Abstract
Oxygen evolution reaction (OER) is critical to renewable energy conversion technologies, but the structure-activity relationships and underlying catalytic mechanisms in catalysts are not fully understood. We herein demonstrate a strategy to promote OER with simultaneously achieved lattice oxygen activation and enhanced local electric field by dual doping of cations and anions. Rough arrays of Fe and F co-doped CoO nanoneedles are constructed, and a low overpotential of 277 mV at 500 mA cm−2 is achieved. The dually doped Fe and F could cooperatively tailor the electronic properties of CoO, leading to improved metal-oxygen covalency and stimulated lattice oxygen activation. Particularly, Fe doping induces a synergetic effect of tip enhancement and proximity effect, which effectively concentrates OH− ions, optimizes reaction energy barrier and promotes O2 desorption. This work demonstrates a conceptual strategy to couple lattice oxygen and local electric field for effective electrocatalytic water oxidation.
Similar content being viewed by others
Introduction
Electrochemical water splitting coupling of anodic oxygen evolution reaction (OER) and cathodic hydrogen evolution reaction (HER), represents a promising technology for sustainable hydrogen generation to relieve energy and environmental crisis1,2. In comparison with the cathodic HER, the OER process suffering from more sluggish kinetics and a larger overpotential is identified as the major bottleneck of water electrolysis3,4,5. Various strategies such as single-atom engineering6,7,8, defect regulation9,10, lattice doping11,12, built-in electric field construction13,14, and surface modification15,16, have been implemented to expedite the electron transfer process for OER. Nevertheless, the performance of the OER catalysts still cannot match that of HER, thus critically restricting their industrial applications. Gaining profound insight into the catalytic mechanism, and comprehending the correlation between the physicochemical structure of electrocatalysts and electrochemical behaviors, are of great significance to the development of highly reactive and durable OER catalysts.
At present, two typical kinds of recognized OER mechanisms that have a necessary connection with the redox metal cations or the lattice oxygen centers are proposed, which are named the adsorbate evolution mechanism (AEM) and the lattice oxygen oxidation mechanism (LOM), respectively17. However, as for the AEM, different oxygen intermediates including OH*, O*, and OOH* are involved, rendering a theoretically limiting overpotential to 370 mV18,19. Different from the AEM, the LOM undergoes an OH−, O22−, and O2 formation pathway, which can expedite the direct coupling of lattice oxygen to bypass the limiting energy barrier of OOH* formation in the AEM process20,21,22. As a consequence, the LOM provides an appealing avenue to boost the activity of OER electrocatalysts, such as perovskite20, multimetallic alloy23, and bimetallic (oxy)hydroxide24. Nevertheless, the switching from AEM to LOM is difficult to realize because the lattice oxygen activation is unfavorable in thermodynamics, and may typically requires a strong covalency of the transition metal-oxygen bond20,25. Hence, accurate adjustment of the electronic states of metal cations and oxygen ligands simultaneously for steering high metal-oxygen covalency is desired to heighten the intrinsic OER performance.
Importantly, the reactive rate of OER catalysts via LOM is still limited by mass transfer to the electrode surface, especially at industrial current densities (generally, >200 mA cm−2)26. Numerous researches have verified that high-curvature nanomaterials can effectively promote efficiency and improve current density in different electrocatalytic reactions, such as electrocatalytic CO2 reduction27,28, alkyne semihydrogenation29, OER30, and HER31,32. It has been found that high-curvature nanostructures with a sharp-tip enhancement can introduce a large local electric field for concentrating electrolyte ions or aggregating reactants on the tip surface, which may simultaneously lower the reaction energy barrier and enable fast mass transfer to the active sites27,32,33. Nevertheless, the effect of tip-enhanced electric field on OER such as reaction intermediate formation and O2 gas release has rarely been explored.
Taking the above considerations, a fascinating OER electrocatalyst should possess the features to regulate lattice oxygen redox chemistry for accommodating the LOM route by tailoring metal cations and oxygen ligands simultaneously, and also has abundant high-curvature sites to facilitate the mass transfer, which can cooperatively improve the electrocatalytic activity. However, how to integrate the two precisely is challenging and rarely reported. More importantly, a clear-cut explanation of the synergetic workings of lattice oxygen activation and local electric field enhancement as well as their interplay on electrocatalytic performance, has yet to be established.
In this study, we report a facile cation and anion dual doping strategy for simultaneous realization of lattice oxygen activation and local electric field enhancement to promote OER. Considering the similar size compatibility of Fe and Co, F and O, and the large electronegativity of F (x = 3.98)34,35, well-architected Fe and F co-doped CoO nanoneedle arrays (Fe, F-CoO NNAs) with a rather rough surface are constructed, and a low overpotential of 169 mV at the current density of 10 mA cm−2 is achieved, which is among the best results reported so far. Significantly, the Fe, F-CoO NNAs catalyst only requires the overpotentials of 234 mV and 277 mV to deliver large current densities of 100 and 500 mA cm−2, respectively. Combining experimental results and theoretical calculations, it can be further confirmed that dual doping of Fe and F jointly upshifts Co d-band center (εd) and O 2p band around the Fermi level (Ef), improves the covalency of the metal-oxygen band as well as activates lattice oxygen, thus facilitating the electron transfer and awakening the LOM pathway. Additionally, finite element simulations and density functional theory (DFT) in conjunction with in situ optical microscope reveal that Fe doping significantly increases the local charge density through coupling sharp tip enhancement and proximity effect, which concentrates more OH− ions, optimizes the reaction energy barrier of LOM pathway, and promotes O2 bubble release. Correspondingly, the thermodynamics and kinetics barriers for OER are reduced simultaneously, leading to boosted electrocatalytic performance. These results endow the multi-scale regulation strategy of integrating lattice oxygen activation and local electric field enhancement with great potential in industrial electrocatalytic water oxidation.
Results and discussion
Synthesis and characterization of catalysts
The preparation of Fe, F-CoO NNAs through a facile cation and anion dual doping method is schematically illustrated in Fig. 1a. Uniform Co(OH)F NNAs were in-situ grown on Ni foam (NF) by a facile hydrothermal method, which can be transformed into Fe, F-CoO NNAs through sequential immersion in K3[Fe(CN)6] solution and annealing procedures. Notably, Fe and F atoms could be easily substituted into the CoO lattices due to their similar atomic sizes with Co and O, respectively. To facilitate comparison, CoO NNAs, Fe-doped CoO NNAs (Fe-CoO NNAs), and F-doped CoO NNAs (F-CoO NNAs) were also prepared using the similar strategy as Fe, F-CoO NNAs.
Field emission scanning electron microscopy (FESEM) shows that the as-prepared Co(OH)F precursor displays a smooth nanoneedle structure with a base diameter of ~150 nm (Supplementary Fig. 1). After K3[Fe(CN)6] treatment, the crystal phase and the nanoneedle structure of Co(OH)F are almost maintained (Supplementary Fig. 2). After annealing treatment, arrays of Fe and F co-doped CoO nanoneedles are constructed, which have a rather rough surface (Fig. 1b, c). This may be due to Fe doping, leading to more structural defects in Fe, F-CoO NNAs36. Energy dispersive spectroscopy (EDS) results confirm the successful doping of Fe and F in the Fe, F-CoO NNAs, with atomic contents of 0.6% and 11.3%, respectively (Supplementary Fig. 3). The effect of Fe doping on the rough surface is further verified by the enhanced surface roughness of Fe, F-CoO NNAs with the increase of Fe dopant (Supplementary Fig. 4). From FESEM images (Supplementary Fig. 5), the morphologies of the CoO, Fe-CoO, and F-CoO NNAs all exhibit a similar needle-shaped structure but have a smooth or rough surface, depending on whether Fe is doped or not. Powder X-ray diffraction (XRD) patterns show no impurities except for cubic phase CoO (JCPDS No. 04-003-2614), suggesting that Fe and F atoms substitute Co and O atoms, respectively (Supplementary Fig. 6). Note that the positions of the main peaks have no significant changes for all the doped samples, which may be ascribed to the similar ion radius (Fe3+ (0.645 Å) vs. Co2+ (0.65 Å), and F− (1.33 Å) vs. O2− (1.40 Å)) and the low concentration of Fe3+. While the intensities of the peaks reduce after F doping, which is probably due to the relatively higher content of F. Four vibrational peaks are observed in the Raman spectra, which can be assigned to the F2g (186 cm−1), Eg (458 cm−1) and A1g (656 cm−1) modes of Co2+−O coordination, and the F2g (541 cm−1) mode of Co3+−O band (Supplementary Fig. 7)37. Detailed analysis by transmission electron microscopy (TEM) also confirms the nanosized needle-shaped morphology of Fe, F-CoO NNAs with a rather rough surface, which is in agreement with the SEM images (Fig. 1d). The lattice fringes with the spacings of 0.244 nm and 0.211 nm are observed in the high-resolution TEM (HRTEM) images, which can be attributed to the (111) and (200) planes of cubic CoO, respectively (Fig. 1e). Additionally, the selected area electron diffraction (SAED) pattern only reveals the diffraction fringes of CoO, which is consistent with the result of XRD pattern (Fig. 1f). Elemental mapping images further prove the homogeneous distribution of Co, O, Fe, and F elements throughout the nanoneedle, manifesting the successful formation of Fe, F-CoO NNAs (Fig. 1g).
To investigate the electronic structure of Fe, F-CoO NNAs, X-ray photoelectron spectroscopy (XPS) was further conducted. The XPS survey spectrum confirms the presence of Co, Fe, F, and O elements in Fe, F-CoO NNAs (Supplementary Fig. 8). The Fe 2p XPS spectra of Fe, F-CoO NNAs and Fe-CoO NNAs display the Fe 2p1/2 and Fe 2p3/2 peaks centered at 712.4 eV and 724.5 eV, respectively, verifying the existence of Fe3+ ions (Supplementary Fig. 9a)38. The F 1 s profiles also confirm the Co−F bond in Fe, F-CoO NNAs and F-CoO NNAs (Supplementary Fig. 9b)39. The Co 2p XPS spectra can be deconvoluted into two spin-orbit doublets at 780.5/796.3 eV of Co3+ and 782.7/797.7 eV of Co2+ with two shake-up satellites40. The existence of Co3+ ions might be derived from Co2+ oxidation when exposed to air41. Notably, the Co 2p spectrum of Fe, F-CoO NNAs is negatively shifted to lower energy compared to CoO NNAs, indicating the electronic rich state (Supplementary Fig. 9c). The Co 2p spectrum of Fe, F-CoO NNAs is located between Fe-CoO NNAs and F-CoO NNAs, illustrating that the Fe and F dopants might act as electronic donors and electronic acceptors, respectively, and jointly change the electronic structure of CoO. The O 1s spectra show three oxygen species including lattice-O, adsorbed-O or hydroxyl (–OH), and adsorbed H2O (Fig. 1h). In particular, the peaks of lattice-O for the Fe-CoO NNAs, F-CoO NNAs, and Fe, F-CoO NNAs all reveal a positive shift relative to that of CoO NNAs, unveiling a higher electron-cloud density and higher lattice oxygen activity in the doped CoO samples42. Moreover, among the four samples, the largest content of lattice oxygen is obtained in Fe, F-CoO NNAs, which may benefit the OER process (Supplementary Table 1)43.
The electronic and chemical coordination structures of the catalysts were further explored using X-ray absorption spectroscopy (XAS). Figure 2a presents the O K-edge spectra of the CoO NNAs, F-CoO NNAs and Fe, F-CoO NNAs, in which the O K-edge pre-edge peak centered at 532 eV is attributed to the hybridization of O 2p-state with the Co 3d. As described, the O K-edge pre-peak almost disappears for F-CoO NNAs, suggesting that oxygen release occurs with F doping. It is notable that compared with CoO NNAs, Fe, F-CoO NNAs present a more intense pre-edge peak, suggesting the strengthened metal-oxygen covalency44,45. This result is consistent with those from O 1s XPS spectra. The Co K-edge X-ray absorption near edge structure (XANES) spectra show that the absorption edges of the three samples are located between standard CoO and Co2O3, manifesting the valence state of Co between +2 and +3 (Fig. 2b). A shift to lower energies is observed for Fe, F-CoO NNAs compared to CoO NNAs, suggesting the lower Co valence. The Fourier-transformed extended X-ray absorption fine structure (FT-EXAFS) spectra of Co K-edge reveal two shells at ~1.4 and ~2.4 Å, corresponding to the Co−O and Co−Co scattering paths, respectively (Fig. 2c). The almost overlapped Co K-edge oscillation plots and the similar distances of Co−O and Co−Co in un-doped and doped samples indicate that the incorporation of Fe and F does not cause significant structural changes in CoO (Supplementary Figs. 10, 11, Supplementary Table 2). This is further confirmed by the similar wavelet transform (WT) plots (Fig. 2d–i), agreeing well with the observations from XRD and Raman.
Electrocatalytic OER performance
The OER activity of Fe, F-CoO NNAs was evaluated in 1 M KOH electrolytes using a conventional three-electrode system, with CoO NNAs, F-CoO NNAs, and Fe-CoO NNAs for comparison. Linear sweep voltammetry (LSV) curves evidence the best OER performance of the Fe, F-CoO NNAs with the lowest overpotential among all the samples (Fig. 3a, Supplementary Fig. 12). As shown, the Fe, F-CoO NNAs only require an overpotential of 169 mV at the evaluation metrics of 10 mA cm−2, surpassing those of F-CoO NNAs (213 mV), Fe-CoO NNAs (220 mV), CoO NNAs (304 mV), commercial IrO2 (294 mV) (Fig. 3b). Notably, to deliver large current densities of 100 mA cm−2 and 500 mA cm−2, extremely low overpotentials of 234 mV and 277 mV are achieved for the Fe, F-CoO NNAs, respectively, which are superior to those of the comparisons. Also, the distinguished OER performance of Fe, F-CoO NNAs is revealed by the lower Tafel slope of 41.6 mV dec−1 compared to those of F-CoO NNAs (55.8 mV dec−1), Fe-CoO NNAs (60.1 mV dec−1), and CoO NNAs (74.7 mV dec−1), implying the faster OER kinetics (Fig. 3c). The corresponding Tafel slopes and overpotentials are comparable to those of the state-of-the-art transition metal-based OER electrocatalysts (Fig. 3d & Supplementary Tables 3,4). Besides, the real-time potential of Fe, F-CoO NNAs hardly increases during the continuous testing for 300 h at large current densities of 100 mA cm−2 and 500 mA cm−2 (Fig. 3e). This result is also comparable or even superior to most transition metal-based OER electrocatalysts (Supplementary Table 5). The robust durability is also verified with the LSV curves (Supplementary Fig. 13). FESEM and XRD further demonstrate that the morphology and crystal structure show negligible changes after the cycling test, suggesting their robust stability and great potential in practical applications (Supplementary Fig. 14).
Furthermore, the intrinsic activities of the as-prepared electrocatalysts were evaluated by normalizing the LSV curves with the electrochemical active surface area (ECSA) to exclude the effect of geometric structure. Fe, F-CoO NNAs obtain the largest electrical double-layer capacitance (Cdl) of 6.46 mF cm−2, corresponding to an ECSA of 81 cm2 (Supplementary Figs. 15, 16). Besides, in contrast to F-CoO NNAs, Fe-CoO NNAs, and CoO NNAs, the Fe, F-CoO NNAs exhibit a more favorable intrinsic activity as demonstrated by the higher ECSA-normalized current densities (Supplementary Fig. 17). In particular, for Fe, F-CoO NNAs, the ECSA-normalized current density can reach 4.41 mA cm−2 at an overpotential of 300 mV, which is about 1.9 times of F-CoO NNAs (2.37 mA cm−2), and even 6.7 times and 17.6 times greater than Fe-CoO NNAs (0.66 mA cm−2) and CoO NNAs (0.25 mA cm−2), respectively (Fig. 3f). The above results further verify that the intrinsic electrocatalytic activity of CoO is boosted by Fe, F dual doping.
Kinetic study
Afterward, the kinetic processes, with regard to the electron transport and the adsorption/desorption of reactants on the electrode surface, were studied by electrochemical impedance spectroscopy (EIS). Nyquist plots manifest that the charge transfer resistance (Rct) of Fe, F-CoO NNAs is significantly smaller than those of F-CoO NNAs, Fe-CoO NNAs, and CoO NNAs, indicating the faster charge transfer rate and accelerated electrocatalytic kinetics (Supplementary Fig. 18, Supplementary Table 6)46. Operando EIS was carried out to better expound the reaction kinetics during the oxygen evolution process. As depicted, the electronic transfer and the adsorption of reactants processes are markedly facilitated with the increase of voltage, contributing to faster OER kinetics (Fig. 3g and Supplementary Fig. 19)47. Besides, the relatively small phase angles in the low-frequency region of Bode phase plots represent rapid electron transport inside the electrodes, while the swiftly descending of the phase angles in the high-frequency regions implies the accelerated interface reaction during the electrocatalytic process (Supplementary Fig. 20)48. Fe, F-CoO NNAs exhibit lower phase angles in comparison with those of F-CoO NNAs, Fe-CoO NNAs and CoO NNAs, confirming a more active interface (Fig. 3h). From the above results, we can deduce that Fe, F dual doping effectively enhance the intrinsic OER activity of CoO and promote the interfacial charge/electron transfer at the electrode interface, thus promoting the OER process.
Exploration of reaction mechanism
Given the high OER activity of the Fe, F-CoO NNAs, the pH dependence on OER activities was also investigated, which can provide insights into the reaction mechanism. As profiled in Supplementary Fig. 21, the current densities of the Fe, F-CoO NNAs increase steeply with the increase of pH from 12.5 to 14.0, suggesting a nonconcerted proton-electron transfer pathway21. The pH dependence is closely related to the proton reaction order (ρ), namely, Fe, F-CoO NNAs (0.98) > F-CoO NNAs (0.95) > Fe-CoO NNAs (0.80) > CoO NNAs (0.65) (Fig. 4a). Generally, a ρ value close to 1 manifests a preferential LOM, and therefore Fe, F-CoO NNAs and F-CoO NNAs may undergo the LOM pathway49. Besides, the strongest pH-dependent behavior of Fe, F-CoO NNAs evidences that the lattice oxygen redox chemistry of CoO can be activated most effectively through Fe and F dual substitution24. To verify the LOM mechanism, tetramethylammonium cation (TMA+) is adopted as a chemical probe of negatively charged peroxo/superoxo-like (O22−/O2−) intermediates due to their strong electrostatic interactions (Fig. 4b)21,24. Distinctly, the current density of Fe, F-CoO NNAs declines significantly in 1 M TMAOH with the largest reduction factor of 90.7% at 1.55 V among the samples, reflecting that the LOM process in Fe, F-CoO NNAs is severely hindered by TMA+ (Fig. 4c). In contrast, Fe-CoO NNAs and CoO NNAs both show incredibly tiny fractional variations in OER activity and kinetics, indicting the preferred AEM process in these two catalysts (Supplementary Fig. 22). These results were directly demonstrated with Raman spectra, in which the typical peaks of TMA+ at 753 cm−1 and 953 cm−1 are observed for Fe, F-CoO NNAs and F-CoO NNAs, but absent for Fe-CoO NNAs and CoO NNAs (Supplementary Fig. 23)24. The above analyses prove that the OER mechanism switches from AEM to LOM after F doping, and more importantly, Fe and F dual doping is more favorable for the LOM pathway in contrast with other single-doped CoO catalysts. Furthermore, in situ surface-enhanced Raman spectroscopy was carried out to gain a deeper insight into the active sites of Fe, F-CoO NNAs. As shown in Fig. 4d, three spectral features of CoO, assigned to the Eg vibration mode of Co (II) − O, F2g mode of Co (III) − O band, and A1g of Co (II) − O band, are observed at around 473, 544, and 691 cm−1 at 1.23 V37,50. Notably, when the potential is elevated to 1.33 V, the two peaks of Co (II) − O coordination at 473 and 691 cm−1 attenuate slightly, while the intensity of Co (III) − O peak increases significantly. And this phenomenon is more evident with the further increased potential, suggesting more Co (II) is transformed into Co (III) species. This may be because the low-valence metal sites can be spontaneously and rapidly oxidized by alkaline electrolytes, which is believed favorable for activating lattice oxygen43,51. Moreover, a broad feature in the range of 900 ~ 1200 cm−1 gradually appears in the surface-enhanced Raman spectra at 1.33 V and above, with a zenith at around ~1020 cm−1, which is assigned to a surface superoxol-like species (OO−) that are often recognized as the active oxygen species of LOM24,43,52.
Due to the isotope effect, the LOM pathway was further identified by coupling oxygen isotope with electrochemical in situ Raman spectroscopy. A three-step strategy is adopted for the oxygen isotope labeling experiments (Fig. 4e)53. First, the as-prepared Fe, F-CoO NNAs are labeled in 0.1 M KOH H218O aqueous solution (denoted as 18O-KOH) with a chronoamperometry method for 20 min at 1.664 V versus RHE. As indicated in Supplementary Fig. 24, the F2g and A1g peaks of the Co−O band both shift to lower frequencies, indicating the successful labeling of lattice oxygen with 18O in Fe, F-CoO NNAs25,53. Subsequently, the 18O-labeled Fe, F-CoO NNAs (denoted as Fe, F-Co18O NNAs) sample was transferred into 0.1 M KOH-H216O (16O-KOH) aqueous solution and finally, Raman spectra were in situ collected in 16O-KOH electrolytes. Raman spectra reveal that the peaks of F2g mode of Co−O band and OO− band gradually moved toward higher frequencies with the elevated potentials, demonstrating that the lattice oxygen of Fe, F-CoO NNAs can exchange with the electrolyte and get involved in the OER process (Fig. 4f). Furthermore, 18O isotope technology combined with on-line differential electrochemical mass spectrometry (DEMS) was used to detect O2 gas generated during the OER. As shown in Fig. 4g, the signals for mass-to-charge ratio (m/z) of 32 and 34, corresponding to 32O2 (16O16O) and 34O2 (16O18O), respectively, are detected for Fe, F-Co18O NNAs, confirming the involvement of lattice oxygen in the OER. These observations provide more compelling evidence for the LOM mechanism.
Theoretical insights into reaction mechanism
To elucidate the origins of the different electrochemical behaviors of doped CoO, and also clarify the impacts of Fe and F dual doping on electronic structure and reaction mechanism, theoretical studies were elaborately performed based on DFT calculations. The CoO (200) slabs with Fe and/or F atoms situated on the top sites were chosen as the computational models for three reasons (Supplementary Fig. 25). First, the (200) atomic layer is stable and usually chosen for theoretical calculations in most works. Second, HRTEM and XRD reveal that the CoO (200) are the exposed active surfaces. Third, the segregation energy (Eseg) for Fe and F dopants in the CoO (200) surface, which is defined as the total energy difference of the CoO slab with dopant in the first layer and sub-layer (bulk), are −1.94 eV and 0.79 eV, respectively (Supplementary Fig. 26)54. This result indicates that Fe prefers to dope in the surface and F can dope in the surface and bulk, consistent well with the XPS and EDS mapping results. Moreover, it is believed that electrochemical reactions often occur at the oxide surface and only the surface allows the formation of O–O bonds because of the low flexibility55. Therefore, the CoO models with Fe and F atoms situated on the top site were constructed. As illustrated in the 3d orbital partial density of states (PDOS) of the Co atom (the active site), compared with pure CoO slab, Fe doping can apparently upshift the εd of the Co atom approaching the Ef, while the F atom has little impact on the Co 3d orbital (Fig. 5a). More importantly, the Co atom in Fe, F-CoO slab obtains the highest εd of −3.34 eV among the four models, which effectively strengthens the interaction between electrocatalysts and oxygen intermediates owing to the synergistic effect of Fe and F heteroatoms56. From the 2p orbital PDOS of the active O atom, unoccupied oxygen states (shaded portion) above the Ef are observed after the incorporation of F, allowing more electrons of oxygen intermediates to enter (Fig. 5b). It should be noted that the single Fe dopant has negligible influence on the increased O 2p states around the Ef. Compared to the other doped CoO slabs, the higher energy level of the O 2p band for Fe, F co-doped slab, closer to Ef, indicates a higher oxygen ion mobility, which may favor the oxygen vacancy formation and OH– absorption57. The synergistic effect of Fe and F atoms on the electronic structure can also be verified from the calculated PDOS of Co 3d, O 2p, and Fe 3d orbits. As depicted in Fig. 5c, substantial overlaps are found in the Co 3d, O 2p, and Fe 3d orbits of Fe, F-CoO, suggesting a strong interaction between Co and Fe atoms as well as a covalent hybridization between Co sites and the oxygen ligands. Additionally, the introduction of Fe and F causes more unoccupied metal-oxygen bands to enter above Ef (shaded portion), indicating a stronger metal-oxygen covalency in Fe, F-CoO (Fig. 5c and d)43. The covalent characteristic can also be quantitatively studied by electronic localization function (ELF) analysis, in which the electronic locality is reduced after Fe, F dual substitution, indicating a strengthened covalent character of metal-oxygen bond (Fig. 5e–g)58. In addition, non-bonding oxygen states are usually recognized as crucial for lattice oxygen oxidation. For CoO and Fe-CoO, there is one kind of oxygen: O1, O-M-O (M=Co, Fe). For F-CoO and Fe, F-CoO, there are two kinds of oxygen: O1, O-M-O and O2, O-M-F (M=Co, Fe). As shown in Supplementary Fig. 27, large amounts of high-energy non-bonding oxygen states are generated, which are associated with the O2 bonding environment. High metal-oxygen covalency and the existence of non-bonding oxygen states both are beneficial for triggering lattice oxygen to participate in the OER process and promoting the facile electron transfer between metal and oxygen intermediates (O22–/O2–), thereby enhancing the OER kinetics24,43,59.
The oxygen evolution processes on the different configurations and the Gibbs free energy for the evolution of different intermediates in both the AEM and the LOM pathways were further carried out. The AEM and LOM routes with five different elementary steps are schematically illustrated in Fig. 5h, i. As shown, the AEM pathway experiences concerted proton-electron transfer processes with four reactive oxygen species, namely, M − OH, M − O, M − OOH, and M − OO (M represents the transition metal)24. Different from the AEM, the LOM undergoes the route of O − M − OH, MOO (dashed box), OO − M − ▢, and M − OH (bold O is lattice oxygen active site, ▢ denotes oxygen vacancy), which involves the direct coupling of *O intermediate with active lattice oxygen. The free energy diagrams reveal that the OER mechanisms of the CoO and Fe-CoO slabs both follow a conventional AEM route, since the potential determining step (PDS) in an AEM route, that is Co−OO formation, holds lower energy compared to oxygen vacancy formation in a LOM pathway (Fig. 5j & Supplementary Figs. 28, 29). Additionally, the energy barrier of the PDS for the AEM pathway decreases from 2.01 to 1.38 eV after Fe doping (Supplementary Table 7). This is in great alignment with the result that Fe-doping causes a positive shift of εd of active Co sites, thus enhancing the OER process. However, once F is doped into CoO, as seen from F-CoO and Fe, F-CoO slabs, the free energy change for the formation of oxygen vacancy in the LOM pathway decreases dramatically, implying that F doping plays a critical role in stabilizing the oxygen vacancy (Fig. 5k & Supplementary Figs. 30, 31). As a result, the LOM pathway is thermodynamically more favorable for F-CoO and Fe, F-CoO slabs with a lower energy barrier compared to the AEM pathway, further verifying the effective activation of lattice oxygen in F-CoO and Fe, F-CoO slabs. This is also evidenced by the prominent upshift of O 2p bands toward Ef, as observed in the O 2p PDOS diagrams (Supplementary Fig. 32). What’s more, the Fe, F-CoO slab delivers the lowest energy uphill of 1.17 eV to complete the OER loop among the four samples, thereby exhibiting supreme intrinsic activity and a decreased overpotential for OER. These are in good alignment with the optimized electron structures of Co and O atoms, and the highest metal-oxygen covalency in the Fe, F-CoO slab as demonstrated above.
Effects of local electric field
Furthermore, the pivotal role of Fe doping-induced rough nanoneedle structure for boosted electrocatalytic activity was investigated. Finite element method simulations were first employed to explore the distributions of charges and OH− ions close to the electrode surface. Four models with different radii and disparate surfaces were constructed to simulate the immersion of CoO electrodes in 1.0 M KOH electrolyte (Supplementary Fig. 33). Evidently, positive charge density is mainly centralized at the tips of nanoneedles and displays a 24-fold increase with the sharpening of the top radius from 110 to 3.2 nm (Fig. 6a, b). The tip-enhanced local current is probably due to the electron migration resulting from the electrostatic repulsion effect27. To simulate the rough surface, 1.5 nm spherules were decorated on the nanoneedle surface as a model, in which each spherule can serve as a tiny tip for charge accumulation. Intriguingly, a larger positive charge density of 0.094 C m–2 is found, approximately 1.4 times that of the smooth one (Fig. 6c). Moreover, decreasing the distance between the spherules from 16 to 6 nm is favorable to converging the positive charge density surrounding the nanoneedle surface and increasing the charge density dramatically, suggesting a conspicuous proximity enhancement (Fig. 6d). The charge density can reach 0.11 C m−2, corresponding to an electric field of 1.58 × 10−2 V/Å. To quantitatively reckon the influence of the electric field on the distribution of surface OH– ions, a Gouy-Chapman-Stern model is then adopted for portraying the concentration of OH– in the Helmholtz layer of the electrical double layer near the electrode surface. As depicted, due to the coupling of tip-enhanced electric field and the adjacency effect, the OH– concentration on rough needle-like structure with small spherule gaps (6 nm) reaches the highest, increased by 170 % and 20 % compared to smooth needle tips and the model with large spherule gaps (16 nm), respectively (Fig. 6e–h). A higher OH– concentration means a larger pH, which thermodynamically favors the OER30. Furthermore, the effect of local electric field on the OER process was investigated by DFT. As illustrated in Supplementary Fig. 34, at an electric field of 1.58 × 10−2 V/Å, the energy uphill of PDS for LOM on the Fe, F-CoO slab is lowered to 0.99 eV, indicating the accelerated lattice oxygen activation kinetics. Meanwhile, the release rate of O2 bubbles on the rough nanoneedle structure is significantly faster than that on flat surfaces due to the smaller stretch force, as demonstrated by the in situ optical microscope images (Fig. 6i, j & Supplementary Movies 1,2)60,61. Hence, the Fe, F-CoO NNAs can induce a stronger local electric field to enrich OH– ions at the electrode surface, expose more active sites to OH– ions, optimize the energy barrier of LOM, as well as promote O2 release, thus promoting the alkaline OER process.
Industrial overall water splitting performance
The applicability of the Fe, F-CoO NNAs catalyst in industrial overall water splitting was also investigated. The configuration of the alkaline two-electrode electrolyzer is schematically presented in Supplementary Fig. 35, employing Fe, F-CoO NNAs and Pt/C catalysts as the anode and cathode, respectively. Polarization curves manifest that the Fe, F-CoO NNAs only require 1.41 V to deliver in 1.0 M KOH electrolyte at the current density of 10 mA cm–2, which is much lower than those of F-CoO NNAs, Fe-CoO NNAs, CoO NNAs, and IrO2 catalysts (Supplementary Fig. 36). Especially, low cell voltages of 1.57 V and 1.70 V are achieved for the as-assembled Fe, F-CoO NNAs (+) | | Pt/C (–) system, to reach the current densities of 100 mA cm–2 and 500 mA cm–2. These values also surpass most of the state-of-the-art electrocatalysts (Supplementary Table 8). More importantly, the voltage of the alkaline electrolyzer can be maintained for 60 h without obvious loss at industrial current densities from 100 to 500 mA cm–2 (Supplementary Fig. 37). Thus, the Fe, F-CoO NNAs show great potential in large-scale water splitting.
In summary, this work demonstrates the importance of cation and anion dual doping on multi-scale regulation of lattice oxygen redox chemistry and local electric field for enhancing OER activity, through a combination of experiments, XAS, in situ Raman spectroscopy, 18O isotope technology, DEMS, DFT calculations, finite element method simulations, and in situ optical microscope. Rough Fe, F-CoO NNAs with triggered lattice oxygen sites and an enhanced local electric field have been successfully constructed, which boost the OER process. Studies show that relative to single doping, the dually doping of Fe and F into CoO introduces stronger metal-oxygen covalency and higher lattice oxygen reactivity by regulating the Co εd and the O 2p band simultaneously. In particular, Fe and F dopants mainly adjust the electronic states of the Co atom and oxygen ligand, respectively, resulting in disparate electrochemical behaviors and OER mechanisms in Fe-CoO NNAs and F-CoO NNAs. Moreover, it has been proven that Fe doping induces a sharp tip enhancement and a proximity effect, and contributes to a stronger electric field, which favors the enrichment of OH– around the active sites, optimizes reaction energy barrier, as well as promotes the release of O2 bubbles. As a result, the as-prepared Fe, F-CoO NNAs exhibit remarkably low overpotentials of 169 mV at the current density of 10 mA cm–2 and 277 mV at the industrial current density of 500 mA cm–2 with robust durability, which surpass most of the state-of-the-art catalysts. These results provide new insights into the integration of lattice oxygen redox chemistry and local electric field, which may open a new path to design high-efficiency catalysts for accelerating the OER kinetics, and also deepen the understanding of the structure-activity relationship and electrocatalytic mechanism. More broadly, this work could offer some promising views for other catalytic reactions as well as energy storage systems that involve oxygen chemistry or mass transfer kinetics.
Methods
Chemicals
Co(NO3)2·6H2O was purchased from Shanghai Aladdin Chemical Reagents Co., Ltd. Other chemicals such as urea, NH4F, K3[Fe(CN)6], and KOH were obtained from Sinopharm Reagent Co., Ltd. All the reagents were directly used without further purification.
Synthesis of Co(OH)F NNAs
Typically, NF was ultrasonically cleaned in 3 M HCl solution for 30 min, then rinsed with de-ionized (DI) water and anhydrous ethanol three times, respectively. The cleaned NF was dried in an oven at 60 °C overnight before use. Co(OH)F NNAs were grown on NF via a simple hydrothermal method. Specifically, a mixed solution of 0.125 M Co(NO3)2·6H2O, 0.625 M urea, and 0.125 M NH4F was transferred into a 25 mL Teflon-lined stainless steel autoclave containing pretreated NF. The autoclave was maintained at 120 °C for 6 h. After cooling to room temperature, the NF was removed and rinsed with DI water and anhydrous ethanol sequentially. Co(OH)F NNAs on NF were finally obtained after drying in an oven at 60 °C for 12 h.
Synthesis of Fe, F-CoO NNAs
In a typical synthesis, the as-prepared Co(OH)F NNAs supported on NF were immersed in 0.01 M K3[Fe(CN)6] solution at 50 °C for 20 min. Then, the product was washed with DI water and anhydrous ethanol by ultrasonic and dried at 60 °C. Subsequently, the as-obtained product was annealed at 300 °C for 4 h with a heating rate of 2 °C min−1 to obtain Fe, F-CoO NNAs. The loading of the catalyst was about 4.5 mg cm−2. Fe, F-CoO NNAs with different Fe contents can be prepared by changing the concentrations of K3[Fe(CN)6] (0.005 M, 0.01 M, and 0.02 M).
Synthesis of F-CoO NNAs
Typically, F-CoO NNAs were prepared by annealing Co(OH)F NNAs at 300 °C for 4 h with a heating rate of 2 °C min−1.
Synthesis of Co(OH)2 NNAs
In a typical synthesis, a mixture of 0.125 M Co(NO3)2·6H2O and 0.625 M urea was transferred into a 25 mL Teflon-lined stainless steel autoclave containing pretreated NF. The stainless steel autoclave was then maintained at 120 oC for 6 h to grow Co(OH)2 NNAs on NF. Eventually, the product was rinsed with DI water and anhydrous ethanol, and dried in an oven at 60 °C for 12 h.
Synthesis of Fe-CoO NNAs
Briefly, the synthetic procedure of Fe-CoO NNAs was similar to that of Fe, F-CoO NNAs except using Co(OH)2 NNAs rather than Co(OH)F NNAs as the precursor.
Synthesis of CoO NNAs
Briefly, the as-obtained Co(OH)2 NNAs on NF were annealed at 300 °C for 4 h with a heating rate of 2 °C min−1 to prepare CoO NNAs.
Characterization
FESEM and EDS were conducted on A Hitachi S-4800 scanning electron micro-analyzer. TEM, HRTEM, and SAED images were acquired on a JEM-2100F field emission micro-analyzer at 200 kV. XRD was performed on a Philips PW3040/60 X-ray diffractometer equipped with Cu-Ka radiation. Ex situ Raman was conducted on a Renishaw in Via-Refles with a 532 nm laser as the exciting source. XPS was carried out on an ESCALab MKII X-ray photoelectron spectrometer using Al Ka X-ray radiation as the excitation source. In situ optical microscope pictures were captured by a BX53MRF-S optical microscope. O K-edge and Co K-edge XAS spectra were collected on the RapidXAFS 2 M (Anhui Absorption Spectroscopy Analysis Instrument Co., Ltd.), and the Si (533) spherically bent crystal analyzer with a radius of curvature of 500 mm was used for Co.
Electrochemical measurements
All the electrochemical measurements were performed on a CHI 760E electrochemical workstation. The OER performances were evaluated in a standard three-electrode electrochemical system at room temperature with O2-saturated 1 M KOH aqueous solution as the electrolyte. The as-prepared sample was used as the working electrode, while a carbon rod and a saturated calomel electrode served as the counter and reference electrodes, respectively. Before the assessment of OER performance, all the catalysts were activated to a stable state with cyclic voltammetry (CV) scanning at a scanning rate of 50 mV s−1. LSV was performed at a sweep rate of 5 mV s−1 and all the LSV curves were corrected with 90% IR compensation to eliminate the effect of solution resistance. Tafel plots were obtained from the polarization curves (Potential vs. the logarithm of current density (log |j | )). The electrochemical stability of the catalysts was measured by chronopotentiometry under the industrial-level current densities of 100 mA cm−2 and 500 mA cm−2. The potential versus RHE was converted according to the following equation.
The ECSAs of the catalysts were estimated based on the electric double-layer capacitance (Cdl). Cyclic voltammetry was performed from 0.15 to 0.25 V vs. RHE at various scanning rates from 20 to 100 mV s−1. The Cdl is estimated by the quotient of the current density difference (∆j/2) in the center of the potential window and the scanning rate. The calculation for ECSA is shown as follows.
where Cs is 0.04 mF cm−2 in alkaline electrolyte, and A is the area of the working electrode (0.5 cm−2 in this work). EIS measurements were performed at frequencies ranging from 100000 to 0.01 Hz under an AC voltage of 5 mV.
Electrochemical overall water splitting tests were measured using a two-electrode system. The as-prepared catalysts and Pt/C on NF were used as an anode for OER and a cathode for HER, respectively. For preparing the cathode, 5 mg of commercial 20 wt.% Pt/C catalyst and 40 μL of 5 wt.% Nafion solution were dispersed in 960 μL alcohol and water (1:1) by sonication for 30 min to form a homogeneous ink. Then the as-prepared Pt/C ink (475 μL) was dropped on the surface of NF. LSV curves were performed in 1 M KOH solution at a sweep speed of 5 mV s−1 with 90% IR compensation. Electrochemical stability was measured by the chronopotentiometry method at the current density of 100 ~ 500 mA cm−2.
Theoretical simulations, finite element analysis numerical simulations, and in situ electrochemical Raman measurements, as well as supplementary figures and tables, were provided in Supplementary Information.
Data availability
The authors declare that the data supporting the findings of this study can be found in the paper and Supplementary Information files, or are available from the corresponding authors upon request.
References
Vojvodic, A. & Norskov, J. K. Optimizing perovskites for the water-splitting reaction. Science 334, 1355–1356 (2011).
Hu, E. et al. Construction of hierarchical Ni-Co-P hollow nanobricks with oriented nanosheets for efficient overall water splitting. Energy Environ. Sci. 11, 872–880 (2018).
Zhao, S. et al. Ultrathin metal-organic framework nanosheets for electrocatalytic oxygen evolution. Nat. Energy 1, 1–10 (2016).
Ng, J. W. D. et al. Gold-supported cerium-doped NiOx catalysts for water oxidation. Nat. Energy 1, 16053 (2016).
Hu, E. et al. Graphene layers-wrapped Fe/Fe5C2 nanoparticles supported on N-doped graphene nanosheets for highly efficient oxygen reduction. Adv. Energy Mater. 8, 1702476 (2018).
Li, J. et al. A general strategy for preparing pyrrolic-N4 type single-atom catalysts via pre-located isolated atoms. Nat. Commun. 12, 6806 (2021).
Cao, L. et al. Dynamic oxygen adsorption on single-atomic Ruthenium catalyst with high performance for acidic oxygen evolution reaction. Nat. Commun. 10, 4849 (2019).
Zhai, P. et al. Engineering single-atomic ruthenium catalytic sites on defective nickel-iron layered double hydroxide for overall water splitting. Nat. Commun. 12, 4587 (2021).
Zhang, R. et al. Tracking the role of defect types in Co3O4 structural evolution and active motifs during oxygen evolution reaction. J. Am. Chem. Soc. 145, 2271–2281 (2023).
Yan, D. et al. Cation defect engineering of transition metal electrocatalysts for oxygen evolution reaction. Adv. Energy Mater. 12, 2202317 (2022).
Yan, J. et al. Single atom tungsten doped ultrathin α-Ni(OH)2 for enhanced electrocatalytic water oxidation. Nat. Commun. 10, 2149 (2019).
Zhao, Y., Nakamura, R., Kamiya, K., Nakanishi, S. & Hashimoto, K. Nitrogen-doped carbon nanomaterials as non-metal electrocatalysts for water oxidation. Nat. Commun. 4, 2390 (2013).
Zhang, L. et al. Self-reconstructed metal-organic framework heterojunction for switchable oxygen evolution reaction. Angew. Chem. Int. Ed. 61, e202214794 (2022).
Qiu, C. et al. Interfacial engineering FeOOH/CoO nanoneedle array for efficient overall water splitting driven by solar energy. Chem. Eur. J. 26, 4120–4127 (2020).
Yan, L. et al. Engineering self-supported hydrophobic-aerophilic air cathode with CoS/Fe3S4 nanoparticles embedded in S, N co-doped carbon plate arrays for long-life rechargeable Zn-air batteries. Adv. Energy Mater. 13, 2204245 (2023).
Yang, X. G. et al. Enhanced activity of enzyme immobilized on hydrophobic ZIF-8 modified by Ni2+ ions. Angew. Chem. Int. Ed. 62, e202216699 (2023).
Wang, X., Zhong, H., Xi, S., Lee, W. S. V. & Xue, J. Understanding of oxygen redox in the oxygen evolution reaction. Adv. Mater. 34, 2107956 (2022).
Xiao, K. et al. Activating lattice oxygen in spinel ZnCo2O4 through filling oxygen vacancies with fluorine for electrocatalytic oxygen evolution. Angew. Chem. Int. Ed. 62, e202301408 (2023).
Song, J. et al. A review on fundamentals for designing oxygen evolution electrocatalysts. Chem. Soc. Rev. 49, 2196–2214 (2020).
Grimaud, A. et al. Activating lattice oxygen redox reactions in metal oxides to catalyse oxygen evolution. Nat. Chem. 9, 457–465 (2017).
Wang, C. et al. Engineering lattice oxygen activation of iridium clusters stabilized on amorphous bimetal borides array for oxygen evolution reaction. Angew. Chem. Int. Ed. 60, 27126–27134 (2021).
Huang, Z. F. et al. Tuning of lattice oxygen reactivity and scaling relation to construct better oxygen evolution electrocatalyst. Nat. Commun. 12, 3992 (2021).
Zhang, N. et al. Lattice oxygen activation enabled by high-valence metal sites for enhanced water oxidation. Nat. Commun. 11, 4066 (2020).
Huang, Z. F. et al. Chemical and structural origin of lattice oxygen oxidation in Co-Zn oxyhydroxide oxygen evolution electrocatalysts. Nat. Energy 4, 329–338 (2019).
Zhang, N. & Chai, Y. Lattice oxygen redox chemistry in solid-state electrocatalysts for water oxidation. Energy Environ. Sci. 14, 4647–4671 (2021).
Hu, Q. et al. Integrating well-controlled core-shell structures into “superaerophobic” electrodes for water oxidation at large current densities. Appl. Catal. B:Environ. 286, 119920 (2021).
Liu, M. et al. Enhanced electrocatalytic CO2 reduction via field-induced reagent concentration. Nature 537, 382–386 (2016).
Chen, Q. et al. Ordered Ag nanoneedle arrays with enhanced electrocatalytic CO2 reduction via structure-induced inhibition of hydrogen evolution. Nano Lett. 22, 6276–6284 (2022).
Gao, Y. et al. Field-induced reagent concentration and sulfur adsorption enable efficient electrocatalytic semihydrogenation of alkynes. Sci. Adv. 8, eabm9477 (2022).
Liu, P. et al. Tip-enhanced electric field: A new mechanism promoting mass transfer in oxygen evolution reactions. Adv. Mater. 33, 2007377 (2021).
Liu, D. et al. Atomically dispersed platinum supported on curved carbon supports for efficient electrocatalytic hydrogen evolution. Nat. Energy 4, 512–518 (2019).
Nairan, A. et al. Proton selective adsorption on Pt-Ni nano-thorn array electrodes for superior hydrogen evolution activity. Energy Environ. Sci. 14, 1594–1601 (2021).
Jiang, H., Hou, Z. & Luo, Y. Unraveling the mechanism for the sharp-tip enhanced electrocatalytic carbon dioxide reduction: The kinetics decide. Angew. Chem. Int. Ed. 56, 15617–15621 (2017).
Zhang, L. et al. Attenuating a metal-oxygen bond of a double perovskite oxide via anion doping to enhance its catalytic activity for the oxygen reduction reaction. J. Mater. Chem. A 8, 14091–14098 (2020).
Yu, X. et al. Activation or passivation: Influence of halogen dopant (F, Cl, Br) on photothermal activity of Mn2O3 in degrading toluene. Appl. Catal. B: Environ. 309, 121236 (2022).
Xie, L., Zhao, D., Dai, J., Wu, Z. & Li, L. Solvothermally doping NiS2 nanoparticles on carbon with ferric ions for efficient oxygen evolution catalysis. Catalysts 9, 458 (2019).
Lei, H. et al. Coordination and interface engineering to boost catalytic property of two-dimensional ZIFs for wearable Zn-air batteries. J. Energy Chem. 68, 78–86 (2022).
Li, M. et al. Scalable dry production process of a duperior 3D net-like carbon-based iron oxide anode material for lithium-ion batteries. Angew. Chem. Int. Ed. 56, 12649–12653 (2017).
Chen, X., Wei, M. & Zhou, J. Fluorine-doping-assisted vacancy engineering for efficient electrocatalyst toward hydrogen production. J. Mater. Chem. A 9, 22626–22634 (2021).
Lu, W. et al. Construction of CoO/Co-Cu-S hierarchical tubular heterostructures for hybrid supercapacitors. Angew. Chem. Int. Ed. 58, 15441–15447 (2019).
Lian, J. et al. Magnetic flower-like Fe-doped CoO nanocomposites with dual enzyme-like activities for facile and sensitive determination of H2O2 and dopamine. Inorg. Chem. 60, 1893–1901 (2021).
Mi, J. et al. Activation of partial metal sites in high-entropy oxides for enhancing thermal and electrochemical catalysis. Chin. J. Catal. 48, 235–246 (2023).
Wu, Y. et al. Triggering lattice oxygen activation of single-atomic Mo sites anchored on Ni-Fe oxyhydroxides nanoarrays for electrochemical water oxidation. Adv. Mater. 34, 2202523 (2022).
Roychoudhury, S. et al. Deciphering the oxygen absorption pre-edge: A caveat on its application for probing oxygen redox reactions in batteries. Energy Environ. Mater. 4, 246–254 (2021).
Wang, X. et al. The role of electron localization in covalency and electrochemical properties of lithium-ion battery cathode materials. Adv. Funct. Mater. 31, 2001633 (2021).
Huang, J. et al. Modifying redox properties and local bonding of Co3O4 by CeO2 enhances oxygen evolution catalysis in acid. Nat. Commun. 12, 3036 (2021).
Su, H. et al. In-situ spectroscopic observation of dynamic-coupling oxygen on atomically dispersed iridium electrocatalyst for acidic water oxidation. Nat. Commun. 12, 6118 (2021).
Chen, X. et al. S-doping triggers redox reactivities of both iron and lattice oxygen in FeOOH for low-cost and high-performance water oxidation. Adv. Funct. Mater. 32, 2112674 (2022).
Mefford, J. T. et al. Water electrolysis on La1-xSrxCoO3-δ perovskite electrocatalysts. Nat. Commun. 7, 11053 (2016).
Xiao, L. et al. Electronic and nano-structural modulation of Co(OH)2 nanosheets by Fe-benzenedicarboxylate for efficient oxygen evolution. Chem. Res. Chin. U. 39, 219–223 (2023).
Guo, W. et al. In situ revealing the reconstruction behavior of monolayer rocksalt CoO nanosheet as water oxidation catalyst. J. Energy Chem. 70, 373–381 (2022).
Moysiadou, A., Lee, S., Hsu, C. S., Chen, H. M. & Hu, X. Mechanism of oxygen evolution catalyzed by cobalt oxyhydroxide: cobalt superoxide species as a key intermediate and dioxygen release as a rate-determining step. J. Am. Chem. Soc. 142, 11901–11914 (2020).
Lee, S., Banjac, K., Lingenfelder, M. & Hu, X. Oxygen isotope labeling experiments reveal different reaction sites for the oxygen evolution reaction on nickel and nickel iron oxides. Angew. Chem. Int. Ed. 58, 10295–10299 (2019).
Farsi, L. & Deskins, N. A. First principles analysis of surface dependent segregation in bimetallic alloys. Phys. Chem. Chem. Phys. 21, 23626–23637 (2019).
Grimaud, A., Hong, W. T., Shao-Horn, Y. & Tarascon, J. M. Anionic redox processes for electrochemical devices. Nat. Mater. 15, 121–126 (2016).
Wang, Z. et al. Elevating the d-band center of six-coordinated octahedrons in Co9S8 through Fe-incorporated topochemical deintercalation. Adv. Energy Mater. 11, 2003023 (2021).
Han, B. et al. Nanoscale structural oscillations in perovskite oxides induced by oxygen evolution. Nat. Mater. 16, 121–126 (2017).
Ji, J. et al. Co2+/3+/4+-regulated electron state of Mn-O for superb aqueous zinc-manganese oxide batteries. Adv. Energy Mater. 11, 2003203 (2021).
Mueller, D. N., Machala, M. L., Bluhm, H. & Chueh, W. C. Redox activity of surface oxygen anions in oxygen-deficient perovskite oxides during electrochemical reactions. Nat. Commun. 6, 6097 (2015).
Song, Q. et al. General strategy to optimize gas evolution reaction via assembled striped-pattern sduperlattices. J. Am. Chem. Soc. 142, 1857–1863 (2020).
Lin, Q. et al. Tuning the interface of Co1-xS/Co(OH)F by atomic replacement strategy toward high-performance electrocatalytic oxygen evolution. ACS Nano 16, 15460–15470 (2022).
Acknowledgements
We thank the Anhui Absorption Spectroscopy Analysis Instrument Co, Ltd. for XAFS measurements and analysis. This work was financially supported by the National Natural Science Foundation of China (22272150), the Major Program of Zhejiang Provincial Natural Science Foundation of China (LD22B030002) and Zhejiang Provincial Ten Thousand Talent Program (2021R51009). H. W. acknowledges National Natural Science Foundation of China (22302177) and Key Science and Technology Project of Jinhua City (2020-1-044). H. H. acknowledges National Natural Science Foundation of China (22002083) and MSCA-IF-2020 Individual Fellowships (101024758).
Author information
Authors and Affiliations
Contributions
Y.H. and H.Y.W. conceived the original concept, supervised this project, and wrote the paper. P.C.Y. and K.Q.F. performed the synthesis, characterizations, and electrochemical performances of the catalysts. P.C.Y. and K.Q.F. analyzed the data. Y.H.W. helped the in situ Raman measurements. H.H. performed the density functional theory calculations. C.B.M. helped the preparation of catalysts. J.Q.N. helped with the data analysis and revision of the manuscript. All authors discussed the results and commented on the manuscript.
Corresponding authors
Ethics declarations
Competing interests
The authors declare no competing interests.
Peer review
Peer review information
Nature Communications thanks the anonymous, reviewer(s) for their contribution to the peer review of this work. A peer review file is available.
Additional information
Publisher’s note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The images or other third party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons license and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Ye, P., Fang, K., Wang, H. et al. Lattice oxygen activation and local electric field enhancement by co-doping Fe and F in CoO nanoneedle arrays for industrial electrocatalytic water oxidation. Nat Commun 15, 1012 (2024). https://doi.org/10.1038/s41467-024-45320-0
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/s41467-024-45320-0
- Springer Nature Limited