Universal synthesis of coral-like ternary MOF-derived sulfides as efficient OER electrocatalysts

Tianpeng Liu a, Yangping Zhang a, Jun Yu a, Mengyun Hu a, Zhengying Wu *b, Xiao Wei a, Shudi Yu a and Yukou Du *a
aCollege of Chemistry, Chemical Engineering and Materials Science, Soochow University, Industrial Park, Renai Road, Suzhou 215123, PR China. E-mail: duyk@suda.edu.cn
bJiangsu Key Laboratory for Environment Functional Materials, School of Materials Science and Engineering, Suzhou University of Science and Technology, Suzhou 215009, China. E-mail: zywu@mail.usts.edu.cn

Received 9th July 2024 , Accepted 25th July 2024

First published on 26th July 2024


Abstract

The strategy of synthesizing high-efficiency oxygen evolution reaction (OER) catalysts using sacrificing metal–organic framework (MOF) templates is considered promising. However, few reports have focused on improving the intrinsic electrocatalytic activity of the MOF templates. Herein, we have developed a universal synthesis method for synthesizing a series of ternary coral-like FeNiM (M = Zn, Co and Cd) MOF templates. Benefitting from the synergistic effect, these trimetallic templates exhibit identical morphologies and outstanding OER performance compared to mono-metal templates. Moreover, transition metal sulfides (FeNiZnS) have been synthesized to enhance the overall electrical conductivity of catalyst materials. Optimized FeNiZnS-1 exhibits a minimal overpotential of 249 mV to achieve a current density of 10 mA cm−2, alongside outstanding electrochemical durability over 60 h in chronopotentiometry (CP) testing. The two-electrode couple FeNiZnS-1//Pt/C achieves a cell voltage of 1.54 V at 10 mA cm−2 for overall water splitting in 1 M KOH solution.


Introduction

Climate deterioration has intensified the global demand for a new energy revolution. The development of renewable and non-polluting new green energy and storage modes has achieved consensus among governments worldwide.1,2 Clean energy sources such as hydrogen, wind, hydropower, and solar power hold promise as viable alternatives for traditional fossil energy. Hydrogen not only has the highest energy density found in fuels, but also serves as an effective form of energy storage, reducing the wastage of other clean energy.3 Hydrogen can be classified into three categories based on its production process: green hydrogen, grey hydrogen, and blue hydrogen.4,5 Among these, green hydrogen has attracted significant attention due to its minimal environmental pollution during production. Compared to the photoelectrochemical water splitting, the electrolysis of water for green hydrogen production has achieved initial industrialization with a higher energy conversion efficiency.6,7 However, the sluggish kinetics of the anodic half-reaction (oxygen evolution reaction, OER) has resulted in a high overpotential in the overall water splitting.8,9 Numerous catalytic materials have been developed to reduce the overpotential of the OER. Noble metal oxides (such as IrO2 and RuO2) demonstrate superior catalytic performance compared to transition metal-based electrocatalysts.10,11 But the rare sources and high cost restrict the widespread application of noble metal-based catalytic materials. Therefore, balancing the cost and performance of catalytic materials is key to solving the high overpotential issue in water splitting.

The multifunctional porous materials, metal–organic frameworks (MOF), have been widely employed in the field of electrocatalysis over the past two decades.12–14 Due to their intrinsic low electrical conductivity, pristine MOFs are not directly used as OER electrocatalysts.15 However, utilizing pristine MOFs as templates or sacrificing precursor materials for the synthesis of MOF-derived electrocatalysts (metal phosphides, metal sulphides, and metal oxides) possesses remarkable advantages.16–19 Benefiting from the diverse chemical compositions and structures, converting pristine MOFs into MOF-derived electrocatalysts can significantly enhance the electrocatalytic performance of the materials. The OER performance of classic MOF templates (such as ZIF8, ZIF67 and MIL53) is often limited by their mono-metal active sites and poor conductivity.20,21 Conventional optimization strategies mainly aim to transform templates into MOF-derived catalysts, with few researchers focusing on enhancing the intrinsic performance of MOF templates.22 MOF-derived sulphides inherit the inherent advantages of high specific surface area and high porosity.23–25 Furthermore, the organic ligands transform into carbon frameworks during high-temperature sulfidation, enhancing the conductivity of the material and facilitating electron transfer in electrochemical reactions.26,27 Unfortunately, during the hydrothermal sulfidation process, the morphology of MOF templates is susceptible to being destroyed, resulting in a low electrocatalytic performance.28,29 Thus, it is necessary to intricately regulate the reaction time and temperature in order to achieve preservation of the MOF morphology.

In this work, we have developed a universal synthetic strategy and successfully synthesized a series of coral-like ternary MOF templates. Benefitting from the synergistic effect of transition metals, these trimetallic templates exhibit significantly superior fundamental OER performance compared to conventional mono-metal templates, with overpotentials between 280 and 400 mV at a current density of 10 mA cm−2. Furthermore, by regulating the hydrothermal sulphuration time, ternary metal sulphide (FeNiZnS-1) is synthesized without destroying the original morphology of the FeNiZn template. FeNiZnS-1 exhibits a low overpotential of 249 mV to reach a current density of 10 mA cm−2, with a Tafel slope of 41.4 mV dec−1. Meanwhile, it also demonstrates remarkable electrochemical durability in the OER and overall water splitting.

Results and discussion

As shown in Scheme 1, the MOF templates are synthesized via a convenient one-pot hydrothermal method. Various metal salts and 1,3,5-trimesic acid (H3BTC) are dissolved in a DMF solution. The mixture undergoes a 24 h reaction at 170 °C in a Teflon-lined autoclave to yield the respective MOF templates.30 The monometallic Fe-MIL100 formed by the coordination of Fe3+ and H3BTC exhibits a polyhedral structure with octahedra.31 When the Ni element is added into the reaction system, the bimetallic FeNi-MOF exhibits a topological structure similar to Fe-MIL100.32 However, when the third transition element (M = Zn, Co or Cd) participates in the reaction system, the morphology of the trimetallic MOF undergoes a transformation, forming a coral-like nanostructure (Fig. S1). It can be observed that the slight differences in sizes of the three MOF templates can be ascribed to differences in the coordination abilities of various transition metals.33,34
image file: d4qi01725k-s1.tif
Scheme 1 The synthetic procedures of the trimetallic MOF template and FeNiZnS catalysts.

The trimetallic FeNiZn template is transformed into the MOF-derived sulfide through hydrothermal sulfurization at 150 °C. According to the duration of sulfurization time, trimetallic sulfides can be divided into FeNiZnS-1, FeNiZnS-2, and FeNiZnS-3. As shown in Fig. S2, the coral-like nanostructures of the trimetallic FeNiZn template are gradually destroyed with increasing sulfidation time, ultimately transforming into dispersed nanosulfides. By controlling the reaction time, conversion of sulfides and protection of the coral-like morphology can be achieved.

The morphological characterization of the FeNiZn template and FeNiZnS-1 is recorded and shown in Fig. 1. As shown in Fig. 1a and b, the ternary FeNiZn template exhibits a uniform coral-like morphology as expected. Good dispersibility allows the FeNiZn template to fully come in contact with the sulfur source during the vulcanization process. It can be easily observed that FeNiZnS-1 synthesized through 1 h hydrothermal sulfidation still retains a clear coral-like nanostructure (Fig. 1c and d). Similarly, the intricate coral-like stacking of FeNiZnS-1 is revealed through HAADF-STEM (Fig. S3a). The crystallinity of the material is determined by high-resolution TEM. As shown in Fig. S3b, no clear lattice fringes are observed for FeNiZnS-1, indicating its amorphous structure. The long-range disordered amorphous structure of FeNiZnS-1 provides potential active sites for participating in catalytic reaction processes.35 In addition, the EDS spectra of the trimetallic templates and sulfides reflect the elemental composition of the catalysts (Fig. S4 and S5). The trimetallic templates and sulfides both manifest the anticipated elemental proportion, confirming the stable synthesis capability of this system. Furthermore, STEM-EDX elemental mapping is utilized to analyze the elemental composition and distribution of FeNiZnS-1. As depicted in Fig. 1e, FeNiZnS-1 exhibits a homogeneous elemental distribution of Fe, Ni, Zn and S, confirming the formation of trimetallic sulfides.


image file: d4qi01725k-f1.tif
Fig. 1 Morphological characterization of FeNiZn and FeNiZnS-1: (a) TEM image of FeNiZn, (b) SEM image of FeNiZn, (c) TEM image of FeNiZnS-1, (d) SEM image of FeNiZnS-1, and (e) elemental mappings of FeNiZnS-1.

The XRD patterns depicted in Fig. 2a demonstrate a similar conclusion, consistent with the previous analysis. Apart from the derivative peaks attributed to MOFs themself, ternary metal sulfides did not exhibit distinct diffraction peaks, confirming the prior conclusions regarding the low crystallinity of FeNiZnS-1. The diffraction peaks of the FeNiZn template located at 10.54° and 25.34° gradually diminish with increasing sulfidation time, indicating the transformation of the pristine MOF. It is worth noting that the diffraction peaks located at 20.73° and 22.73° correspond to the (202) and (114) crystal planes of NiSO4·6H2O (PDF#79-0189), and the peak at around 32.38° is assigned to the (200) crystal plane of (FeNi)S2 (PDF#02-0850), respectively. This indicates that the generation of NiSO4·6H2O and (FeNi)S2 may be the primary factor leading to the collapse of the coral-like nanostructure.


image file: d4qi01725k-f2.tif
Fig. 2 (a) XRD patterns of FeNiZn, FeNiZnS-1, FeNiZnS-2, and FeNiZnS-3. XPS spectra of FeNiZnS-1, (b) survey scan, (c) Fe 2p, (d) Ni 2p, (e) Zn 2p and (f) S 2p.

Moreover, a series of X-ray photoelectron spectroscopy (XPS) tests are employed to assess the elemental valence of catalytic materials. Compared to the FeNiZn template, the FeNiZnS-1 catalyst exhibits a distinct S 2p peak in the survey scan, indicating the successful introduction of sulfur during the sulfidation process (Fig. 2b). Additionally, the constituent elements in FeNiZnS-1 have been thoroughly examined. As illustrated in Fig. 2c, the peaks located at 711.27 and 714.98 eV are matched with Fe 2p3/2 and Fe 2p1/2.36 Notably, the Ni 2p spectrum of FeNiZnS-1 (Fig. 2d) displays characteristic peaks at 856.05, 860.87 and 853.08 eV, which correspond to Ni 2p3/2, Ni 2p1/2 and Ni0.37 In addition, in the high-resolution Zn 2p spectrum (Fig. 2e), the peaks found at 1022.08 and 1045.08 eV are attributed to Zn 2p3/2 and 2p1/2, respectively.38 The S 2p XPS spectra of FeNiZnS-1 are depicted in Fig. 2f. The peaks observed at 162.2 and 163.5 are ascribed to S2− 2p3/2 and S22− 2p1/2 and S22− 2p1/2, which correspond to the bond between the metal and sulfur, indicating the conversion of the MOF into metal sulfide.39 Likewise, the characteristic peak at around 168.65 eV indicates the generation of S–O bonds in the FeNiZnS-1 sample when exposed to air.40 Additionally, by testing samples with different degrees of sulphuration, we can explore changes in the valence states of each element during the reaction process (Fig. S6–S8). As depicted in Fig. S9a, the binding energy of Fe 2p3/2 and Ni 2p3/2 in FeNiZnS-1 leads to an upward shift, whereas the binding energy of Zn results in a negative shift. With increasing sulphuration time, the binding energies of Fe, Ni, and Zn elements exhibit a positive shift. In FeNiZnS-1, the valences of Fe and Ni species increase while those of Zn species decrease. Electron transfer occurs from Fe and Ni species to Zn species, confirming that sulfidation alters the electronic structure of the FeNiZn template.41 In the S 2p energy level, the ratio of S–O to M–S peak areas increases with prolonged sulphuration time, thereby confirming conclusions drawn from XRD analysis regarding the formation of NiSO4·6H2O species. So, through a detailed analysis of the morphological structure, elemental distribution, phases, and surface chemical environment of FeNiZnS-1, the successful synthesis of the FeNiZnS-1 catalyst can be clearly verified.

Relevant electrochemical experiments are conducted with a glassy carbon electrode as the working electrode in a 1 M KOH solution at room temperature. To prepare the catalyst ink, 3 mg of catalyst and 3 mg carbon black were dispersed in a solution containing 0.99 mL of ethanol and 10 μL of Nafion, followed by sonication for 30 min. The linear sweep voltammetry curves (LSVs) of common monometallic templates (ZIF8 and ZIF67) are recorded and shown in Fig. S10 to evaluate the enhancement of the OER activity of the trimetallic template compared to that of the monometallic template. ZIF8 and ZIF67 exhibit an unsatisfactory OER performance, requiring overpotentials of 412 and 510 mV to attain a current density of 10 mA cm−2, respectively. As depicted in Fig. 3a and b, the FeNiZn, FeNiCo and FeNiCd templates possess an outstanding electrocatalytic performance, with overpotentials of only 298, 287 and 374 mV at 10 mA cm−2, significantly lower than those of the monometallic templates. This indicates that the metal sites of trimetallic catalysts and the synergistic effects of transition metal elements contribute additional efficacious active sites for the OER process, enhancing the overall catalytic performance of the material. Furthermore, in order to delve into the intrinsic activity of the trimetallic template, the data of the Tafel slope are determined by fitting the LSV at a scanning rate of 5 mV s−1 (Fig. 3c). The FeNiZn template exhibits a Tafel slope of 71.1 mV dec−1, lower than those of FeNiCo (97.7 mV dec−1) and FeNiCd (112.4 mV dec−1) templates. The electrochemical impedance spectroscopy (EIS) plot reveals the charge transfer resistance of the trimetallic templates. FeNiCd exhibits a larger charge transfer resistance compared to FeNiZn and FeNiCo, which confirms that FeNiZn and FeNiCo have better performance due to their higher electron transfer efficiency in reactions (Fig. 3d and Table. S1). Furthermore, the double layer capacitance (Cdl) value and electrochemically active surface area (ECSA) of the electrocatalysts are obtained through CV tests conducted at different scanning rates (10 mV s−1 to 50 mV s−1). Similarly, the FeNiZn template exhibits the highest Cdl value (1.91 mF cm−2) compared to FeNiCo (1.88 mF cm−2) and FeNiCd (0.67 mF cm−2), indicating the largest abundance of active sites during the electrochemical process (Fig. S11). These electrochemical characterization results verify that the FeNiZn template possesses superior electronic transport capabilities, effective active surface area and catalytic kinetics compared to other trimetallic templates. We have conducted basal evaluations of the OER performance of two types of template sulfides (FeNiZnS and FeNiCoS). As shown in Fig. S12, FeNiZnS exhibits better OER performance than its precursor, while FeNiCoS does not exhibit significant performance enhancement compared to the precursor. On the whole, the FeNiZn template is more suitable as a precursor for MOF-derived sulfides.


image file: d4qi01725k-f3.tif
Fig. 3 Electrochemical OER performance of trimetallic templates (FeNiZn, FeNiCo and FeNiCd). (a) LSV curves, (b) the corresponding overpotential histograms, (c) Tafel slope, and (d) EIS Nyquist plots.

Thanks to the remarkable OER performance of the ternary FeNiZn template, a series of ternary sulfide electrocatalysts are synthesized through a one-step hydrothermal sulfidation at different reaction times (1–3 h). As shown in Fig. 4a, the FeNiZnS-1 electrocatalyst demonstrates the most favorable overpotential of 249 mV at 10 mA cm−2, a reduction of 49 mV compared to that of the FeNiZn template. This indicates that the amorphous coral-like nanostructure of FeNiZnS-1 with rich active sites could reduce the activation energy barrier, enhancing the OER performance of electrocatalysts. With the time of sulfidation increasing, FeNiZnS-2 and FeNiZnS-3 show higher overpotentials of 271 mV and 324 mV to drive a current density of 10 mA cm−2 (Fig. 4b). The deterioration of performance is attributed to the disruption of the template's coral-like nanostructure, reduction of effective electron transfer pathways, and formation of inert NiSO4·6H2O, matching with previous XRD analysis results. The kinetic characteristics of FeNiZnS-1 and other electrocatalysts are investigated using the Tafel slope (Fig. 4c). The FeNiZnS-1 electrocatalyst exhibits a low Tafel slope of 41.45 mV dec−1, which is obviously lower than those of FeNiZnS-2 (89.3 mV dec−1), FeNiZnS-3 (114.2 mV dec−1) and commercial RuO2 (165.1 mV dec−1), indicating the fastest OER kinetics mechanism. As shown in Fig. 4d, the EIS Nyquist diagrams are obtained across frequency values ranging from 100 kHz to 1 Hz and fitted with an equivalent circuit model. FeNiZnS-1 displays a low charge transfer resistance (Rct) of 9.14 Ω, which is lower than those of FeNiZnS-2 (15.12 Ω), FeNiZnS-3 (19.37 Ω) and commercial RuO2 (120.8 Ω). The charge transfer resistance of trimetallic sulfides is significantly lower than that of the FeNiZn template, confirming that the sulfidation process significantly enhances the overall electrical conductivity of the materials, which is beneficial for charge transfer during the OER process. Similarly, the ECSA of trimetallic sulfides can be determined through the evaluation of the Cdl value (Fig. S13). The FeNiZnS-1 electrocatalyst has a larger Cdl value (2.15 mF cm−2) than FeNiZnS-2 (1.19 mF cm−2) and FeNiZnS-3 (0.64 mF cm−2). Furthermore, the chronopotentiometry (CP) test is conducted to assess the stability of catalysts under a current density of 10 mA cm−2 (Fig. 4e). FeNiZnS-1 shows remarkable long-term stability, exhibiting a negligible alteration in activity even after a duration of 60 h. In addition, the OER performance of FeNiZnS-1 is compared with that of metal sulfides and carbon black materials in recent years (Fig. S14 and Table S2). It could be obviously observed that the FeNiZnS-1 catalysts outperform many kinds of previously reported sulfides and carbon black materials.


image file: d4qi01725k-f4.tif
Fig. 4 Electrochemical performance and stability testes of trimetallic sulfides. (a) LSV curves of catalysts under different sulfidation times, (b) overpotential histograms, (c) Tafel slope fitted by LSV curves, (d) AC impedance test of FeNiZnS-1, FeNiZnS-2 and FeNiZnS-3, and (e) chronopotentiometry test at 10 cm−2.

Moreover, in order to investigate deeply the electrocatalytic activity origins of trimetallic sulfides, a series of physical characterization studies and analyses are conducted on FeNiZnS-1 after the OER (FeNiZnS-1/AO). As depicted in Fig. 5a, it is obvious that when coupled with conductive carbon black, the trimetallic sulfides exhibit a surface covered with carbon black. HRTEM is employed for further examination of the relationship between carbon black and active species. The interlayer spacing of 0.38 nm is attributed to the result calculated using Bragg's law based on the (002) planes of carbon, confirming the successful loading of carbon black (Fig. S15).42 As shown in Fig. 5b and c, following electrochemical testing, a portion of the amorphous phase underwent crystalline transformation, resulting in the formation of an amorphous/crystalline interface.43 The crystalline phase structure and carbon black fillers indeed enhanced the overall electrical conductivity of the material. Similarly, Fig. 5d illustrates two distinct lattice planes with interplanar spacings of 0.29 nm and 0.31 nm, corresponding to the (220) plane of FeOOH and the (110) plane of NiOOH.44 The conductive carbon black possesses a high specific surface area capable of adsorbing the active species MOOH generated during the OER process, thereby preventing the aggregation of active species and the reduction of electrocatalytic activity.45,46 Raman spectroscopy is used to assess alterations in the defect density of carbon materials during reaction processes (Fig. 5f). The D band and G band are located at 1350 cm−1 and 1580 cm−1 respectively, representing the degree of material defects and the stretching vibration mode of C sp2 hybridization. The ratio (ID/IG) of FeNiZnS-1/AO shows an increasing trend compared to FeNiZnS-1, indicating that the carbon black and generation of active species promoted the overall electrocatalyst defectiveness.47 XRD is used to investigate the phase composition of FeNiZnS-1/AO. The peak located at 25° is attributed to the (002) graphite-type reflections (Fig. S16).48 The absence of distinct diffraction peaks for hydroxylated oxides (MOOH) is due to them being masked by the peaks of carbon black. The elemental surface compositions and chemical states of products after electrochemical tests are assessed. In the S 2p spectrum for FeNiZnS-1/AO (Fig. S17a), the peaks of 2p3/2 and 2p3/2 exhibit a conspicuous diminution, indicating the transformation of metal sulfides into low-crystallinity (oxy)hydroxide during the anodic OER process. The augmentation of the S–O peak located at 168.7 eV is due to the oxidation of S species to SO42− under high oxygenation conditions at the anode.49 As illustrated in Fig. S16b, the binding energy of Ni 2p3/2 and 2p1/2 has a slight upshift in comparison with that of FeNiZnS-1, suggesting the generation of active species with high oxidation states. The characteristic peak at 857.85 eV is attributed to Ni3+ of NiOOH.50 Moreover, it is observed that there is an occurrence of zinc species dissolution during the transition from metal sulfides to (oxy)hydroxides (Fig. 5e). Finally, the d-band centers of trimetallic sulfides are measured based on high-resolution X-ray photoelectron spectroscopy (HR-XPS).51,52 As shown in the diagram in Fig. S18, the d-band center values of FeNiZn and FeNiZnS-1 are −7.71 and −7.38 eV, respectively. After sulfurization, the d-band center of FeNiZnS-1 becomes closer to the Fermi level, indicating enhanced interaction between the oxygen-containing intermediate and the catalyst surface.53 In summary, FeNiZnS-1 exhibits excellent electrical conductivity and transforms into real time catalytic active species (MOOH) during the OER process, after coupling with carbon black. Benefiting from the preserved coral-like morphology and synergistic effects among transition metals, FeNiZnS-1 demonstrated outstanding OER catalytic potential as a pre-catalyst.


image file: d4qi01725k-f5.tif
Fig. 5 The physical characterization images of FeNiZnS-1/AO: (a) TEM, (b, c and d) HRTEM, (e) SEM-EDS, and (f) Raman.

To evaluate the application prospects of electrocatalysts, we constructed a two-electrode system of FeNiZnS-1//Pt/C to drive overall water splitting in a 1 M KOH solution (Fig. 6a). The FeNiZnS-1//Pt/C electrode requires only 1.54 V to achieve a current density of 10 mA cm−2, which is obviously lower than those of FeNiZn//Pt/C (1.63 V) and commercial RuO2//Pt/C (1.67 V) electrodes (Fig. 6b). In addition, the electrochemical stability of FeNiZnS-1//Pt/C is evaluated through a long-term chronopotentiometry (CP) test at 10 mA cm−2. As depicted in Fig. 6c, FeNiZnS-1//Pt/C exhibits a slight potential rise over a 50 h overall water splitting test, demonstrating excellent electrochemical stability compared to commercial RuO2//Pt/C electrodes.


image file: d4qi01725k-f6.tif
Fig. 6 (a) Schematic image, (b) LSV curves of FeNiZn//Pt/C, FeNiZnS-1//Pt/C and commercial RuO2//Pt/C, and (c) CP test in alkaline solution.

Conclusions

In summary, based on a facile hydrothermal method, we have synthesized a series of coral-like ternary MOF templates with similar morphologies. The further optimized FeNiZnS-1 has the following advantages during the OER process. (i) Benefiting from the synergistic effect of transition metals, the FeNiZn sacrificial template exhibits better OER activity than conventional mono-metal templates. (ii) Appropriate vulcanization time improves the electron transmission capability of the catalyst, while ensuring the integrity of the coral-like morphology. (iii) FeNiZnS-1 exhibits outstanding OER (overpotential of 249 mV at 10 mA cm−2) and overall water splitting performance (1.54 V at 10 mA cm−2). In addition, the real-time active species (NiOOH and FeOOH) in the OER are determined by analyzing the morphological changes, physical phases, and electronic structures of the post-reaction products. The synthesis method of high-performance multi-metal MOF templates and the FeNiZn MOF-derived sulfides in this work may offer insights for the development of efficient OER electrocatalysts.

Data availability

The data that support the findings of this study are available from the corresponding author, upon reasonable request.

Conflicts of interest

There are no conflicts to declare.

Acknowledgements

This work was supported by the National Natural Science Foundation of China (Grant No. 52073199 and 52274304).

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