asymmetric Electric Double Layers at Electrified Oxide/Electrolyte Interfaces. J. Phys. Chem. Lett. 12 , (2021). Additional Declarations There is NO Competing Interest. Supplementary Files SIProbingnearsurfaceionsiniridiumoxideV10.docx Supporting Information Cite Share Download PDF Status: Posted Version 1 posted You are reading this latest preprint version Research Square lets you share your work early, gain feedback from the community, and start making changes to your manuscript prior to peer review in a journal. As a division of Research Square Company, we’re committed to making research communication faster, fairer, and more useful. We do this by developing innovative software and high quality services for the global research community. Our growing team is made up of researchers and industry professionals working together to solve the most critical problems facing scientific publishing. Also discoverable on Platform About Our Team In Review Editorial Policies Advisory Board Help Center Resources Author Services Accessibility API Access RSS feed Manage Cookie Preferences © Research Square 2026 | ISSN 2693-5015 (online) Privacy Policy Terms of Service Do Not Sell My Personal Information {"props":{"pageProps":{"initialData":{"identity":"rs-4886343","acceptedTermsAndConditions":true,"allowDirectSubmit":true,"archivedVersions":[],"articleType":"Physical Sciences - Article","associatedPublications":[],"authors":[{"id":349659942,"identity":"3ca1de0e-63ca-45d9-abcb-4be0544f808c","order_by":0,"name":"Rik V. Mom","email":"data:image/png;base64,iVBORw0KGgoAAAANSUhEUgAAAZAAAAAyAQMAAABI0h/eAAAABlBMVEX///8AAABVwtN+AAAACXBIWXMAAA7EAAAOxAGVKw4bAAAA8klEQVRIiWNgGAWjYBADOT5mIPmAQYKxAcRNAGI+AlqM2ZjBKpG0sBHQktgGVQnRwoBHi3kDjwHTjYpt6W3szA8YEiosZPule8wePGxjyMOlReYAjwFzzpnbuW3MbAYMCWckjGfOOWNuALS0GJcWCQa2BObcNpAWHpDzJBI33Mgxk0g4A3UqHi3pbGAt/yQS9xPWwnwApCUBoqUBaIsESEsFHi3MzAcOA/1iCPLLgYRjEsYzbqSVAbVI4NbC3tj4OKfitjw//+GHDz7U1Mn2z0jeJvnDwCaxH4cWBmAMHoCxDyCJS+DSMApGwSgYBaOACAAAYBxM6/NEGFgAAAAASUVORK5CYII=","orcid":"https://orcid.org/0000-0002-5111-5591","institution":"Leiden University","correspondingAuthor":true,"prefix":"","firstName":"Rik","middleName":"V.","lastName":"Mom","suffix":""},{"id":349659943,"identity":"c9f0fbc4-e9a3-44c3-9d75-41f55e3b54c7","order_by":1,"name":"Nipon Deka","email":"","orcid":"","institution":"Leiden University","correspondingAuthor":false,"prefix":"","firstName":"Nipon","middleName":"","lastName":"Deka","suffix":""},{"id":349659944,"identity":"3c10a782-45ff-4942-976a-ecf3397c8f6a","order_by":2,"name":"Denis Bernsmeier","email":"","orcid":"","institution":"TU Berlin","correspondingAuthor":false,"prefix":"","firstName":"Denis","middleName":"","lastName":"Bernsmeier","suffix":""},{"id":349659945,"identity":"51120642-8dae-4d4b-90d6-3fe508fc8a79","order_by":3,"name":"Travis Jones","email":"","orcid":"https://orcid.org/0000-0001-8921-7641","institution":"Los Alamos National Laboratory","correspondingAuthor":false,"prefix":"","firstName":"Travis","middleName":"","lastName":"Jones","suffix":""},{"id":349659946,"identity":"1aecd231-8576-46dd-8fb3-affc4d293cc0","order_by":4,"name":"Erdem Irtem","email":"","orcid":"","institution":"VSParticle BV","correspondingAuthor":false,"prefix":"","firstName":"Erdem","middleName":"","lastName":"Irtem","suffix":""},{"id":349659947,"identity":"c85a78bd-d8ac-4f3e-9ffc-ba5b6d5ff55f","order_by":5,"name":"Hanna Trzesniowski","email":"","orcid":"","institution":"Helmholtz Zentrum Berlin","correspondingAuthor":false,"prefix":"","firstName":"Hanna","middleName":"","lastName":"Trzesniowski","suffix":""},{"id":349659948,"identity":"d66b9062-5e42-4cb7-8979-9a969e96fce8","order_by":6,"name":"Sheena Louisia","email":"","orcid":"","institution":"Leiden University","correspondingAuthor":false,"prefix":"","firstName":"Sheena","middleName":"","lastName":"Louisia","suffix":""},{"id":349659949,"identity":"eabb7a1f-9527-45fa-b2d4-fed69430dffd","order_by":7,"name":"Kees E. Kolmeier","email":"","orcid":"","institution":"Leiden Institute of Chemistry","correspondingAuthor":false,"prefix":"","firstName":"Kees","middleName":"E.","lastName":"Kolmeier","suffix":""},{"id":349659950,"identity":"f0d6d567-b01b-42b9-a801-f4c976338cd2","order_by":8,"name":"Mihaela Gorgoi","email":"","orcid":"","institution":"Helmholz Zentrum für Materialien und Energie","correspondingAuthor":false,"prefix":"","firstName":"Mihaela","middleName":"","lastName":"Gorgoi","suffix":""},{"id":349659951,"identity":"d2dfd117-87dc-4af8-be4a-6d0a27da9f6f","order_by":9,"name":"Patrick Zeller","email":"","orcid":"","institution":"Fritz Haber Institute of the Max Planck Society","correspondingAuthor":false,"prefix":"","firstName":"Patrick","middleName":"","lastName":"Zeller","suffix":""}],"badges":[],"createdAt":"2024-08-09 10:23:20","currentVersionCode":1,"declarations":"","doi":"10.21203/rs.3.rs-4886343/v1","doiUrl":"https://doi.org/10.21203/rs.3.rs-4886343/v1","draftVersion":[],"editorialEvents":[],"editorialNote":"","failedWorkflow":false,"files":[{"id":64068682,"identity":"39188a4c-260c-4deb-993b-e4ab243c6c11","added_by":"auto","created_at":"2024-09-06 06:06:01","extension":"png","order_by":1,"title":"Figure 1","display":"","copyAsset":false,"role":"figure","size":518371,"visible":true,"origin":"","legend":"\u003cp\u003e\u003cem\u003ea) Schematic of the experiment (blue and red spheres represent the iridium and oxygen atoms respectively), b) cross-section SEM micrograph of the mesoporous IrO\u003c/em\u003e\u003csub\u003e\u003cem\u003e2\u003c/em\u003e\u003c/sub\u003e\u003cem\u003e film, c-e) effect of pH, cations in alkaline, and acidic electrolytes on OER activity of IrO\u003c/em\u003e\u003csub\u003e\u003cem\u003e2\u003c/em\u003e\u003c/sub\u003e\u003cem\u003e respectively.\u003c/em\u003e\u003c/p\u003e","description":"","filename":"1.png","url":"https://assets-eu.researchsquare.com/files/rs-4886343/v1/6f4e44a708e15b132c803029.png"},{"id":64068286,"identity":"cffeb483-5fbb-48ee-a1a1-5b530b31fa34","added_by":"auto","created_at":"2024-09-06 05:58:01","extension":"png","order_by":2,"title":"Figure 2","display":"","copyAsset":false,"role":"figure","size":594099,"visible":true,"origin":"","legend":"\u003cp\u003e\u003cem\u003ea-b) Operando Na K-edge absorption spectra of Na\u003c/em\u003e\u003csup\u003e\u003cem\u003e+\u003c/em\u003e\u003c/sup\u003e\u003cem\u003e near an IrO\u003c/em\u003e\u003csub\u003e\u003cem\u003e2\u003c/em\u003e\u003c/sub\u003e\u003cem\u003e surface at pH~1 (0.1M HClO\u003c/em\u003e\u003csub\u003e\u003cem\u003e4\u003c/em\u003e\u003c/sub\u003e\u003cem\u003e+0.1M NaClO\u003c/em\u003e\u003csub\u003e\u003cem\u003e4\u003c/em\u003e\u003c/sub\u003e\u003cem\u003e) and pH~13 (0.1M NaOH). c) Calculated concentration of Na\u003c/em\u003e\u003csup\u003e\u003cem\u003e+\u003c/em\u003e\u003c/sup\u003e\u003cem\u003e in the pores and the number of Na\u003c/em\u003e\u003csup\u003e\u003cem\u003e+\u003c/em\u003e\u003c/sup\u003e\u003cem\u003e per unit area of the double layer. d) frequency response of an IrO\u003c/em\u003e\u003csub\u003e\u003cem\u003e2\u003c/em\u003e\u003c/sub\u003e\u003cem\u003e coated quartz crystal in alkaline electrolytes, e) Normalized Na K-edge spectra of Na\u003c/em\u003e\u003csup\u003e\u003cem\u003e+\u003c/em\u003e\u003c/sup\u003e\u003cem\u003e near IrO\u003c/em\u003e\u003csub\u003e\u003cem\u003e2\u003c/em\u003e\u003c/sub\u003e\u003cem\u003e surface at pH~13 (0.1M NaOH)\u003c/em\u003e\u003csub\u003e\u003cem\u003e. \u003c/em\u003e\u003c/sub\u003e\u003cem\u003ef) Variation of shoulder (1078.2 eV) to white line (1081.5 eV) intensity ratio with applied potential, g) ball model showing Na\u003c/em\u003e\u003csup\u003e\u003cem\u003e+\u003c/em\u003e\u003c/sup\u003e\u003cem\u003e adsorption at high potential.\u003c/em\u003e\u003c/p\u003e","description":"","filename":"2.png","url":"https://assets-eu.researchsquare.com/files/rs-4886343/v1/f3b9f2363fae1389a91f7171.png"},{"id":64068289,"identity":"b3641d94-e9d5-4e32-9ec9-8374e6b778a6","added_by":"auto","created_at":"2024-09-06 05:58:01","extension":"png","order_by":3,"title":"Figure 3","display":"","copyAsset":false,"role":"figure","size":289745,"visible":true,"origin":"","legend":"\u003cp\u003e\u003cem\u003ea-b) Operando O K-edge spectra of IrO\u003c/em\u003e\u003csub\u003e\u003cem\u003e2\u003c/em\u003e\u003c/sub\u003e\u003cem\u003e at pH~1 (0.1M HClO\u003c/em\u003e\u003csub\u003e\u003cem\u003e4\u003c/em\u003e\u003c/sub\u003e\u003cem\u003e+0.1M NaClO\u003c/em\u003e\u003csub\u003e\u003cem\u003e4\u003c/em\u003e\u003c/sub\u003e\u003cem\u003e) and pH~13 (0.1M NaOH) respectively. Both spectra are normalized to the edge jump at 550 eV, c) theoretically calculated charge on the surface at 1.5 V\u003c/em\u003e\u003csub\u003e\u003cem\u003eRHE\u003c/em\u003e\u003c/sub\u003e\u003cem\u003e, d) Proposed mechanism for oxidation-induced surface charging.\u003c/em\u003e\u003c/p\u003e","description":"","filename":"3.png","url":"https://assets-eu.researchsquare.com/files/rs-4886343/v1/c588001db7d470bd6ac3427a.png"},{"id":64068290,"identity":"b4985bf8-6a60-4b15-9252-870ffd247c9a","added_by":"auto","created_at":"2024-09-06 05:58:02","extension":"png","order_by":4,"title":"Figure 4","display":"","copyAsset":false,"role":"figure","size":181430,"visible":true,"origin":"","legend":"\u003cp\u003e\u003cem\u003ea) Cl K-edge XAS of ClO\u003c/em\u003e\u003csub\u003e\u003cem\u003e4\u003c/em\u003e\u003c/sub\u003e\u003csup\u003e\u003cem\u003e-\u003c/em\u003e\u003c/sup\u003e\u003cem\u003e ions near IrO\u003c/em\u003e\u003csub\u003e\u003cem\u003e2\u003c/em\u003e\u003c/sub\u003e\u003cem\u003e surface, b) EQCM in 0.1M HClO\u003c/em\u003e\u003csub\u003e\u003cem\u003e4\u003c/em\u003e\u003c/sub\u003e\u003cem\u003e+0.1M NaClO\u003c/em\u003e\u003csub\u003e\u003cem\u003e4\u003c/em\u003e\u003c/sub\u003e\u003cem\u003e.\u003c/em\u003e\u003c/p\u003e","description":"","filename":"4.png","url":"https://assets-eu.researchsquare.com/files/rs-4886343/v1/cf6d86d652b1b2631df8d091.png"},{"id":66660893,"identity":"c3c4ea51-d20e-45c1-955f-a751b4659707","added_by":"auto","created_at":"2024-10-15 08:53:19","extension":"pdf","order_by":0,"title":"","display":"","copyAsset":false,"role":"manuscript-pdf","size":2076812,"visible":true,"origin":"","legend":"","description":"","filename":"manuscript.pdf","url":"https://assets-eu.researchsquare.com/files/rs-4886343/v1/9d6dfe53-a61a-47b3-8e1b-a9d4a0ed02c6.pdf"},{"id":64068287,"identity":"8d05fb15-6fbe-40c4-8a92-f07a917eba97","added_by":"auto","created_at":"2024-09-06 05:58:01","extension":"docx","order_by":1,"title":"","display":"","copyAsset":false,"role":"supplement","size":7764204,"visible":true,"origin":"","legend":"Supporting Information","description":"","filename":"SIProbingnearsurfaceionsiniridiumoxideV10.docx","url":"https://assets-eu.researchsquare.com/files/rs-4886343/v1/90e329c9a6682ea204f9520f.docx"}],"financialInterests":"There is \u003cb\u003eNO\u003c/b\u003e Competing Interest.","formattedTitle":"Electrode-electrolyte interactions on oxide surfaces: the crucial role of surface redox chemistry","fulltext":[{"header":"Main text","content":"\u003cp\u003eWhen a potential is applied to an electrode, this induces a surface charge, which in turn causes a re-arrangement of the ions and water molecules in the near-surface electrolyte\u003csup\u003e10\u003c/sup\u003e. This dynamic interfacial electrolyte structure, the EDL, is part of the reaction environment at the electrode surface and therefore has marked effect on the kinetics of electrochemical reactions. Exploiting this electrolyte effect to optimize the performance of electrocatalytic devices is challenging, however, because the relationship between the parameters that are controlled, such as the electrolyte pH and cation\u003csup\u003e11\u0026ndash;13\u003c/sup\u003e/anion\u003csup\u003e14\u0026ndash;16\u003c/sup\u003e composition, and the formed EDL structure is not well understood. This is particularly true for metal oxide electrodes, as here not only the interfacial electrolyte structure is highly dependent on the applied conditions, but also the surface structure of the electrode itself\u003csup\u003e17\u0026ndash;19\u003c/sup\u003e. In this study, we set out to determine the impact of this dynamic surface structure on the ion-water-electrode interactions and the resulting EDL structure.\u0026nbsp;\u003c/p\u003e\n\u003cp\u003eTo gain direct insights into the ion-water-electrode interactions at the metal oxide-electrolyte interface, we have designed an interface-sensitive electrochemical X-ray absorption spectroscopy (EC-XAS) approach (figure 1a). Sensitivity to the electrode-electrolyte interface is created by making use of: 1) a mesoporous IrO\u003csub\u003e2\u003c/sub\u003e electrode with an extremely high electrode-electrolyte interface area (figure 1b and section 1 in the SI) and, 2) soft-tender XAS with a probing depth smaller than the electrode thickness. In this way, only the electrolyte inside the pores is probed, which is in large part in contact with the electrode. This allows us to selectively investigate the behavior of interfacial ions through their K-edge XAS spectra. We employed this methodology to examine the interactions of Na\u003csup\u003e+\u003c/sup\u003e and ClO\u003csub\u003e4\u003c/sub\u003e\u003csup\u003e-\u003c/sup\u003e ions with the IrO\u003csub\u003e2\u003c/sub\u003e electrode in both acidic and alkaline electrolyte, and link this to the observed catalytic activity during the oxygen evolution reaction (OER).\u003c/p\u003e\n\u003cp\u003eThe differences in the OER activity of iridium oxide in acidic and alkaline electrolytes provide a first indication for ion-electrode interactions. Alkaline electrolytes lead to a lower OER activity (figure 1c). Furthermore, the activity in alkaline media depends on the choice of alkali metal cation (figure 1d). These observations suggest that the cations of the electrolyte interact with the OER intermediates under alkaline conditions, thereby affecting the catalytic activity. On the other hand, no cation dependent activity is observed in acidic electrolytes (figure 1e), thus showing the crucial role of the pH in the cation-IrO\u003csub\u003e2\u003c/sub\u003e interactions. These trends are in line with the literature\u003csup\u003e6,20,21\u003c/sup\u003e.\u003c/p\u003e\n\u003cp\u003eIn order to examine more closely how Na\u003csup\u003e+\u003c/sup\u003e ions behave in the vicinity of an electrified IrO\u003csub\u003e2\u0026nbsp;\u003c/sub\u003esurface, we stepwise polarized our porous IrO\u003csub\u003e2\u003c/sub\u003e electrode in 0.1M NaOH (pH~13) and 0.1 M HClO\u003csub\u003e4\u003c/sub\u003e + 0.1 M NaClO\u003csub\u003e4\u003c/sub\u003e (pH~1) and recorded Na K-edge X-ray absorption spectra at every potential step. Since these soft XAS measurements only probe the electrolyte inside the pores, the absolute intensity of the Na K-edge allows us to track the concentration of the sodium ions inside the porous electrode. At pH 1, the Na K-edge spectrum exhibits only a weak signal, and there is no significant change in intensity when varying the potential (figure 2a). These findings indicate that at pH 1, the Na\u003csup\u003e+\u003c/sup\u003e ions are not part of the interfacial electrolyte, in line with the absence of a cation dependent OER activity as shown in figure 1e.\u003c/p\u003e\n\u003cp\u003eIn alkaline electrolyte, Na\u003csup\u003e+\u003c/sup\u003e ions are strongly attracted to the IrO\u003csub\u003e2\u003c/sub\u003e electrode, as seen from the high intensity of the Na K-edge spectra (figure 2b). Furthermore, it can be observed that the cation-IrO\u003csub\u003e2\u003c/sub\u003e interaction is potential-dependent. Based on the concept of capacitive charging\u003csup\u003e22\u0026ndash;26\u003c/sup\u003e, the traditional view is that when the electrode potential is increased in the positive direction, positively charged cations will be repelled. However, the intensity of the Na K-edge increases when increasing the applied potential. This implies that with the increase in positive potential, more cations are attracted towards the surface. This result shows that the IrO\u003csub\u003e2\u003c/sub\u003e-electrolyte interface does not function as a classical capacitor, indicating that interfacial chemistry beyond basic electrostatics plays an important role in the electrode-electrolyte interactions for oxide electrodes.\u0026nbsp;\u003c/p\u003e\n\u003cp\u003eTo obtain a more quantitative view on the Na\u003csup\u003e+\u003c/sup\u003e ions interacting with the IrO\u003csub\u003e2\u003c/sub\u003e surface in 0.1 M NaOH, we combined the XAS data and BET surface area analysis to calculate the approximate Na\u003csup\u003e+\u003c/sup\u003e coverage on the electrode. First, we calculated the Na\u003csup\u003e+\u003c/sup\u003e ion concentration in the porous volume of the catalyst (figure 2c, left axis), utilizing the edge jump intensity of the Na K-edge spectra (calculation in section 5 of SI). We see that the Na\u003csup\u003e+\u003c/sup\u003e ion concentration surges to 3 times the bulk concentration at around 1.0 V\u003csub\u003eRHE\u003c/sub\u003e and continues to rise at the onset of OER. By incorporating the BET surface area into our calculations, we determined the Na\u003csup\u003e+\u003c/sup\u003e coverage on the electrode (figure 2c right axis, calculation in section 5.4 of SI). At 1.4 V\u003csub\u003eRHE\u003c/sub\u003e the ion coverage reaches 0.8 Na\u003csup\u003e+\u003c/sup\u003e ion per nm\u003csup\u003e2\u003c/sup\u003e. Comparing this to the area occupied by a hydrated Na\u003csup\u003e+\u003c/sup\u003e ion (0.2 nm\u003csup\u003e2\u003c/sup\u003e)\u003csup\u003e27\u003c/sup\u003e, it is clear that a significant fraction of the surface is covered. This high cation coverage near the electrode surface can be linked to the lower OER activity of IrO\u003csub\u003e2\u003c/sub\u003e in alkaline electrolytes: interfacial ions have been proposed to modify electrocatalytic activity through site blocking, interactions with reaction intermediates, and alteration of the interfacial water structure (water transport/pH buffering effect)\u003csup\u003e8,11,28\u003c/sup\u003e.\u003c/p\u003e\n\u003cp\u003eTo verify our conclusions from the XAS analysis, and extend them to other cations, we tracked the mass of the mesoporous electrode in situ using electrochemical quartz crystal microbalance (EQCM). When cations are attracted to the catalyst, they enter the pores and thereby contribute to the observed mass of the electrode. Such a mass increase equates to a decrease in the quartz crystal resonance frequency. In line with the XAS analysis, figure 2d shows a decrease in resonance frequency with increasingly positive potential, confirming that cations are attracted at more positive potentials. The decrease in oscillation frequency (increase in mass) is larger for heavier cations (K\u003csup\u003e+\u003c/sup\u003e, Cs\u003csup\u003e+\u003c/sup\u003e) indicating a response based on the choice of cation. Notably, the mass change exhibits two distinct regimes, the first up to 0.6 V\u003csub\u003eRHE\u003c/sub\u003e and the second from 0.6-1.2V\u003csub\u003eRHE\u003c/sub\u003e where the latter displays a higher slope. This shows that the cation attraction accelerates at higher potentials, as also confirmed by tracking of the Na K-edge XAS intensity as a function of potential (figure S7b in SI).\u003c/p\u003e\n\u003cp\u003eTo probe the nature of the interaction between the cations and the IrO\u003csub\u003e2\u003c/sub\u003e surface in alkaline electrolytes, we analyzed the shape of the normalized Na K-edge spectra (figure 2e). In the porous volume within the catalyst layer, there are two types of Na\u003csup\u003e+\u003c/sup\u003e ions: those which reside very close to the electrode in the electric double layer and those located at a larger distance from the surface, i.e., bulk electrolyte that is not under the direct influence of the electrode surface and its electric field. A Na\u003csup\u003e+\u003c/sup\u003e ion in the bulk electrolyte can be identified by a Na K-edge spectrum with an unequal intensity ratio of the peaks at 1078.2 eV and 1081.5 eV (dark-yellow dotted spectrum in figure 2e). This spectrum represents fully hydrated Na\u003csup\u003e+\u003c/sup\u003e ions\u003csup\u003e29\u003c/sup\u003e. Noticeably, our operando spectra deviate from this bulk spectrum, exhibiting a higher 1078.2 eV to 1081.5 eV peak intensity ratio (blue spectra in figure 2e). This increase in peak intensity ratio of the Na K-edge spectrum is the signature of the distortion and opening of the hydration shell of the Na\u003csup\u003e+\u003c/sup\u003e ion, as shown both experimentally and theoretically\u003csup\u003e30\u0026ndash;32\u003c/sup\u003e. This indicates that upon interaction with the IrO\u003csub\u003e2\u003c/sub\u003e surface, the Na\u003csup\u003e+\u003c/sup\u003e ions loose part of their hydration shell. Thus, the Na\u003csup\u003e+\u003c/sup\u003e ions interact directly with the oxide surface and its active OER sites, which will directly impact the stability of the catalytic intermediates.\u0026nbsp;\u003c/p\u003e\n\u003cp\u003eIn figure 2e, it can be noted that the 1078.2 eV/1081.5 eV intensity ratio is potential dependent. In part, this can be explained by an increasing Na\u003csup\u003e+\u003c/sup\u003e concentration in the double layer at more positive potentials, because this increases the contribution of adsorbed Na\u003csup\u003e+\u003c/sup\u003e with respect to Na\u003csup\u003e+\u003c/sup\u003e in the bulk electrolyte. However, if we subtract the bulk contribution using the spectrum recorded at pH 1, which only contains the bulk contribution, there is still a steady rise in the 1078.2 eV/1081.5 eV peak intensity ratio (figure 2f and section 7 in SI). This implies that when the electrode surface becomes increasingly crowded with Na\u003csup\u003e+\u003c/sup\u003e ions at high potentials, the hydration shell of the ions is further distorted. To confirm that these strong hydration shell distortions are the result of Na\u003csup\u003e+\u003c/sup\u003e adsorption rather than Na\u003csup\u003e+\u003c/sup\u003e intercalation into the oxide lattice, we monitored the IrO\u003csub\u003e2\u003c/sub\u003e lattice oxygen peak at 530 eV in the O K-edge. We observed no changes as a function of time or potential, indicating that the \u0026nbsp;lattice distortion/break-up required for Na\u003csup\u003e+\u003c/sup\u003e intercalation into the rutile lattice did not occur.\u0026nbsp;\u003c/p\u003e\n\u003cp\u003e\u0026nbsp;\u003c/p\u003e\n\u003cp\u003eIn the following, we will show that the observed strong Na\u003csup\u003e+\u003c/sup\u003e- IrO\u003csub\u003e2\u003c/sub\u003e interactions and their unexpected potential dependence are intimately linked to the surface chemistry of the IrO\u0026shy;\u003csub\u003e2\u003c/sub\u003e electrode. To investigate this surface chemistry, we recorded \u0026shy;\u003cem\u003eoperando\u003c/em\u003e O K-edge XAS spectra. The spectral range spanning 527-530 eV in the O K-edge data provides insights into the behavior of surface oxygen atoms in iridium oxide\u003csup\u003e18\u003c/sup\u003e. These surface oxygen atoms fall into three categories: 1) H\u003csub\u003e2\u003c/sub\u003eO/OH/O bound to one Ir atom at the CUS (coordinatively unsaturated sites), which we term e.g.,\u0026nbsp;\u0026micro;\u003csub\u003e1\u003c/sub\u003e-OH, 2) OH/O bound to two Ir atoms at bridge sites, which we term e.g.,\u0026nbsp;\u0026micro;\u003csub\u003e2\u003c/sub\u003e-OH, and 3) O atoms bound to three Ir atoms as in bulk IrO\u003csub\u003e2\u003c/sub\u003e, which we label\u0026nbsp;\u0026micro;\u003csub\u003e3\u003c/sub\u003e-O. Since the\u0026nbsp;\u0026micro;\u003csub\u003e3\u003c/sub\u003e-O atoms are inert\u003csup\u003e18,33\u003c/sup\u003e, we focus on the\u0026nbsp;\u0026micro;\u003csub\u003e1\u003c/sub\u003e- and\u0026nbsp;\u0026micro;\u003csub\u003e2\u003c/sub\u003e- groups here. These groups strongly differ in their O K-edge spectrum, as shown in previous work\u003csup\u003e18,33\u0026ndash;35\u003c/sup\u003e. This can be used to explain the \u003cem\u003eoperando\u003c/em\u003e data in figure 3(a-b). The low intensity in the 527-530 eV window observed at \u0026le;0.35 V\u003csub\u003eRHE\u003c/sub\u003e in both acidic and alkaline electrolyte is consistent with \u0026micro;\u003csub\u003e1\u003c/sub\u003e-OH\u003csub\u003e2\u003c/sub\u003e,\u0026nbsp;\u0026micro;\u003csub\u003e1\u003c/sub\u003e-OH, and\u0026nbsp;\u0026micro;\u003csub\u003e2\u003c/sub\u003e-OH surface groups which display almost no intensity in this potential range. The increasing intensity at 529 eV at higher potentials can be attributed to\u0026nbsp;\u0026micro;\u003csub\u003e2\u003c/sub\u003e-O formation through the deprotonation reaction\u0026nbsp;\u0026micro;\u003csub\u003e2\u003c/sub\u003e-OH\u0026nbsp;\u0026agrave;\u0026nbsp;\u0026micro;\u003csub\u003e2\u003c/sub\u003e-O + H\u003csup\u003e+\u003c/sup\u003e + e\u003csup\u003e-\u003c/sup\u003e in acid and \u0026micro;\u003csub\u003e2\u003c/sub\u003e-OH + OH\u003csup\u003e-\u0026nbsp;\u003c/sup\u003e\u0026agrave;\u0026nbsp;\u0026micro;\u003csub\u003e2\u003c/sub\u003e-O + H\u003csub\u003e2\u003c/sub\u003eO + e\u003csup\u003e-\u003c/sup\u003e in alkaline electrolyte. Above ~1.2 V\u003csub\u003eRHE\u003c/sub\u003e, a broadening towards lower excitation energies is observed, which is attributed to the formation of\u0026nbsp;\u0026micro;\u003csub\u003e1\u003c/sub\u003e-O through\u0026nbsp;\u0026micro;\u003csub\u003e1\u003c/sub\u003e-OH\u0026nbsp;\u0026agrave;\u0026nbsp;\u0026micro;\u003csub\u003e1\u003c/sub\u003e-O + H\u003csup\u003e+\u003c/sup\u003e + e\u003csup\u003e-\u003c/sup\u003e in acid and \u0026micro;\u003csub\u003e1\u003c/sub\u003e-OH + OH\u003csup\u003e-\u0026nbsp;\u003c/sup\u003e\u0026agrave;\u0026nbsp;\u0026micro;\u003csub\u003e1\u003c/sub\u003e-O + H\u003csub\u003e2\u003c/sub\u003eO + e\u003csup\u003e-\u003c/sup\u003e in alkaline electrolyte. Note that due to acid-base reactions, \u0026micro;\u003csub\u003e1\u003c/sub\u003e-O\u003csup\u003e-\u003c/sup\u003e and \u0026micro;\u003csub\u003e2\u003c/sub\u003e-O\u003csup\u003e-\u003c/sup\u003e may also be present in alkaline electrolyte, while e.g., \u0026micro;\u003csub\u003e2\u003c/sub\u003e-OH\u003csup\u003e+\u003c/sup\u003e might be formed in acid. This could explain the differences in observed O K-edge spectra in alkaline and acid media. The common denominator, however, is that the surface becomes strongly electrophilic due to the oxidative deprotonation of the surface -OH groups with the increase in potential.\u003c/p\u003e\n\u003cp\u003eTo understand the influence of the deprotonation reaction on the IrO\u003csub\u003e2\u003c/sub\u003e electrode at increasingly positive potential, we computed the charge on the electrode surface through DFT-RISM\u003csup\u003e36,37\u003c/sup\u003e calculations (details in section 9 of SI). Specifically, we compared the surface charge on a partially protonated (reduced) surface to a deprotonated surface (oxidized) in acidic and alkaline environment (figure 3c). For both electrolytes, we see that the oxidized surface possesses higher negative charge compared to the reduced surface. Based on this, we conclude that the electrophilic \u0026micro;\u003csub\u003e1\u003c/sub\u003e-O and\u0026nbsp;\u0026micro;\u003csub\u003e2\u003c/sub\u003e-O groups at the oxidized surface attract electron density towards the surface (figure 3d). This accumulation of negative charge at the surface is compensated by ions from the electrolyte. In alkaline electrolyte, the overall process is:\u003c/p\u003e\n\u003cp\u003e\u003cimg src=\"data:image/png;base64,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\"\u003e\u003cbr\u003e\u003c/p\u003e\n\u003cp\u003eIn agreement with the experiments, this leads to an increased interfacial Na\u003csup\u003e+\u003c/sup\u003e concentration in alkaline electrolyte. Furthermore, reaction 1 explains why the cyclic voltammogram of iridium oxides shows a super-Nernstian shift of the surface redox features when increasing the pH\u003csup\u003e20,38\u003c/sup\u003e (see section 8 in SI), because the number of transferred electrons (1-n) is smaller than the number of transferred protons (1).\u003c/p\u003e\n\u003cp\u003eAccording to the calculations, the same deprotonation-induced decrease in surface charge should occur in acidic electrolyte. However, no Na\u003csup\u003e+\u003c/sup\u003e attraction is observed in the pH 1 experiments. This can be rationalized by considering the acid-base chemistry of the surface, which is not fully captured in the calculations, but was already hinted at by the O K-edge spectra. Such acid-base reactions may generate Ir-O-H\u003csup\u003e+\u003c/sup\u003e groups in acid, leading to a positive surface charge that repels the Na\u003csup\u003e+\u003c/sup\u003e ions and instead attracts ClO\u003csub\u003e4\u003c/sub\u003e\u003csup\u003e-\u0026nbsp;\u003c/sup\u003eions. If oxidative deprotonation makes this positively charged surface less positive at elevated potential, this should repel the ClO\u003csub\u003e4\u003c/sub\u003e\u003csup\u003e-\u003c/sup\u003e ions through the reaction:\u003c/p\u003e\n\u003cp\u003e\u003cimg src=\"data:image/png;base64,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\"\u003e\u003cbr\u003e\u003c/p\u003e\n\u003cp\u003eTo test this hypothesis, we probed the concentration of perchlorate ions near the IrO\u003csub\u003e2\u003c/sub\u003e surface using Cl K-edge spectra\u003csup\u003e39,40\u003c/sup\u003e and EQCM. Indeed, we see that the Cl K-edge intensity decreases with the increase in applied potential (figure 4a). Similarly, a decrease in mass is observed in EQCM is due to the expulsion of ClO\u003csub\u003e4\u003c/sub\u003e\u003csup\u003e-\u003c/sup\u003e ions out of the porous electrode at increasingly positive potentials (figure 4b). This confirms our hypothesis and shows the generality of the mechanism uncovered here: whenever the oxide surface is oxidized, this will increase its electrophilicity, drawing negative charge to the surface, attracting or repelling electrolyte ions. Importantly, oxide surface redox is not particular for IrO\u003csub\u003e2\u003c/sub\u003e, it is widely observed for oxide materials used in electrochemistry\u003csup\u003e6,16,41\u0026ndash;45\u003c/sup\u003e. Furthermore, the driving force for ion adsorption is essentially purely electrostatic (figure S11 in SI) and will therefore occur for any ion. Therefore, we expect that the surface redox effect on ion-oxide interactions is an omnipresent phenomenon in oxide electrochemistry.\u003c/p\u003e"},{"header":"Declarations","content":"\u003cp\u003e\u003cstrong\u003eAcknowledgement\u003c/strong\u003e: R.V.M. and N.D. acknowledge the Dutch Organization for Scientific Research (NWO) for funding under Grant ECCM.TT.ECCM.001. TEJ acknowledges support from the Laboratory Directed Research and Development program of Los Alamos National Laboratory under project number 20240061. Dr. H. T. acknowledges support from the German Federal Ministry of Education and Research in the framework of the project Catlab (03EW0015A/B). The Helmholtz-Zentrum Berlin für Materialien und Energie is acknowledged for the allocation of synchrotron radiation beamtime at the CAT end station of the EMIL beamline with the proposal number 231-11916. We thank Dr. Sören Selve and Dr. Leyla Kotil of TU Berlin for their assistance with TEM and XRD measurements respectively.\u0026nbsp;\u003c/p\u003e"},{"header":"References","content":"\u003col\u003e\n\u003cli\u003eStamenkovic, V. R., Strmcnik, D., Lopes, P. P. \u0026amp; Markovic, N. M. Energy and fuels from electrochemical interfaces. \u003cem\u003eNature Materials\u003c/em\u003e vol. 16 (2016).\u003c/li\u003e\n\u003cli\u003eHaid, R. W., Ding, X., Sarpey, T. K., Bandarenka, A. S. \u0026amp; Garlyyev, B. Exploration of the electrical double-layer structure: Influence of electrolyte components on the double-layer capacitance and potential of maximum entropy. \u003cem\u003eCurrent Opinion in Electrochemistry\u003c/em\u003e vol. 32 (2022).\u003c/li\u003e\n\u003cli\u003eSebasti\u0026aacute;n-Pascual, P., Shao-Horn, Y. \u0026amp; Escudero-Escribano, M. Toward understanding the role of the electric double layer structure and electrolyte effects on well-defined interfaces for electrocatalysis. \u003cem\u003eCurrent Opinion in Electrochemistry\u003c/em\u003e vol. 32 (2022).\u003c/li\u003e\n\u003cli\u003eGrahame, D. C. The electrical double layer and the theory of electrocapillarity. \u003cem\u003eChem. Rev.\u003c/em\u003e \u003cstrong\u003e41\u003c/strong\u003e, (1947).\u003c/li\u003e\n\u003cli\u003eDamaskin, B. B. \u0026amp; Petrii, O. A. Historical development of theories of the electrochemical double layer. \u003cem\u003eJournal of Solid State Electrochemistry\u003c/em\u003e vol. 15 (2011).\u003c/li\u003e\n\u003cli\u003eSuntivich, J., Perry, E. E., Gasteiger, H. A. \u0026amp; Shao-Horn, Y. The Influence of the Cation on the Oxygen Reduction and Evolution Activities of Oxide Surfaces in Alkaline Electrolyte. \u003cem\u003eElectrocatalysis\u003c/em\u003e \u003cstrong\u003e4\u003c/strong\u003e, (2013).\u003c/li\u003e\n\u003cli\u003eTymoczko, J., Colic, V., Ganassin, A., Schuhmann, W. \u0026amp; Bandarenka, A. S. Influence of the alkali metal cations on the activity of Pt(1 1 1) towards model electrocatalytic reactions in acidic sulfuric media. \u003cem\u003eCatal. Today\u003c/em\u003e \u003cstrong\u003e244\u003c/strong\u003e, (2015).\u003c/li\u003e\n\u003cli\u003eHuang, J., Li, M., Eslamibidgoli, M. J., Eikerling, M. \u0026amp; Gro\u0026szlig;, A. Cation Overcrowding Effect on the Oxygen Evolution Reaction. \u003cem\u003eJACS Au\u003c/em\u003e \u003cstrong\u003e1\u003c/strong\u003e, (2021).\u003c/li\u003e\n\u003cli\u003eG\u0026ouml;rlin, M. \u003cem\u003eet al.\u003c/em\u003e Key activity descriptors of nickel-iron oxygen evolution electrocatalysts in the presence of alkali metal cations. \u003cem\u003eNat. Commun.\u003c/em\u003e \u003cstrong\u003e11\u003c/strong\u003e, (2020).\u003c/li\u003e\n\u003cli\u003eFavaro, M. \u003cem\u003eet al.\u003c/em\u003e Unravelling the electrochemical double layer by direct probing of the solid/liquid interface. \u003cem\u003eNat. Commun.\u003c/em\u003e \u003cstrong\u003e7\u003c/strong\u003e, (2016).\u003c/li\u003e\n\u003cli\u003eWaegele, M. M., Gunathunge, C. M., Li, J. \u0026amp; Li, X. How cations affect the electric double layer and the rates and selectivity of electrocatalytic processes. \u003cem\u003eJ. Chem. Phys.\u003c/em\u003e \u003cstrong\u003e151\u003c/strong\u003e, (2019).\u003c/li\u003e\n\u003cli\u003eKhani, H., Puente Santiago, A. R. \u0026amp; He, T. An Interfacial View of Cation Effects on Electrocatalysis Systems. \u003cem\u003eAngewandte Chemie - International Edition\u003c/em\u003e vol. 62 (2023).\u003c/li\u003e\n\u003cli\u003eQin, X., Hansen, H. A., Honkala, K. \u0026amp; Melander, M. M. Cation-induced changes in the inner- and outer-sphere mechanisms of electrocatalytic CO2 reduction. \u003cem\u003eNat. Commun.\u003c/em\u003e \u003cstrong\u003e14\u003c/strong\u003e, (2023).\u003c/li\u003e\n\u003cli\u003eKamat, G. A. \u003cem\u003eet al.\u003c/em\u003e Acid anion electrolyte effects on platinum for oxygen and hydrogen electrocatalysis. \u003cem\u003eCommun. Chem.\u003c/em\u003e \u003cstrong\u003e5\u003c/strong\u003e, (2022).\u003c/li\u003e\n\u003cli\u003eArminio-Ravelo, J. A., Jensen, A. W., Jensen, K. D., Quinson, J. \u0026amp; Escudero-Escribano, M. Electrolyte Effects on the Electrocatalytic Performance of Iridium-Based Nanoparticles for Oxygen Evolution in Rotating Disc Electrodes. \u003cem\u003eChemPhysChem\u003c/em\u003e \u003cstrong\u003e20\u003c/strong\u003e, (2019).\u003c/li\u003e\n\u003cli\u003eNavodye, S. A. K. \u0026amp; Gunasooriya, G. T. K. K. Acid Electrolyte Anions Adsorption Effects on IrO2 Electrocatalysts for Oxygen Evolution Reaction. \u003cem\u003eJ. Phys. Chem. C\u003c/em\u003e \u003cstrong\u003e128\u003c/strong\u003e, 6041\u0026ndash;6052 (2024).\u003c/li\u003e\n\u003cli\u003eDeka, N. \u003cem\u003eet al.\u003c/em\u003e On the Operando Structure of Ruthenium Oxides during the Oxygen Evolution Reaction in Acidic Media. \u003cem\u003eACS Catal.\u003c/em\u003e \u003cstrong\u003e13\u003c/strong\u003e, (2023).\u003c/li\u003e\n\u003cli\u003eMom, R. V. \u003cem\u003eet al.\u003c/em\u003e Operando Structure-Activity-Stability Relationship of Iridium Oxides during the Oxygen Evolution Reaction. \u003cem\u003eACS Catal.\u003c/em\u003e \u003cstrong\u003e12\u003c/strong\u003e, 5174\u0026ndash;5184 (2022).\u003c/li\u003e\n\u003cli\u003eG\u0026ouml;rlin, M. \u003cem\u003eet al.\u003c/em\u003e Oxygen evolution reaction dynamics, faradaic charge efficiency, and the active metal redox states of Ni-Fe oxide water splitting electrocatalysts. \u003cem\u003eJ. Am. Chem. Soc.\u003c/em\u003e \u003cstrong\u003e138\u003c/strong\u003e, 5603\u0026ndash;5614 (2016).\u003c/li\u003e\n\u003cli\u003eKuo, D. Y. \u003cem\u003eet al.\u003c/em\u003e Influence of Surface Adsorption on the Oxygen Evolution Reaction on IrO2(110). \u003cem\u003eJ. Am. Chem. Soc.\u003c/em\u003e \u003cstrong\u003e139\u003c/strong\u003e, (2017).\u003c/li\u003e\n\u003cli\u003eMichael, J. D. \u003cem\u003eet al.\u003c/em\u003e Alkaline electrolyte and fe impurity effects on the performance and active-phase structure of niooh thin films for OER catalysis applications. \u003cem\u003eJ. Phys. Chem. C\u003c/em\u003e \u003cstrong\u003e119\u003c/strong\u003e, (2015).\u003c/li\u003e\n\u003cli\u003eHelmholtz, H. Ueber einige Gesetze der Vertheilung elektrischer Str\u0026ouml;me in k\u0026ouml;rperlichen Leitern mit Anwendung auf die thierisch‐elektrischen Versuche. \u003cem\u003eAnn. Phys.\u003c/em\u003e \u003cstrong\u003e165\u003c/strong\u003e, (1853).\u003c/li\u003e\n\u003cli\u003eGouy, M. Sur la constitution de la charge \u0026eacute;lectrique \u0026agrave; la surface d\u0026rsquo;un \u0026eacute;lectrolyte. \u003cem\u003eJ. Phys. Th\u0026eacute;orique Appliqu\u0026eacute;e\u003c/em\u003e \u003cstrong\u003e9\u003c/strong\u003e, (1910).\u003c/li\u003e\n\u003cli\u003eChapman, D. L. LI. A contribution to the theory of electrocapillarity . \u003cem\u003eLondon, Edinburgh, Dublin Philos. Mag. J. Sci.\u003c/em\u003e \u003cstrong\u003e25\u003c/strong\u003e, (1913).\u003c/li\u003e\n\u003cli\u003eStern, O. ZUR THEORIE DER ELEKTROLYTISCHEN DOPPELSCHICHT. \u003cem\u003eZeitschrift f\u0026uuml;r Elektrochemie und Angew. \u003c/em\u003e\u003cem\u003ePhys. Chemie\u003c/em\u003e \u003cstrong\u003e30\u003c/strong\u003e, (1924).\u003c/li\u003e\n\u003cli\u003eDevanathan, M. A. V. \u0026amp; Tilak, B. V. K. S. R. A. The Structure of the Electrical Double Layer at the Metal-Solution Interface. \u003cem\u003eChem. Rev.\u003c/em\u003e \u003cstrong\u003e65\u003c/strong\u003e, (1965).\u003c/li\u003e\n\u003cli\u003eM\u0026auml;hler, J. \u0026amp; Persson, I. A study of the hydration of the alkali metal ions in aqueous solution. \u003cem\u003eInorg. Chem.\u003c/em\u003e \u003cstrong\u003e51\u003c/strong\u003e, (2012).\u003c/li\u003e\n\u003cli\u003edel Rosario, J. A. D., Li, G., Labata, M. F. M., Ocon, J. D. \u0026amp; Chuang, P. Y. A. Unravelling the roles of alkali-metal cations for the enhanced oxygen evolution reaction in alkaline media. \u003cem\u003eAppl. Catal. B Environ.\u003c/em\u003e \u003cstrong\u003e288\u003c/strong\u003e, (2021).\u003c/li\u003e\n\u003cli\u003eAziz, E. F., Zimina, A., Freiwald, M., Eisebitt, S. \u0026amp; Eberhardt, W. Molecular and electronic structure in NaCl electrolytes of varying concentration: Identification of spectral fingerprints. \u003cem\u003eJ. Chem. Phys.\u003c/em\u003e \u003cstrong\u003e124\u003c/strong\u003e, (2006).\u003c/li\u003e\n\u003cli\u003eGalib, M. \u003cem\u003eet al.\u003c/em\u003e Revisiting the hydration structure of aqueous Na+. \u003cem\u003eJ. Chem. Phys.\u003c/em\u003e \u003cstrong\u003e146\u003c/strong\u003e, (2017).\u003c/li\u003e\n\u003cli\u003eGalib, M., Schenter, G. K., Mundy, C. J., Govind, N. \u0026amp; Fulton, J. L. Unraveling the spectral signatures of solvent ordering in K-edge XANES of aqueous Na+. \u003cem\u003eJ. Chem. Phys.\u003c/em\u003e \u003cstrong\u003e149\u003c/strong\u003e, (2018).\u003c/li\u003e\n\u003cli\u003eAziz, E. F., Freiwald, M., Eisebitt, S. \u0026amp; Eberhardt, W. Steric hindrance of ion-ion interaction in electrolytes. \u003cem\u003ePhys. Rev. B - Condens. Matter Mater. Phys.\u003c/em\u003e \u003cstrong\u003e73\u003c/strong\u003e, (2006).\u003c/li\u003e\n\u003cli\u003eFrevel, L. J. \u003cem\u003eet al.\u003c/em\u003e In situ X-ray spectroscopy of the electrochemical development of iridium nanoparticles in confined electrolyte. \u003cem\u003eJ. Phys. Chem. C\u003c/em\u003e \u003cstrong\u003e123\u003c/strong\u003e, 9146\u0026ndash;9152 (2019).\u003c/li\u003e\n\u003cli\u003eNong, H. N. \u003cem\u003eet al.\u003c/em\u003e Key role of chemistry versus bias in electrocatalytic oxygen evolution. \u003cem\u003eNature\u003c/em\u003e \u003cstrong\u003e587\u003c/strong\u003e, 408\u0026ndash;413 (2020).\u003c/li\u003e\n\u003cli\u003ePfeifer, V. \u003cem\u003eet al.\u003c/em\u003e In situ observation of reactive oxygen species forming on oxygen-evolving iridium surfaces. \u003cem\u003eChem. Sci.\u003c/em\u003e \u003cstrong\u003e8\u003c/strong\u003e, 2143\u0026ndash;2149 (2017).\u003c/li\u003e\n\u003cli\u003eNishihara, S. \u0026amp; Otani, M. Hybrid solvation models for bulk, interface, and membrane: Reference interaction site methods coupled with density functional theory. \u003cem\u003ePhys. Rev. B\u003c/em\u003e \u003cstrong\u003e96\u003c/strong\u003e, (2017).\u003c/li\u003e\n\u003cli\u003eSchmickler, W. Double layer theory. \u003cem\u003eJ. Solid State Electrochem.\u003c/em\u003e \u003cstrong\u003e24\u003c/strong\u003e, (2020).\u003c/li\u003e\n\u003cli\u003eOoka, H., Yamaguchi, A., Takashima, T., Hashimoto, K. \u0026amp; Nakamura, R. Efficiency of Oxygen Evolution on Iridium Oxide Determined from the pH Dependence of Charge Accumulation. \u003cem\u003eJ. Phys. Chem. C\u003c/em\u003e \u003cstrong\u003e121\u003c/strong\u003e, (2017).\u003c/li\u003e\n\u003cli\u003eVaudey, C. E. \u003cem\u003eet al.\u003c/em\u003e Chlorine speciation in nuclear graphite studied by X-ray Absorption Near Edge Structure. \u003cem\u003eJ. Nucl. Mater.\u003c/em\u003e \u003cstrong\u003e418\u003c/strong\u003e, (2011).\u003c/li\u003e\n\u003cli\u003eNakanishi, K. \u0026amp; Ohta, T. Verification of the FEFF simulations to K-edge XANES spectra of the third row elements. \u003cem\u003eJ. Phys. Condens. Matter\u003c/em\u003e \u003cstrong\u003e21\u003c/strong\u003e, (2009).\u003c/li\u003e\n\u003cli\u003eStrmcnik, D. \u003cem\u003eet al.\u003c/em\u003e The role of non-covalent interactions in electrocatalytic fuel-cell reactions on platinum. \u003cem\u003eNat. Chem.\u003c/em\u003e \u003cstrong\u003e1\u003c/strong\u003e, (2009).\u003c/li\u003e\n\u003cli\u003eStoerzinger, K. A. \u003cem\u003eet al.\u003c/em\u003e The Role of Ru Redox in pH-Dependent Oxygen Evolution on Rutile Ruthenium Dioxide Surfaces. \u003cem\u003eChem\u003c/em\u003e \u003cstrong\u003e2\u003c/strong\u003e, (2017).\u003c/li\u003e\n\u003cli\u003eGiordano, L. \u003cem\u003eet al.\u003c/em\u003e PH dependence of OER activity of oxides: Current and future perspectives. \u003cem\u003eCatalysis Today\u003c/em\u003e vol. 262 (2016).\u003c/li\u003e\n\u003cli\u003eKnijff, L., Jia, M. \u0026amp; Zhang, C. Electric double layer at the metal-oxide/electrolyte interface. in \u003cem\u003eEncyclopedia of Solid-Liquid Interfaces\u003c/em\u003e vols 1\u0026ndash;3 (2023).\u003c/li\u003e\n\u003cli\u003eJia, M., Zhang, C. \u0026amp; Cheng, J. Origin of Asymmetric Electric Double Layers at Electrified Oxide/Electrolyte Interfaces. \u003cem\u003eJ. Phys. Chem. Lett.\u003c/em\u003e \u003cstrong\u003e12\u003c/strong\u003e, (2021).\u003c/li\u003e\n\u003c/ol\u003e"}],"fulltextSource":"","fullText":"","funders":[],"hasAdminPriorityOnWorkflow":false,"hasManuscriptDocX":true,"hasOptedInToPreprint":true,"hasPassedJournalQc":"","hasAnyPriority":true,"hideJournal":true,"highlight":"","institution":"","isAcceptedByJournal":false,"isAuthorSuppliedPdf":false,"isDeskRejected":"","isHiddenFromSearch":false,"isInQc":false,"isInWorkflow":false,"isPdf":false,"isPdfUpToDate":true,"isWithdrawnOrRetracted":false,"journal":{"display":true,"email":"[email protected]","identity":"researchsquare","isNatureJournal":false,"hasQc":true,"allowDirectSubmit":true,"externalIdentity":"","sideBox":"","snPcode":"","submissionUrl":"/submission","title":"Research Square","twitterHandle":"researchsquare","acdcEnabled":true,"dfaEnabled":false,"editorialSystem":"","reportingPortfolio":"","inReviewEnabled":false,"inReviewRevisionsEnabled":true},"keywords":"Electrode-electrolyte interface, Electric double layer (EDL), Electrocatalysis, In situ X-ray absorption spectroscopy ","lastPublishedDoi":"10.21203/rs.3.rs-4886343/v1","lastPublishedDoiUrl":"https://doi.org/10.21203/rs.3.rs-4886343/v1","license":{"name":"CC BY 4.0","url":"https://creativecommons.org/licenses/by/4.0/"},"manuscriptAbstract":"\u003cp\u003eThe electric double layer (EDL) formed by ions at the electrode-electrolyte interface is a fundamental component of any electrochemical system, ranging from batteries to fuel cells and electrolyzers\u003csup\u003e1\u003c/sup\u003e. At the atomic level, the behavior of the EDL varies greatly with the choice of electrode, electrolyte, and conditions\u003csup\u003e2,3\u003c/sup\u003e. However, it is thought to follow one general rule analogous to a capacitor\u003csup\u003e4,5\u003c/sup\u003e: low electrode potentials lead to a negative electrode surface charge which attracts cations to the EDL, whereas high potentials lead to a positive surface charge and anion attraction. Here, we show that this most basic rule does not apply for the oxide-electrolyte interface. Using an interface-sensitive X-ray absorption spectroscopy (XAS) approach, we show that increasing the electrode potential attracts cations and repels anions at the IrO\u003csub\u003e2\u003c/sub\u003e-electrolyte interface. We show that this behavior is driven by the surface redox chemistry of the oxide, which dictates the surface charge of the electrode by modulating the surface electrophilicity. Our findings rationalize the cation-dependent performance trends observed for oxide electrodes\u003csup\u003e6–9\u003c/sup\u003e, paving the way to exploit them in electrolyte engineering.\u003c/p\u003e","manuscriptTitle":"Electrode-electrolyte interactions on oxide surfaces: the crucial role of surface redox chemistry","msid":"","msnumber":"","nonDraftVersions":[{"code":1,"date":"2024-09-06 05:57:56","doi":"10.21203/rs.3.rs-4886343/v1","editorialEvents":[{"type":"communityComments","content":0}],"status":"published","journal":{"display":true,"email":"[email protected]","identity":"researchsquare","isNatureJournal":false,"hasQc":true,"allowDirectSubmit":true,"externalIdentity":"","sideBox":"","snPcode":"","submissionUrl":"/submission","title":"Research Square","twitterHandle":"researchsquare","acdcEnabled":true,"dfaEnabled":false,"editorialSystem":"","reportingPortfolio":"","inReviewEnabled":false,"inReviewRevisionsEnabled":true}}],"origin":"","ownerIdentity":"887d3c8e-c11f-494d-9d2d-2732e746015a","owner":[],"postedDate":"September 6th, 2024","published":true,"recentEditorialEvents":[],"rejectedJournal":[],"revision":"","amendment":"","status":"posted","subjectAreas":[{"id":37114557,"name":"Physical sciences/Chemistry/Electrochemistry"},{"id":37114558,"name":"Physical sciences/Chemistry/Catalysis/Electrocatalysis"},{"id":37114559,"name":"Physical sciences/Chemistry/Surface chemistry"}],"tags":[],"updatedAt":"2024-10-15T08:45:11+00:00","versionOfRecord":[],"versionCreatedAt":"2024-09-06 05:57:56","video":"","vorDoi":"","vorDoiUrl":"","workflowStages":[]},"version":"v1","identity":"rs-4886343","journalConfig":"researchsquare"},"__N_SSP":true},"page":"/article/[identity]/[[...version]]","query":{"redirect":"/article/rs-4886343","identity":"rs-4886343","version":["v1"]},"buildId":"qtupq5eGEP_6zYnWcrvyt","isFallback":false,"isExperimentalCompile":false,"dynamicIds":[84888],"gssp":true,"scriptLoader":[]}

Text is read by the "Ask this paper" AI Q&A widget below. Extraction quality varies by source — PMC NXML preserves structure cleanly, OA-HTML may include some navigation residue, and OA-PDF can have broken hyphenation. The publisher copy (via DOI) is the canonical version.

My notes (saved in your browser only)

Ask this paper AI returns verbatim quotes from the full text · source: preprint-html

Answers must be backed by verbatim quotes from this paper's full text. Hallucinated quotes are dropped automatically; if no verbatim passage answers the question, we say so. How this works

Citation neighborhood (no data yet)

We don't have any in-corpus citations linked to this paper yet. This is a recent paper (2024) — citers typically take a year or two to land, and the OpenAlex reference graph may still be filling in.

Source provenance

europepmc
last seen: 2026-05-20T01:45:00.602351+00:00
unpaywall
last seen: 2026-05-28T02:00:01.590549+00:00
License: CC-BY-4.0