Abstract
Covalent organic frameworks (COFs) are ideal templates for constructing metal-free catalysts for the oxygen reduction reaction due to their highly tuneable skeletons and controllable porous channels. However, the development of highly active sites within COFs remains challenging due to their limited electron-transfer capabilities and weak binding affinities for reaction intermediates. Herein, we constructed highly active catalytic centres by modulating the electronic states of the pyridine nitrogen atoms incorporated into the frameworks of COFs. By incorporating different pyridine units (such as pyridine, ionic pyridine, and ionic imidazole units), we tuned various properties including dipole moments, reductive ability, hydrophilicity, and binding affinities towards reaction intermediates. Notably, the ionic imidazole COF (im-PY-BPY-COF) exhibited greater activity than the neutral COF (PY-BPY-COF) and ionic pyridine COF (ion-PY-BPY-COF). Specifically, im-PY-BPY-COF demonstrated a half-wave potential of 0.80 V in 0.1 M KOH, outperforming other metal-free COFs. Theoretical calculations and in situ synchrotron radiation Fourier transform infrared spectroscopy confirmed that the carbon atoms in the ionic imidazole rings improved the activity by facilitating binding of the intermediate OOH* and promoting the desorption of OH*. This study provides new insights into the design of highly active metal-like COF catalysts.
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Introduction
The oxygen reduction reaction (ORR) plays critical roles as the essential half-reactions of metal-air batteries and fuel cells1,2,3,4,5. In the pursuit of high-efficiency catalysts, metal-free materials have emerged as promising candidates because of their cost-effectiveness and superior chemical stabilities6,7,8,9,10. Doping heteroatoms into porous carbon materials has proven to be an effective strategy for improving catalytic performance11,12,13. However, precise control of the location, content, and type of doping sites remains challenging, underscoring the necessity of understanding the relationships between these structures and their corresponding properties.
Covalent organic frameworks (COFs) are porous polymers with well-defined structures, maintained by covalently bonded building blocks14,15,16,17,18,19,20. The tunable skeletons and porosities of COFs make them useful for various applications, such as gas capture21,22,23, molecular separations24,25,26, photocatalysis27,28,29, and ion sensing or conduction30,31,32,33,34. Additionally, COFs constructed with electroactive units have shown promise in electrocatalysis and electronic chemical storage systems35,36,37,38,39. COFs serve as bridges between molecular catalysts and carbon catalysts, offering opportunities to modulate the locations, coordination environment, and densities of active sites40. Recently, sulphur-containing COFs were seen to catalyse the ORR41. In addition to heteroatom incorporation, the introducing of functional groups to modulate the catalytic performance of the carbon atoms in imine linkage (C = N) has emerged as another important strategy42,43,44,45. To achieve highly active catalysts, COFs with different functional groups, linkages, and topologies have been synthesized46,47,48,49,50. However, their activities still fell short compared to those of carbon catalysts and commercial Pt/C catalysts, and the current record for a half-wave potential is 0.75 V vs. RHE. This limited activity was attributed to the poor electron conductivity of the frameworks and the weak binding of O2 and other oxygen-containing intermediates51. Thus, developing electronic conductive frameworks with strong polar sites holds promise for constructing highly active metal-free ORR catalysts52,53,54,55,56,57.
In this study, we sought to enhance the catalytic activities of COFs in the ORR by modulating their intrinsic catalytic properties and improving their electronic conductivities. To achieve this goal, we carefully controlled the states of the nitrogen atoms in the COFs, which allowed us to fine-tune various properties such as the electronic conductivity, dipole moments, reductive ability, hydrophilicity, and binding ability of the oxygen-containing intermediate. The im-PY-BPY-COF showed a high electronic conductivity of 6.8 × 10 –8 S cm–1, which was 3600 and 440 times greater than those of PY-BPY-COF and ion-PY-BPY-COF, respectively. The im-PY-BPY-COF demonstrated better ORR activity than other metal-free COFs.
Results and Discussion
Chemistry and structure of catalytic COFs
We synthesized the base PY-BPY-COF by reacting 4,4’,4”,4”‘-(pyrene-1,3,6,8-tetrayl)-tetraaniline (PY) with [2,2’-bipyridine] -5,5’-dicarbaldehyde (BPY) in a mixture of n-butanol/1,2-dichlorobenzene (0.5 mL/0.5 mL) containing HOAc (6 M, 0.1 mL). The reaction was conducted at 120 °C for 72 h via a solvothermal method, resulting in a yield of 86% (Supplementary Fig. 1a). Subsequently, the COF was reacted with bromoethane in a postsynthetic strategy to obtain ion-PY-BPY-COF (Supplementary Fig. 1b)58,59,60,61,62,63. Furthermore, we synthesized a new COF (im-PY-BPY-COF) via a cycloaddition reaction between PY-BPY-COF and paraformaldehyde (Fig. 1a & 1b and Supplementary Fig. 1c).
The skeletons and catalytic centres of the COFs were first investigated with Fourier transform infrared (FT-IR) spectroscopy. The C = N linkages in PY-BPY-COF generated a peak at 1608 cm–1 (Supplementary Fig. 2, black curve), which also observed in spectra of the ion-PY-BPY-COF and im-PY-BPY-COF samples, suggesting preservation of the COF skeletons after ionization of the pyridine units. Additionally, the new bonds at 2928 and 2911 cm–1 in the spectrum of ion-PY-BPY-COF originated from the ethyl groups attached to the pyridine N sites (Supplementary Fig. 2, green curve). For im-PY-BPY-COF, the intensity of the C = N peak was greater than those in the other samples, which was attributed to the formation of new C = N bonds in the imidazole units (Supplementary Fig. 2, red curve). X-ray absorption near-edge spectroscopy (XANES) analysis of the nitrogen K-edge was used to investigate the conversion of pyridine-N to imidazole-N (Supplementary Fig. 3). The c peaks (graphitic N, 408.4 eV) of PY-BPY-COF and im-PY-BPY-COF were very close, while the peak for im-PY-BPY-COF (C = N-C, 399.9 eV) was significantly weaker than that of PY-BPY-COF, and the b peak (C-N-C, 401.8 eV) of im-PY-BPY-COF was stronger than that of PY-BPY-COF. These results indicated the formation of imidazole-N64,65.
The PXRD patterns of PY-BPY-COF showed peaks at 3.11°, 4.45°, 6.22°, 9.31°, 12.5°, and 24.9° corresponding to the (100), (220), (330), (440), and (001) facets, respectively (Fig. 1c). To refine the crystal structure, Pawley refinements was carried out by self-consistent charge density functional tight-binding method. The theoretical and experimental results showed minor deviations, and the goodness of fit factors Rwp and Rp were 3.16 and 3.56%, respectively. Two stacking models, AA and AB, were used to simulate for the COF, and the PXRD pattern obtained with the AA stacking model agreed well with the experimental results (Supplementary Fig. 4 and Supplementary Data 1). Upon ionization of the pyridine units within the COFs, the crystallinity was well maintained, as evidenced by the intense peak at 3.15° in the PXRD pattern, along with multiple peaks at 6.31°, 9.50°, 13.1° and 24.2° originating from the (110), (220), (330), (440) and (001) facets, respectively (Fig. 1d). The different stacking models used for the simulations confirmed that the AA stacking model was adopted by the ion-PY-BPY-COF (Supplementary Fig. 5 and Supplementary Table 1). Similarly, im-PY-BPY-COF also exhibited good crystallinity after the imidazole ring was constructed from bipyridine units. The PXRD pattern of im-PY-BPY-COF showed peak at 3.26° for the (100) facet, corresponding to a positive shift relative to that of PY-BPY-COF. Peaks originating from the (220), (330), (440), and (001) facets were observed at 6.58°, 9.92°, 13.1°, and 24.1°, respectively (Fig. 1e). Pawley refinements showed that the theoretical values were consistent with the experimental results (Rwp = 2.09% and Rp = 1.53%). The simulated stacking models also confirmed that the COFs adopted AA stacking models rather than AB stacking models (Supplementary Fig. 6 and Supplementary Table 2).
The porosities of the COFs played key roles in mass transport during the catalytic processes. Nitrogen (N2) sorption measurements were conducted on the three COF precursors at 77 K. The basal COF, PY-BPY-COF, exhibited a high Brunauer-Emmett-Teller (BET) surface area of 2258 m2 g–1 (Fig. 2a). The pore size distribution revealed a total pore volume of 1.5 cm3 g–1 and an average pore size of 2.4 nm for PY-BPY-COF (Fig. 2b). After postfunctionalization of the COFs, the corresponding surface areas and pore volumes had decreased. Compared to those of the original PY-BPY-COF, the BET surface areas of ion-PY-BPY-COF and im-PY-BPY-COF were lower, at 1820 and 1024 m2 g–1, respectively (Fig. 2d & 2g). The decreased BET surface area and pore volume of im-PY-BPY-COF were attributed to stacking disorder caused by ionic repulsions, as well as pore filling by trifluoroacetate counterions57. The pore sizes of ion-PY-BPY-COF and im-PY-BPY-COF remained the same as that of PY-BPY-COF, with reduced pore volumes of 1.1 and 0.7 cm3 g–1, respectively (Fig. 2e & 2h). The porosities and crystallinities of the COFs were examined with high-resolution transmission electron microscopy (HR-TEM) (Fig. 2c & 2f & 2i). Additionally, the COFs were measured using selected area electron diffraction (SAED). The clear diffraction rings were observed from the SAED patterns, which were assigned to COF crystal planes of (100), (220), and (330), respectively (Supplementary Fig. 7). This is consistent with the FFT and PXRD observations of the COFs, confirming the well-maintained crystalline structures upon the modifications66.
Solid-state 13C nuclear magnetic resonance (NMR) spectroscopy was used to examine the carbon arrangements within the three COFs. The 13C NMR spectrum of PY-BPY-COF showed a peak at 156.1 ppm attributed to the C atoms in C = N, while the peaks ranging from 156.2 to 149.2 ppm were attributed to the carbon atoms in the pyridine rings (Supplementary Fig. 8). The carbon atoms in the PY units showed resonances between 131.1 and 121.3 ppm. With the introduction of ethyl units into the COF, additional peaks appeared at 21.8, 35.2 and 38.3 ppm for ion-PY-BPY-COF (Supplementary Fig. 9). The 13C NMR spectrum of im-PY-BPY-COF showed a well-retained C = N peak, with a new peak at 136.3 ppm arising from the formation of imidazole rings. Importantly, the peak corresponding to the carbon atoms adjacent to pyridine nitrogen was shifted from 149.2 to 126.4 ppm, and the peak at 161.3 ppm was attributed to the anions (CF3COO–) in the COFs (Supplementary Fig. 10). These observations confirmed the syntheses of the intended COFs.
The XPS survey spectra confirmed the presence of all the elements in the three COFs (Supplementary Fig. 11). In the high-resolution N 1 s spectrum of PY-BPY-COF, peaks at 398.8 and 399.4 eV were observed, corresponding to pyridine and imine, respectively (Fig. 3a). Upon ionization of the pyridine units, the N 1 s peak disappeared and was replaced by two new peaks at 398.9 and 401.2 eV; these were attributed to the pyridine radical cation and positively charged nitrogen, respectively, confirming the presence of pyridinium in the ion-PY-BPY-COF. Similarly, upon protonation of the pyridine units, the N 1 s peak vanished and was replaced by two new peaks at 398.4 and 401.2 eV, indicating the presence of pyridinium in im-PY-BPY-COF63,67,68.
The morphologies of the COFs were examined with scanning electron microscopy (SEM) and transmission electron microscopy (TEM). The SEM images revealed dendritic structures with uniform sizes for PY-BPY-COF, which were consistent with those of the ion-PY-BPY-COF and im-PY-BPY-COF. (Supplementary Fig. 12). Moreover, clear layered structures were observed in the TEM images (Supplementary Figs. 13-15). The energy-dispersive X-ray map showed uniform distributions of all the elements within the skeletons. (Supplementary Figs. 16-18). In addition, the C, N, H elemental analysis results are presented in Supplementary Table 3 and agreed with the theoretically calculated values based on the networks.
The electronic conductivities of the COFs were tested with the four-probe method at 298 K. The electronic conductivity of PY-BPY-COF was 1.8 × 10–11 S cm–1 (Fig. 3b). Upon ionization of the pyridine units, a significant improvement in the electronic conductivity was observed. The ion-PY-BPY-COF demonstrated an electronic conductivity of 1.4 ×10–10 S cm–1 (Fig. 3b). Importantly, im-PY-BPY-COF achieved an even higher conductivity of 6.8 × 10–8 S cm–1, which was 3614 and 441 times greater than that those of unmodified PY-BPY-COF and ion-PY-BPY-COF, respectively. The electron paramagnetic resonance (EPR) spectra of the synthesized COF contained a weak peak at 3524 Gs for PY-BPY-COF (Fig. 3c), indicating the presence of organic radicals. The intensity of thew radical peak was noticeably higher in the case of im-PY-BPY-COF, indicating a greater contribution of radicals from the ionic imidazole units, resulting in enhanced electron conductivity68. The conjugation properties of PY-BPY-COF, ion-PY-BPY-COF, and im-PY-BPY-COF were studied with solid-state ultraviolet‒visible (UV‒Vis) absorption spectroscopy (Fig. 3d). By analyzing the Tauc plots derived from the UV‒vis absorption spectra, the optical bandgaps were calculated as 1.98, 1.91, and 1.76 eV for PY-BPY-COF, ion-PY-BPY-COF, and im-PY-BPY-COF, respectively (Supplementary Fig. 19). The narrow bandgap of im-PY-BPY-COF favour electronic transport. Additionally, the valence band-XPS (VB-XPS) measurements of the valence band positions for PY-BPY-COF, ion-PY-BPY-COF, and im-PY-BPY-COF were yielded values of 1.33, 1.37, and 1.38 eV, respectively (Supplementary Fig. 20).
To gain a deeper understanding of the electronic structures of PY-BPY-COF, ion-PY-BPY-COF, and im-PY-BPY-COF, density functional theory calculations were performed at the B3LYP/Def2-SVP level. The three COFs displayed typical donor-acceptor configurations, with the highest occupied molecular orbitals (HOMO) located mainly at the PY units of the COFs, and the lowest unoccupied molecular orbitals (LUMO) were fully localized over the linkers (Fig. 3e). The LUMO and HOMO energy-levels for PY-BPY-COF were –5.31 and –2.40 eV, respectively, resulting in an energy gap of 2.91 eV. In comparison, the ion-PY-BPY-COF exhibited a lower HOMO energy (–8.75 eV) and considerably lower LUMO energy (–8.22 eV), while the im-PY-BPY-COF exhibited a lower HOMO energy (–6.68 eV) and substantially lower LUMO energy (–5.48 eV). These findings indicated that the ion-PY-BPY-COF had greater reducing ability due to its lower HOMO and LUMO energies. Furthermore, the dipole moments for PY-BPY-COF, ion-PY-BPY-COF, and im-PY-BPY-COF were 1.24, 43.40 and 39.63 Debye, respectively. The high dipole moments indicated that the ionic imidazole units influenced the intermolecular polarity and promote charge-redistribution within the molecular backbones (Supplementary Fig. 21). This internal charge-transfer that may facilitate the absorption of O-containing intermediates69
.The hydrophilicities of the COFs played crucial roles in determining their electrocatalytic ORR activities. The water contact angles for the surfaces of PY-BPY-COF, ion-PY-BPY-COF and im-PY-BPY-COF were 92°, 75° and 72°, respectively, indicating that the presence of ionic linkers increased the hydrophilicities of the COFs (Supplementary Fig. 22).
The thermal and chemical stabilities of the COFs were investigated. Thermogravimetric analyses (TG) revealed that the three COFs were thermally stable below 400 °C under a N2 atmosphere (Supplementary Fig. 23). To assess their chemical stabilities, the COFs were treated with 0.1 M KOH for one week. PXRD patterns confirmed that the crystallinities of the COFs remained intact after the treatment (Supplementary Fig. 24). Furthermore, the FT-IR spectra exhibited all the expected peaks, indicating preservation of their framework structures (Supplementary Fig. 25).
Thus, while im-PY-BPY-COF shares similar crystal and pore structures with PY-BPY-COF and ion-PY-BPY-COF, it exhibited a significantly higher electronic conductivity, improved charge transfer ability, enhanced reductive ability, and greater hydrophilicity than the other two COFs.
ORR performance on catalytic COFs
We investigated the catalytic performance of the COFs with a three-electrode system under alkaline conditions. Cyclic voltammetry (CV) measurements were initially performed at a scan rate of 50 mV s–1 with a 0.1 M KOH aqueous solution saturated with N2 or O2 (Supplementary Fig. 26). In an oxygen-saturated environment, im-PY-BPY-COF exhibited a clear peak at 0.7 V vs. RHE, indicating its reactivity in the ORR. No peak was observed under nitrogen-saturated conditions. In comparison, the spectra of PY-BPY-COF and ion-PY-BPY-COF exhibited reduction peaks at 0.65 and 0.68 V, respectively, these values were 50 and 20 mV more negative than that of im-PY-PY-COF, indicating weaker activity. Linear sweep voltammograms (LSV) were obtained with a rotating-disk electrode and a scan rate of 1600 rpm. Initially, the catalytic behaviour of commercial Pt/C was studied as a control. The onset potential (EO) for Pt/C was 0.97 V, corresponding to a current density of 0.1 mA cm–2, and the half-wave potential (E1/2) was 0.85 V with a limited current density (jlim) of 5.6 mA cm–2 (Fig. 4a). PY-BPY-COF had EO and E1/2 values of 0.84 and 0.73 V, respectively, with a jlim of 4.2 mA cm–2, indicating inferior performance compared to Pt/C. On the other hand, ion-PY-BPY-COF demonstrated improved catalytic activity, with an EO of 0.88 V, E1/2 of 0.77 V, and jlim of 5.7 mA cm–2. Notably, im-PY-BPY-COF exhibited even better catalytic performance, with an EO of 0.90 V, an E1/2 of 0.80 V and a jlim of 5.8 mA cm–2. The ORR activity of im-PY-BPY-COF was higher than those of most reported metal-free COF catalysts (Supplementary Table 4). The kinetic behaviors were explored by comparing the Tafel slopes. The Tafel slope for im-PY-BPY-COF was 56.2 mV dec–1, which was markedly lower than those of PY-BPY-COF (79.4 mV dec–1), ion-PY-BPY-COF (76.8 mV dec–1), and Pt/C (117.7 mV dec–1), indicating favorable kinetic behavior (Fig. 4b).
To elucidate the distinct catalytic activities of the linkers in COFs, we synthesized bipyridine (BPY), ion-bipyridine (ion-BPY) and im-bipyridine (im-BPY) compounds (Supplementary Fig. 27). Subsequently, their catalytic activities were investigated (Supplementary Fig. 28). The LSV curves revealed that im-BPY had greater activity with an EO and an E1/2 of 0.88 V and 0.72 V, respectively, which were higher than those of BPY and ion-BPY. This confirmed that the catalytic activities of the small molecules followed the same trend observed for the COFs, further supporting the contributions of the different linkers. To eliminate the potential difference in charge transfer between carbon nanotubes (CNTs) and small molecules during the catalytic process, we linked small molecules to aminated CNTs. The LSV curves revealed that the catalytic activities of the small molecules attached to CNTs were similar to those of the COFs, further confirming the contributions of the different linkers (Supplementary Fig. 29). In addition, we investigated the ORR activity originating from the CNTs alone. The E0, E1/2, and jlim values for the CNTs were 0.85 V, 0.69 V and 3.24 mA cm‒2, respectively, indicating that the observed activity was indeed originated from the COFs (Supplementary Fig. 30).
In order to further investigate the catalytic activity, we investigated the TOF and mass activity of COF. (Fig. 4c). The im-PY-BPY-COF catalyst exhibited the highest TOF of 0.0198 s–1 at an experimental potential of 0.7 V, which was 5.4 and 3.2 times greater than the values exhibited by PY-BPY-COF (0.0037 s–1) and ion-PY-BPY-COF (0.0061 s–1), respectively. The corresponding mass activity for im-PY-BPY-COF was 0.57 A mg–1, which was higher than those of PY-BPY-COF (0.17 A mg–1) and ion-PY-BPY-COF (0.19 A mg–1).
To investigate the catalytic behaviors of the prepared COFs, we measured their electrochemically active surface areas (ECSA). Electrochemical double-layer capacitances (Cdl) were calculated from CV plots taken over the range 0.92‒1.02 V at scan rates of 10‒50 mV s–1 (Supplementary Fig. 31). The Cdl values for im-PY-BPY-COF, ion-PY-BPY-COF, and PY-BPY-COF were 8.2, 6.8 and 5.8 mF cm–2, respectively (Fig. 4d), with corresponding normalized ECSA of 205, 170 and 145, respectively. The larger ECSA indicated that the im-PY-BPY-COF contained more exposed active sites during the catalytic process than did the other COFs. The normalized LSV curve for im-PY-BPY-COF displayed a higher current density than those of PY-BPY-COF and ion-PY-BPY-COF from 0.2 to 0.9 V (Fig. 4e, red curve). This indicated that the excellent catalytic performance was primarily due to the intrinsic activity of the carbon sites rather than the ECSA.
The selectivity of the catalyst is another important parameter for the ORR, and was evaluated with a rotating ring-disk electrode. The Pt/C catalyst exhibited an electron transfer number (n) of 3.9‒4.0, with hydrogen peroxide (H2O2) yields of 4% within the potential range of 0.8‒0.2 V (Fig. 4f, black curve). In comparison, the im-PY-BPY-COF catalyst had n values ranging from 3.6‒4.0 and H2O2 yields of 10%‒18% (Fig. 4f, red curve), indicating a 4e– pathway for the ORR. However, PY-BPY-COF and ion-PY-BPY-COF exhibited lower selectivity. The n values for PY-BPY-COF ranged from 3.0 to 3.8, with the corresponding H2O2 yields of 12‒50% within the same potential range (Fig. 4f, blue curve). The ion-PY-BPY-COF delivered n values of 3.4‒3.7, and H2O2 yields of 20‒30% (Fig. 4f, green curve).
The durability of im-PY-BPY-COF was tested for 20 h at 0.4 V. The resulting current-time chronoamperometric response displayed a minimal decrease in the current density (only 10%) (Supplementary Fig. 32). Moreover, the PXRD patterns and FT-IR spectra revealed that the crystal structures and frameworks were well preserved after the long-term stability test, indicating high stability in a 0.1 M KOH solution (Supplementary Figs. 33 & 34). In addition, im-BY-BPY-COF demonstrated good chemical stability when methanol was added to the electrolytes, as the current density exhibited minor changes (Supplementary Fig. 35).
Density functional theory calculations
To investigate the catalytic mechanism, theoretical calculations were also conducted. The catalytic sites in the COFs were identified as C atoms with positive charges. Bader charge analyses of all atoms in the COFs revealed that the C atoms adjacent to the N sites in the pyridine units of (C1) for PY-BPY-COF and the carbon atoms between the N atoms in the imidazole units of im-PY-BPY-COF (C3) specifically served the catalytic sites for the ORR (Fig. 5a and Supplementary Fig. 36). The free energy changes (∆G) for the ORR with the catalytic COFs were calculated as U = 1.23 V. The rate-determining step (RDS) for PY-BPY-COF was found to be the formation of OOH* from O2 (Supplementary Fig. 37), with a ∆G of 2.07 eV (Fig. 5b). In contrast, the positively charged COFs had different RDS steps in their catalytic processes, which involved of OH* to H2O. The ∆G value for ion-PY-BPY-COF was 0.74 eV (Supplementary Fig. 38), while im-PY-BPY-COF delivered a lower ∆G of 0.38 eV (Supplementary Fig. 39), confirming its superior catalytic activity.
To identify the reaction intermediates and understand the catalytic reaction mechanism, in-situ SR-FTIR spectroscopy was employed, which reliably identified key intermediate species during the reaction process (Supplementary Fig. 40). The results obtained for im-PY-BPY-COF under different monitoring conditions are shown in Fig. 5c. An obvious absorption band corresponding to the emergence of OOH* (located at 1,050-1,060 cm–1) was observed once the applied potential exceeded 0.9 V70, indicating that the carbon atoms in im-PY-BPY-COF facilitated the formation of OOH*. Notably, a new IR absorption band for C-OH species was observed at 1640‒1650 cm–1 at 0.9 V (Fig. 5d)53, and its intensity increased with increasing applied potential, suggesting that the carbon sites were active sites for the absorption of OH* to promote ORR process. Linear plots of the in-situ SR-FTIR absorption band intensities for the C-OH and OOH* species with respect to the applied voltage are shown in Fig. 5e. Interestingly, the intensity of the C-OH absorption band increased after only 0.9 V and remained basically unchanged after 0.8 V. Meanwhile, the intensity of the absorption band increased sharply before 0.8 V and then gradually decreased. These pieces of evidence strongly confirmed that carbons in im-PY-BPY-COF preadsorbed oxygen to form a highly active OOH* structure, which then spontaneously generated the C-OH that served serving as the final product in the subsequent reaction for fast ORR kinetics. For ion-PY-BPY-COF, the intensity changes for the OOH* and C-OH vibrational bands were similar to those observed for im-PY-BPY-COF, indicating that they had the same rate-determining steps in the catalytic process (Fig. 5f and Supplementary Fig. 41). In situ SR-FTIR spectra of PY-BPY-COF revealed that the intensity of the C-OH band followed the same trend as that of OOH*, suggesting that the activity depended solely on the binding ability of OOH*, which was consistent with the theoretical results (Fig. 5g and Supplementary Fig. 42).
Discussion
In this study, catalytic COFs with different types of pyridine units were developed to catalyse the ORR. The properties of the COFs, such as their electronic conductivities, dipole moments, reductive abilities, and hydrophilicities, were carefully tuned with a precise charge-modifying strategy involving the pyridine units. Moreover, the carbon atoms in the ionic imidazole showed stronger binding affinities for the intermediate OOH* and facilitated the desorption of OH*, thereby enhancing the overall catalytic activity. The optimized COF catalyst showed better performance than other COF-based catalysts. This study provides valuable insights into the design and exploration of ideal active sites in COFs for efficient ORR catalysis.
Methods
Synthesis of PY-BPY-COF
The PY-BPY-COF was synthesized according to the previous report71. The mixtures of PY (11.3 mg, 0.02 mmol), BPY (8.5 mg, 0.04 mmol), HOAc (6 M, 0.1 mL), n-Butanol (0.5 mL) and 1,2-dichlorobenzene (0.5 mL) of and reacted at 120 °C for 72 h. The obtained solid was washed with THF three times and subjected to Soxhlet extraction with THF. to produce PY-BPY-COF in an isolated yield of 86%.
Synthesis of ion-PY-BPY-COF
The ion-PY-BPY-COF was synthesized according to previous report72. The PY-BPY-COF (50 mg) was dispersed in a mixture of acetonitrile (4 mL) and bromoethane (1 mL), which was then refluxed under nitrogen protection for 12 h. The product was flittered, washed with different solvents including THF, ethanol and acetone, and then dried under vacuum for 12 h to afford the ion-PY-BPY-COF.
Synthesis of im-PY-BPY-COF
The synthesized PY-BPY-COF (18.4 mg, 0.02 mmol) and paraformaldehyde (7.2 mg, 0.24 mmol) were added in the mixed solvents of mesitylene (0.5 mL) and n-BuOH (0.5 mL),. Then trifluoroacetic (0.04 mL) was added into the mixture. The suspension was reacted at 120 °C for 12 h under vacuum. The precipitate was treated by the same methods as that for PY-BPY-COF. with an isolated yield of 63%.
Synthesis of BPY-CNT
1 g of aminated CNT was mixed with BPY (50 mg) in dioxane solution (100 mL) at 80 °C for 2 h. The production was flitted, washed with THF, and ethanol, and then dried under vacuum for 12 h to afford the BPY-CNT.
Synthesis of ion-BPY-CNT
BPY-CNT (250 mg) was dispersed in a mixture of acetonitrile (10 mL) and bromoethane (2.5 mL) in a flask. The mixture was refluxed for 12 h under nitrogen protection. The production was flitted, washed with THF, and ethanol and dried under vacuum for 12 h to afford the ion-BPY-CNT.
Synthesis of im-BPY-CNT
In a flask, BPY-CNT (250 mg) and 0.3 mL of diiodomethane were dissolved in 10 mL of anhydrous acetonitrile under atmosphere. The reaction mixture was stirred at 100 °C for 48 h. The production was flitted, washed with THF, and ethanol and dried under vacuum for 12 h to afford the im-BPY-CNT.
Electrochemical measurements
The electrochemical measurements were conducted under the same condition according to previous report73. Firstly, the homogeneous catalysts ink was prepared by dispersing 5 mg of COFs and 3 mg of CNTs in 500 µL Nafion ethanol solution (0.25 wt.%) through 1 h to sonification treatment. Then, 16 µL prepare ink dropped onto a glassy carbon electrode (diameter 5.00 mm, surface area 0.125 cm2). The electrochemical measurements of COFs catalysts were carried out in a typical three-electrode cell at room temperature over an electrochemical workstation (Pine Research Instrumentation, USA). Platinum wire and silver/silver chloride (Ag/AgCl) electrode (saturated with 3 M KCl) were served as counter and reference electrodes, respectively. For evaluating the ORR activity and selectivity of different catalysts, a rotating ring disk electrode (RRDE) consisting of a platinum ring and a glassy carbon disk was used as the working electrode substrate. The RRDE measurements were performed at a rotation rate of 1600 ppm with a sweep rate of 10 mV s-1. The ORR electrochemical experiments were conducted in O2-saturated KOH solutions (0.1 M).
In situ Fourier transform infrared spectroscopy measurements
In situ synchrotron radiation Fourier transform infrared spectroscopy (SR-FTIR) investigations were carried out at the beamline BL01B of the National Synchrotron Radiation Laboratory, China74. A customized top-plate cell-reflection infrared reactor, which was equipped with a ZnSe crystal as the infrared transmission window (cutoff energy of ~625 cm–1), was used as in situ FTIR reactor (Supplementary Fig. 43). The FTIR spectrometer (Bruker 66 v/s) contains a KBr beam splitter and a liquid-nitrogen-cooled HgCdTe detector. In addition, the SR-FTIR system was also equipped with an infrared microscope (Bruker Hyperion 3000) with a magnification factor 16 objective lens. This configuration allowed for infrared spectroscopy measurements across the wide range of 15 ‒ 4000 cm–1 with a resolution of 0.25 cm–1. To minimize the loss of infrared light, the catalyst electrode was tightly sealed under the ZnSe crystal window, maintaining a micrometer-level gap. All the infrared spectra were recorded after applying a constant potential to the catalyst electrode for 30 min. To obtain high quality SR-FTIR spectra, a reflection mode with a vertical incidence of infrared light was used, and each spectrum was scanned for ~514 times with a resolution of 2 cm–1.
Data availability
The authors declare that all the data supporting the findings of this study are available within the article. The Supplementary Information, Source Data, and full image dataset are also available from the corresponding author upon request.
References
Santoro, C., Bollella, P., Erable, B., Atanassov, P. & Pant, D. Oxygen reduction reaction electrocatalysis in neutral media for bioelectrochemical systems. Nat. Catal. 5, 473–484 (2022).
Liu, X. & Dai, L. Carbon-based metal-free catalysts. Nat. Rev. Mater. 1, 16064 (2016).
Zhao, Y. et al. Oxygen Evolution/Reduction Reaction Catalysts: From In Situ Monitoring and Reaction Mechanisms to Rational Design. Chem. Rev. 123, 6257–6358 (2023).
Kamiyama, A. et al. MgO-Template Synthesis of Extremely High Capacity Hard Carbon for Na-Ion Battery. Angew. Chem. Int. Ed. 60, 5114–5120 (2021).
Zhao, X., Pachfule, P. & Thomas, A. Covalent organic frameworks (COFs) for electrochemical applications. Chem. Soc. Rev. 50, 6871–6913 (2021).
Su, Y. et al. Crystalline and Stable Benzofuran-Linked Covalent Organic Frameworks from Irreversible Cascade. Reactions. J. Am. Chem. Soc. 142, 13316–13321 (2020).
Vogt, C. & Weckhuysen, B. M. The concept of active site in heterogeneous catalysis. Nat. Rev. Chem. 6, 89–111 (2022).
García-Arroyo, P. et al. Pyrenetetraone-based covalent organic framework as an effective electrocatalyst for oxygen reduction reaction. Nano Res. 15, 3907–3912 (2022).
Sharma, R. K. et al. Recent development of covalent organic frameworks (COFs): synthesis and catalytic (organic-electro-photo) applications. Mater. Horizons 7, 411–454 (2020).
Wu, Q.-J. et al. Boosting Electroreduction of CO2 over Cationic Covalent Organic Frameworks: Hydrogen Bonding Effects of Halogen Ions. Angew. Chem. Int. Ed. 62, e202215687 (2023).
Long, X. et al. Heterocyclization Strategy for Construction of Linear Conjugated Polymers: Efficient Metal-Free Electrocatalysts for Oxygen Reduction. Angew. Chem. Int. Ed. 58, 11369–11373 (2019).
You, Z. et al. Metal-Free Carbon-Based Covalent Organic Frameworks with Heteroatom-Free Units Boost Efficient Oxygen Reduction. Adv. Mater. 35, 2209129 (2023).
Geng, K. et al. Covalent Organic Frameworks: Design, Synthesis, and Functions. Chem. Rev. 120, 8814–8933 (2020).
Meng, Z. & Mirica, K. A. Covalent organic frameworks as multifunctional materials for chemical detection. Chem. Soc. Rev. 50, 13498–13558 (2021).
Guan, Q., Zhou, L.-L. & Dong, Y.-B. Metalated covalent organic frameworks: from synthetic strategies to diverse applications. Chem. Soc. Rev. 51, 6307–6416 (2022).
Meng, F., Bi, S., Sun, Z., Wu, D. & Zhang, F. 2,4,6-Trimethylpyridine-Derived Vinylene-Linked Covalent Organic Frameworks for Confined Catalytic Esterification. Angew. Chem. Int. Ed. 61, e202210447 (2022).
Xu, J. et al. Vinylene-Linked Covalent Organic Frameworks (COFs) with Symmetry-Tuned Polarity and Photocatalytic Activity. Angew. Chem. Int. Ed. 59, 23845–23853 (2020).
Liu, R. et al. Covalent organic frameworks: an ideal platform for designing ordered materials and advanced applications. Chem. Soc. Rev. 50, 120–242 (2021).
Keller, N. & Bein, T. Optoelectronic processes in covalent organic frameworks. Chem. Soc. Rev. 50, 1813–1845 (2021).
Yuan, S. et al. Covalent organic frameworks for membrane separation. Chem. Soc. Rev. 48, 2665–2681 (2019).
Lu, M. et al. Confining and Highly Dispersing Single Polyoxometalate Clusters in Covalent Organic Frameworks by Covalent Linkages for CO2 Photoreduction. J. Am. Chem. Soc. 144, 1861–1871 (2022).
Lyu, H., Li, H., Hanikel, N., Wang, K. & Yaghi, O. M. Covalent Organic Frameworks for Carbon Dioxide Capture from Air. J. Am. Chem. Soc. 144, 12989–12995 (2022).
Huang, N., Krishna, R. & Jiang, D. Tailor-Made Pore Surface Engineering in Covalent Organic Frameworks: Systematic Functionalization for Performance Screening. J. Am. Chem. Soc. 137, 7079–7082 (2015).
Fu, J. et al. Fabrication of COF-MOF Composite Membranes and Their Highly Selective Separation of H2/CO2. J. Am. Chem. Soc. 138, 7673–7680 (2016).
Khan, N. A. et al. Solid-Vapor Interface Engineered Covalent Organic Framework Membranes for Molecular Separation. J. Am. Chem. Soc. 142, 13450–13458 (2020).
Yusuf, K. et al. Inverse Gas Chromatography Demonstrates the Crystallinity-Dependent Physicochemical Properties of Two-Dimensional Covalent Organic Framework Stationary Phases. Chem. Mater. 35, 1691–1701 (2023).
Zhang, F.-M. et al. Rational Design of MOF/COF Hybrid Materials for Photocatalytic H2 Evolution in the Presence of Sacrificial Electron Donors. Angew. Chem. Int. Ed. 57, 12106–12110 (2018).
Lan, Z.-A. et al. A Fully Coplanar Donor–Acceptor Polymeric Semiconductor with Promoted Charge Separation Kinetics for Photochemistry. Angew. Chem. Int. Ed. 60, 16355–16359 (2021).
Guo, C. et al. Anthraquinone Covalent Organic Framework Hollow Tubes as Binder Microadditives in Li−S Batteries. Angew. Chem. Int. Ed. 61, e202113315 (2022).
Xie, Z. et al. Stable 2D Heteroporous Covalent Organic Frameworks for Efficient Ionic Conduction. Angew. Chem. Int. Ed. 58, 15742–15746 (2019).
You, X. et al. Charged Nanochannels in Covalent Organic Framework Membranes Enabling Efficient Ion Exclusion. ACS Nano 16, 11781–11791 (2022).
Li, X. & Loh, K. P. Recent Progress in Covalent Organic Frameworks as Solid-State Ion Conductors. ACS Mater. Lett. 1, 327–335 (2019).
Ma, H. et al. Cationic Covalent Organic Frameworks: A Simple Platform of Anionic Exchange for Porosity Tuning and Proton Conduction. J. Am. Chem. Soc. 138, 5897–5903 (2016).
Xu, Q., Tao, S., Jiang, Q. & Jiang, D. Ion Conduction in Polyelectrolyte Covalent Organic Frameworks. J. Am. Chem. Soc. 140, 7429–7432 (2018).
Xu, R. et al. Well-Defined Nanostructures for Electrochemical Energy Conversion and Storage. Adv. Energy Mater. 11, 2001537 (2021).
Li, Y. et al. Targeted Synthesis of Isomeric Naphthalene-Based 2D Kagome Covalent Organic Frameworks. Angew. Chem. Int. Ed. 62, e202216795 (2023).
Chen, L. et al. Enantioselective Synthesis of Nitriles Containing a Quaternary Carbon Center by Michael Reactions of Silyl Ketene Imines with 1-Acrylpyrazoles. J. Am. Chem. Soc. 143, 19091–19098 (2021).
Su, Y. et al. Multi-Component Synthesis of a Buta-1,3-diene-Linked Covalent Organic Framework. J. Am. Chem. Soc. 144, 18218–18222 (2022).
Lu, M. et al. Stable Dioxin-Linked Metallophthalocyanine Covalent Organic Frameworks (COFs) as Photo-Coupled Electrocatalysts for CO2 Reduction. Angew. Chem. Int. Ed. 60, 4864–4871 (2021).
Wang, L. et al. Electrocleavage Synthesis of Solution-Processed, Imine-Linked, and Crystalline Covalent Organic Framework Thin Films. J. Am. Chem. Soc. 144, 8961–8968 (2022).
Xing, C. et al. Enhancing Enzyme Activity by the Modulation of Covalent Interactions in the Confined Channels of Covalent Organic Frameworks. Angew. Chem. Int. Ed. 61, e202201378 (2022).
Li, D. et al. Metal-Free Thiophene-Sulfur Covalent Organic Frameworks: Precise and Controllable Synthesis of Catalytic Active Sites for Oxygen Reduction. J. Am. Chem. Soc. 142, 8104–8108 (2020).
Chen, D. et al. Covalent Organic Frameworks Containing Dual O2 Reduction Centers for Overall Photosynthetic Hydrogen Peroxide Production. Angew. Chem. Int. Ed. 62, e202217479 (2023).
Yang, Z. et al. Arylamine-Linked 2D Covalent Organic Frameworks for Efficient Pseudocapacitive Energy Storage. Angew. Chem. Int. Ed. 60, 20754–20759 (2021).
Mu, Z. et al. Hierarchical Microtubular Covalent Organic Frameworks Achieved by COF-to-COF Transformation. Angew. Chem. Int. Ed. 62, e202300373 (2023).
Bi, S. et al. Heteroatom-Embedded Approach to Vinylene-Linked Covalent Organic Frameworks with Isoelectronic Structures for Photoredox Catalysis. Angew. Chem. Int. Ed. 61, e202111627 (2022).
Zhu, Y. et al. Construction of Interlayer Conjugated Links in 2D Covalent Organic Frameworks via Topological Polymerization. J. Am. Chem. Soc. 143, 7897–7902 (2021).
Huang, S. et al. Covalent Organic Frameworks with Molecularly Electronic Modulation as Metal-Free Electrocatalysts for Efficient Hydrogen Peroxide Production. Small Struct. 4, 2200387 (2023).
Bao, R. et al. Designing Thiophene-Enriched Fully Conjugated 3D Covalent Organic Framework as Metal-Free Oxygen Reduction Catalyst for Hydrogen Fuel Cells. Angew. Chem. Int. Ed. 62, e202216751 (2023).
Yue, J.-Y. et al. Two-dimensional porphyrin covalent organic frameworks with tunable catalytic active sites for the oxygen reduction reaction. Chem. Comm. 57, 12619–12622 (2021).
Cao, Q. et al. A Fluorinated Covalent Organic Framework with Accelerated Oxygen Transfer Nanochannels for High-Performance Zinc-Air Batteries. Adv. Mater. 35, 2210550 (2023).
Royuela, S. et al. Oxygen reduction using a metal-free naphthalene diimide-based covalent organic framework electrocatalyst. Chem. Comm. 56, 1267–1270 (2020).
Li, X. et al. Catalytic Linkage Engineering of Covalent Organic Frameworks for the Oxygen Reduction Reaction. Angew. Chem. Int. Ed. 62, e202304356 (2023).
Wei, W. F. et al. Exploiting Reusable Edge-Functionalized Metal-Free Polyphthalocyanine Networks for Efficient Polymer Synthesis at Near Infrared Wavelengths. Angew. Chem. Int. Ed. 62, e202304608 (2023).
Yan, X., Wang, B., Ren, J., Long, X. & Yang, D. An Unsaturated Bond Strategy to Regulate Active Centers of Metal-Free Covalent Organic Frameworks for Efficient Oxygen Reduction. Angew. Chem. Int. Ed. 61, e202209583 (2022).
Li, D. et al. Controlled Asymmetric Charge Distribution of Active Centers in Conjugated Polymers for Oxygen Reduction. Angew. Chem. Int. Ed. 60, 26483–26488 (2021).
Li, X. et al. Constructing ambivalent imidazopyridinium-linked covalent organic frameworks. Nat. Synth. 1, 382–392 (2022).
Xu, J. et al. An Olefin-Linked Covalent Organic Framework as a Flexible Thin-Film Electrode for a High-Performance Micro-Supercapacitor. Angew. Chem. Int. Ed. 58, 12065–12069 (2019).
Meng, F. et al. Synthesis of Ionic Vinylene-Linked Covalent Organic Frameworks through Quaternization-Activated Knoevenagel Condensation. Angew. Chem. Int. Ed. 60, 13614–13620 (2021).
Xu, X., Cai, P., Chen, H., Zhou, H.-C. & Huang, N. Three-Dimensional Covalent Organic Frameworks with she Topology. J. Am. Chem. Soc. 144, 18511–18517 (2022).
Xu, X. et al. Janus Dione-Based Conjugated Covalent Organic Frameworks with High Conductivity as Superior Cathode Materials. J. Am. Chem. Soc. 145, 1022–1030 (2023).
Ge, X. et al. Oxygen Reduction in Alkaline Media: From Mechanisms to Recent Advances of Catalysts. ACS Catal. 5, 4643–4667 (2015).
Zhang, H., Lin, Z., Kidkhunthod, P. & Guo, J. Stable Immobilization of Nickel Ions on Covalent Organic Frameworks for Panchromatic Photocatalytic Hydrogen. Evolution. Angew. Chem. Int. Ed. 62, e202217527 (2023).
Shang, H. et al. Engineering unsymmetrically coordinated Cu-S1N3 single atom sites with enhanced oxygen reduction activity. Nat. Commun. 11, 3049 (2020).
Zhou, Y. et al. Asymmetric dinitrogen-coordinated nickel single-atomic sites for efficient CO2 electroreduction. Nat. Commun. 14, 3776 (2023).
Xie, Y. et al. Tuning the Topology of Three-Dimensional Covalent Organic Frameworks via Steric Control: From pts to Unprecedented ljh. J. Am. Chem. Soc. 143, 7279–7284 (2021).
Liu, M. et al. Post-synthetic modification of covalent organic frameworks for CO2 electroreduction. Nat. Commun. 14, 3800 (2023).
Mi, Z. et al. Covalent Organic Frameworks Enabling Site Isolation of Viologen-Derived Electron-Transfer Mediators for Stable Photocatalytic Hydrogen Evolution. Angew. Chem. In. Ed. 60, 9642-9649 (2021).
Yue, Y., Li, H., Chen, H. & Huang, N. Piperazine-Linked Covalent Organic Frameworks with High Electrical Conductivity. J. Am. Chem. Soc. 144, 2873–2878 (2022).
Cheng, W. et al. Lattice-strained metal-organic-framework arrays for bifunctional oxygen electrocatalysis. Nat. Energy 4, 115–122 (2019).
Xu, H. et al. Proton conduction in crystalline and porous covalent organic frameworks. Nat. Mater. 15, 722–726 (2016).
Xu, H. et al. Stable, crystalline, porous, covalent organic frameworks as a platform for chiral organcatalysts. Nat. Chem. 7, 905–912 (2015).
Wu, D. et al. Bimetallic Covalent Organic Frameworks for Constructing Multifunctional Electrocatalyst. Chem. Eur. J. 25, 3105–3111 (2019).
Geng, S.-K. et al. Nickel ferrocyanide as a high-performance urea oxidation electrocatalyst. Nat. Energy 6, 904–912 (2021).
Acknowledgements
The authors acknowledge the financial supports from the National Natural Science Foundation of China (52303288, 22075309, 22378413), Science and Technology Innovation Plan of the Science and Technology Commission of Shanghai Municipality (22ZR1470100, 23DZ1202600, 23DZ1201804), the Youth Innovation Promotion Association of Chinese Academy of Sciences (E324441401), and Biomaterials and Regenerative Medicine Institute Cooperative Research Project Shanghai Jiao Tong University School of Medicine (2022LHA09). Dr. Yubin Fu gratefully acknowledge the GWK support for funding this project by providing computing time through the Center for Information Services and HPC (ZIH) at TU Dresden. The authors also thank the infrared beamline BL01B from the National Synchrotron Radiation Laboratory for proving support for materials characterization.
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Q. X. conceived the idea and designed the experiments. X. Y. and Q. A. performed the experiments. Y. Fu contributed to the theory calculation part. X. L., S. Y. and M. L. participated in some experiments. X. Y., Q. X. and G. Z. wrote and revised the manuscript. All the authors contributed to the data interpretation, discussion, and manuscript revision. All authors have given approval to the final version of the manuscript. X. Y., and Q. A. contributed equally to this work.
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Yang, X., An, Q., Li, X. et al. Charging modulation of the pyridine nitrogen of covalent organic frameworks for promoting oxygen reduction reaction. Nat Commun 15, 1889 (2024). https://doi.org/10.1038/s41467-024-46291-y
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DOI: https://doi.org/10.1038/s41467-024-46291-y
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