DOI:
10.1039/D2RA08096F
(Paper)
RSC Adv., 2023,
13, 10681-10692
Facile synthesis approach of bifunctional Co–Ni–Fe oxyhydroxide and spinel oxide composite electrocatalysts from hydroxide and layered double hydroxide composite precursors†
Received
19th December 2022
, Accepted 13th March 2023
First published on 4th April 2023
Abstract
Zinc–air batteries (ZABs) are promising candidates for the next-generation energy storage systems, however, their further development is severely hindered by kinetically sluggish oxygen evolution reaction (OER) and oxygen reduction reaction (ORR). Facile synthesis approaches of highly active bifunctional electrocatalysts for OER and ORR are required for their practical applications. Herein, we develop a facile synthesis procedure for composite electrocatalysts composed of OER-active metal oxyhydroxide and ORR-active spinel oxide containing Co, Ni and Fe from composite precursors consisting of metal hydroxide and layered double hydroxide (LDH). Both hydroxide and LDH are simultaneously produced by a precipitation method with a controlled molar ratio of Co2+, Ni2+ and Fe3+ in the reaction solution, and calcination of the precursor at a moderate temperature provides composite catalysts of metal oxyhydroxides and spinel oxides. The composite catalyst shows superb bifunctional performances with a small potential difference of 0.64 V between a potential of 1.51 V vs. RHE at 10 mA cm−2 for OER and a half-wave potential of 0.87 V vs. RHE for ORR. The rechargeable ZAB assembled with the composite catalyst as an air-electrode exhibits a power density of 195 mA cm−2 and excellent durability of 430 hours (1270 cycles) of a charge–discharge cycle test.
Introduction
With the rapidly growing demands for renewable energy, rechargeable zinc–air batteries (ZABs) have caught great attention due to their considerable energy density, low cost, safety, and high theoretical energy storage capacity (1218 W h kg−1).1,2 However, the greatest challenges for ZABs are poor cycle life and high overpotentials due to the kinetically sluggish oxygen evolution reaction (OER) and the oxygen reduction reaction (ORR) at the cathode in alkaline media. The performances of current ZABs hardly satisfy the requirements of practical applications.3–5 Thus, tremendous efforts have been devoted to developing highly active bifunctional OER and ORR electrocatalysts.6–10 Currently, Ru and Pt-based precious metal electrocatalysts have been reported as the best OER and ORR catalysts.11,12 Although Pt-based catalysts are the best ORR catalysts, they are ineffective for OER. Likewise, the most active catalysts for the OER do not offer the best ORR catalysis performance. Calculation studies reported that the intrinsic activities for OER and ORR depend on the adsorption energy of intermediates on active sites, and the scaling relationship between the adsorption energy of intermediates prevents any compound with a single site from being both ORR and OER active.13,14 Thus, combining an ORR active catalyst with an OER active catalysts have been examined to obtain bifunctional composite catalysts as another approach.15 Because scarcity and high cost are hindered commercial applications of the noble metal compounds, there has been a great deal of research effort to develop inexpensive, robust, and efficient bifunctional electrocatalysts for rechargeable ZABs. Abundant Co-based multi transition metal compounds, including metal oxyhydroxides and spinel oxides, are expected as candidates of OER and ORR electrocatalysts16 which have shown higher performances than those of monometallic ones.17
Metal oxyhydroxides have attracted much attention as an electrocatalyst for OER. While the OER activities of monometallic CoOOH are very low, including other transition metals such as Fe and Ni has drastically enhanced the performances.18–20 Since the performances of multi-metal oxyhydroxide deeply depends on the kinds and compositions of metals, precise control of metal composition results in outstanding catalytic activities. A metal oxyhydroxide composed of Co, Ni, and Fe has exhibited higher OER activates than RuO2 electrocatalyst;18,20,21 trimetallic oxyhydroxides are promising materials for OER due to their composition versatility. Spinel oxides are one of the most extensively studied electrocatalysts for ORR.22 Many researchers reported that Co3O4 nanoparticles loaded on carbon materials such as nitrogen-doped reduced graphene oxide23,24 and carbon nanotube25,26 showed superb ORR activities. Furthermore, Co-based spinel oxides with partial substitution of Ni and Fe have exhibited great potential in enhancing ORR activities,27–29 indicating advantages of multi metallic composition to improve activities for spinel oxide electrocatalysts as well.
The composites of metal oxyhydroxide and spinel oxide composed of Co, Ni and Fe are expected to be highly active bifunctional electrocatalysts for ZABs, however, very few studies have been reported for OER and ORR.30 In addition, the synthesis procedures should be as simple as possible without complicated operations from the viewpoint of practical applications. It is known that hydroxides can be converted to oxyhydroxides and layered double hydroxides (LDHs) to spinel oxides by calcination at moderate temperatures.31–34 On the other hand, some studies have reported the formation of metal hydroxides as a byproduct in the synthesis of LDH.35,36 Therefore, we expect that composite precursors of multi-metal hydroxides and LDHs are synthesized by the precipitation method and that calcination of the precursors at an appropriate temperature yields the composite of metal oxyhydroxide and spinel oxide, providing highly active bifunctional electrocatalysts (Scheme 1).
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| Scheme 1 Illustration of synthesis of bifunctional composite electrocatalyst of metal oxyhydroxide and spinel oxide from composite precursors of hydroxide and LDH. | |
In this study, composite precursors of multi-metal hydroxides and LDHs containing Co, Fe and Ni are synthesized by a simple precipitation method and then calcined to synthesize oxyhydroxide and spinel oxide composite catalysts. The crystal structures of the precursors and catalysts are controlled by examining the metal composition and calcination temperature, and the synthesized catalysts are applied to OER and ORR in highly concentrated alkaline solutions. The catalysts are also applied as gas diffusion electrodes in half-cell and ZAB, and their activity and durability are investigated.
Experimental
Catalyst preparation
All of the chemicals were used as received without further purification. All precursors were prepared by a precipitation method. The desired amounts of Co(NO3)2·6H2O, Ni(NO3)2·6H2O and Fe(NO3)3·9H2O (Kanto Chemical Co., Inc.), of which the total metal concentration corresponding to 0.1 mol dm−3 aqueous solution, were dissolved in 150 cm3 pure water to obtain a transparent homogeneous solution. A 1.0 mol dm−3 KOH solution was quickly added in the above solution with vigorous stirring and then precipitation formed. The suspension was kept stirring for 1 h under the atmosphere, followed by filtration and washing with pure water and ethanol. The precipitation was dried in vacuo at room temperature for several hours, and then the precursors were obtained. The precursors were calcined at 100, 150 and 200 °C for 12 h under O2 gas, and then the catalysts were obtained. Hereafter, the precursors and catalysts are designated CoXNiYFeZ and CoXNiYFeZ (T), respectively, where X, Y and Z means metal ratio in the samples determined by energy-dispersive X-ray spectroscopy (EDS) measurement (X + Y + Z = 100) and T means calcination temperature in degrees Celsius.
Characterization
The phase of samples was examined by X-ray powder diffraction (XRD, Rigaku, Ultima IV) using Cu Kα radiation (λ = 0.15418 nm, U = 40 kV, I = 20 mA). Morphology of the prepared samples was observed using a low-voltage scanning electron microscope (SEM, Zeiss, Sigma-500) operated at 1.5 kV. The morphology and composition of the samples were also analyzed using a scanning transmission electron microscope (STEM, JEOL, JEM-ARM200F) with EDS facilities. The metal composition of catalysts was also determined by analyzing solution of the samples dissolved in acid using the inductively coupled plasma atomic emission spectroscopy (ICP-AES) (Shimadzu, ICPE-9000). The specimens of electrodes for cross-section observation were prepared using a cross-section polisher (JEOL, IB-19530CP).
Electrochemical measurement
The electrocatalytic activity was evaluated by the rotating disk electrode (RDE; Pine Instrument Co. Ltd.) system using the catalyst-loaded glassy carbon disk electrode. For the preparation of catalyst inks, 50 mg of the prepared catalysts and carbon conductive additive (Acetylene black) with a 5:1 mass ratio were dispersed ultrasonically in a mixture of 0.2 mL of 5 wt% Na+-exchanged Nafion solution and 4.8 mL of iso-propanol. Nafion was added as a binder and neutralized before dispersion to prevent the catalysts from undergoing acidic dissolution due to the lower pH of the Nafion binder.21 The ink (5 μL) was coated on the glassy carbon disk electrode. The electrochemical measurements were carried out using a three-electrode system connected with VersaSTAT 4 potentiostat/galvanostat (Princeton Applied Research). A platinum coil and Hg/HgO/4 mol dm−3 KOH were used as counter and reference electrodes, respectively. All measurements were carried out at room temperature in a 4 mol dm−3 KOH aqueous solution (pH = 14). The electrocatalytic activity was evaluated using linear sweep voltammetry (LSV) with a potential sweep rate of 1 mV s−1. The electron transfer number during ORR was evaluated by the RRDE method under the ring electrode potential of 1.4 V vs. RHE.37,38 The potential was converted from the Hg/HgO/4 mol dm−3 KOH reference scale to the RHE using the following equation: |
E vs. RHE = E vs. Hg/HgO/4 mol dm−3 KOH + 0.926
| (1) |
Evaluation of air electrode performances
The long-term durability of the prepared catalyst was evaluated using the gas-diffusion electrode (GDE), which consisted of the hydrophobic gas-diffusion layer (GDL), catalyst layer (CL), and Ni mesh current collector (Niraco). The GDE experiments were conducted based on the previous reports.39,40 The hydrophobic gas-diffusion layer (GDL) was prepared from a mixture of 70 wt% carbon black (TOKAI CARBON, #3800) and 30 wt% polytetrafluoroethylene (PTFE). The resultant carbon/PTFE mixture was rolled in several steps to obtain 0.3 mm-thin sheets. After drying the prepared sheet at 60 °C, the GDL was cut out from the sheet into a 12 mm diameter circle, followed by heating at 334 °C for 1 h under N2 flow. Catalyst layers on the GDL were prepared by spraying the catalyst ink in circle with 8 mm diameter, which was a mixture of the prepared catalyst, carbon additive, 5 wt% Na+-exchanged Nafion solution, water and iso-propanol. The ratio of catalyst, carbon and Nafion was controlled to be 45:45:10 in wt% in the resultant catalyst layer. The catalyst was assembled with the GDL with the loading amount of 7 mg cm−2, followed by pressing onto the Ni mesh current collector. The prepared GDE and PTFE gasket O-ring were held in a Swagelok union (PFA-820-6) connected with stainless and perfluoroalkoxy alkane (PFA) pipes. The electrochemical cell for the GDE test consisted of a Pt wire, a Hg/HgO electrode, and a 4 mol dm−3 KOH aqueous solution as a counter electrode, a reference electrode, and an electrolyte solution, respectively. The charge–discharge tests were conducted at 40 °C in the incubator. The air electrode was exposed to ambient air without forced flow. Charge and discharge curves were obtained by monitoring the potential of the air electrode using a galvanostat (Biologic, VSP). The charge–discharge cycle test was conducted by applying 20 mA cm−2 for 1 h with an open circuit potential of 3 min interval for each cycle. The aqueous ZABs were constructed by employing a 500 μm thick zinc foil as the anode, the prepared GDE as the air cathode and 6 mol dm−3 KOH-based electrolyte containing 0.2 mol dm−3 zinc acetate. The ZAB experiments were conducted in an atmospheric environment at room temperature.
Results and discussion
Preparation of precursors
Initially, we examined to prepare composite precursors of multi-metal hydroxide and LDH from aqueous solutions containing more than two kinds of metal ions by the precipitation method and investigated the effect of the molar ratio of metal ions in the solution on the obtained precursors. Fig. 1 shows the XRD patterns of unary, binary and ternary metal precursors prepared by the precipitation method and CoNi-LDH as a reference sample synthesized by a topochemical oxidation method.41 The unary Co100 showed the pattern assignable to β-Co(OH)2, indicating that the precipitation method in the solution containing only Co ion yielded the Co hydroxide with no other products. The binary Co80Ni20 and Co94Fe6 precursors showed patterns assignable to LDH in addition to β-Co(OH)2. Previous studies have reported that LDH samples are synthesized by the precipitation method,33,42 in which alkaline reagents are added to aqueous solutions containing divalent and trivalent metal ions. The LDH can be obtained only when the ratio of trivalent metal ions is 20–33% of total metal ions,34 otherwise metal hydroxides are simultaneously formed as by-products. Thus, precursors in which hydroxide and LDH coexisted could be prepared by controlling the ratio of trivalent metal ions in the reaction solution to less than 20%. In the Co80Ni20 precursor, LDH was also formed in addition to hydroxide even though both ions are divalent. The result was probably due to partially oxidation of the divalent metal ions by dissolved oxygen in the solution,43 resulting in the formation of the LDH. The ternary precursors showed different XRD patterns depending on the metal ion ratio. Both the hydroxide and LDH formed in the Co74Ni13Fe13, Co80Ni6Fe14 and Co84Ni12Fe4 precursors. The precursors with Ni ratios of 20% or higher (Co65Ni20Fe15) did not show the pattern assignable to hydroxide, but only that to LDH. Patterns assignable to hydroxide and LDH were also observed for the Co72Ni6Fe22 precursor. However, the catalyst obtained by calcination of the Co72Ni6Fe22 precursor showed only the pattern assignable to the spinel oxide (Fig. S1†), indicating that the Co72Ni6Fe22 was not appropriate as the precursor. Because the samples calcined at 150 °C for the Co74Ni13Fe13, Co80Ni6Fe14 and Co84Ni12Fe4 showed the patterns assignable to oxyhydroxide and spinel oxide as discussed below, the hydroxide and LDH composite precursors can be obtained when the composition ratio of Ni and Fe is less than 15 at%. These results indicated that the precipitation method in the aqueous solution containing two or three metal ions with the appropriate molar ratio could yield precursors containing both hydroxide and LDH. From the SEM-EDX measurements, the composition metal ratio of the precursors showed a larger ratio of Fe to that in the reaction solution (Table S1†). This was probably due to the solubility of the metal ions, i.e., Fe3+ has a much lower solubility than that of Ni2+ and Co2+. The metal composition was also measured by analyzing solution of the samples dissolved using ICP-AES and similar results to those from SEM-EDX measurement were observed (Table S2†).
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| Fig. 1 XRD patterns of the precursors with different metal composition ratio, Co100 and CoNi-LDH reference (circle: LDH, square: hydroxide). | |
Effects of calcination temperature
It is known that metal hydroxides and LDHs change to metal oxyhydroxides and spinel oxides by calcination at low temperature,18,32,33 respectively, and oxyhydroxides convert to spinel oxides at high temperature.31 In this study, since the oxyhydroxide and spinel oxide must coexist after calcination, we investigated the effect of calcination on the precursors to synthesize the metal oxyhydroxide and spinel oxide composite catalysts. Fig. 2 shows the XRD patterns of the Co74Ni13Fe13, Co100 and samples obtained by calcining them at 100, 150 and 200 °C. The Co100 samples calcined at 100 and 200 °C showed the patterns assignable to β-CoOOH and Co3O4, respectively. The results indicated that the crystal structure of Co(OH)2 changed depending on the calcination temperature, which were consistent with the previous studies.31 The pattern of the Co74Ni13Fe13 (100) showed peaks assignable to oxyhydroxide, indicating that metal hydroxide of precursor changed to oxyhydroxide. Moreover, the peak around 11° disappeared and no peaks assignable to spinel oxide were observed for the Co74Ni13Fe13 (100), suggesting the collapse of the structure of LDH and formation of amorphous oxide at 100 °C. The Co74Ni13Fe13 (150) showed both patterns assignable to oxyhydroxide and spinel oxide. The results indicated that the crystalline structure of oxyhydroxide was maintained and spinel oxide formed from amorphous oxide at 150 °C. Previous studies have reported that calcination changes LDHs to spinel oxides via amorphous oxides,33 which corresponded to the results in this study. In the Co74Ni13Fe13 (200), the peaks assignable to oxyhydroxide disappeared and the pattern of spinel oxide was only observed, suggesting that the oxyhydroxide converted and the whole sample changed to spinel oxide at 200 °C. Therefore, calcination at 150 °C is the best condition for the synthesis of oxyhydroxide and spinel oxide composite catalysts. Because the Co80Ni6Fe14 (150) and Co84Ni12Fe4 (150) also showed the patterns assignable to both oxyhydroxide and spinel oxide (Fig. S2†), we concluded that the composite catalysts of oxyhydroxide and spinel oxide were successfully synthesized by calcination of the composite precursor of hydroxide and LDH at the adequate temperature.
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| Fig. 2 XRD patterns of the Co74Ni13Fe13 precursor, Co100, corresponding calcined samples and CoNi-LDH reference (circle: LDH, square: hydroxide, triangle: oxyhydroxide, diamond: spinel oxide). | |
Characterization of oxyhydroxide and spinel oxide composite catalyst
We investigated the morphology and composition of the composite catalyst. Fig. 3(a)–(c) shows SEM and TEM images of Co74Ni13Fe13 (150). TEM and SEM observations revealed that the Co74Ni13Fe13 (150) catalyst showed an aggregated morphology consisting of oxyhydroxide and spinel oxide primary nanoparticles with diameters of several nanometers. From the high-resolution TEM observation, lattice fringes of primary nanoparticles coincided with the (003) plane of the oxyhydroxide and the (311) plane of the spinel oxide (Fig. 3(c)). These results indicated that Co74Ni13Fe13 (150) was the catalyst with the mixture of oxyhydroxide and spinel oxide. The STEM-EDX mapping exhibited a uniform distribution of Co, Ni, Fe and O in the catalyst, indicating that metal elements homogeneously existed in the nanoparticles (Fig. 3(d)–(h)). Fig. 3(i) shows metal ratios of the oxyhydroxide and spinel oxide determined by STEM-EDX measurements from each primary particle identified by the lattice fringes. The oxyhydroxide and spinel oxide had almost identical average metal ratio; Co:75%, Ni: 14%, Fe: 11%, with small ranges of about ±4%, which were almost the same as the overall metal ratio obtained by SEM-EDX. The results indicated that the catalyst had uniform distribution of metals in both oxyhydroxide and spinel oxide nanoparticles with similar compositions. We also confirmed that metal ratio of catalysts coincided with that of the corresponding precursors.
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| Fig. 3 (a) SEM and (b), (c)TEM images of the Co74Ni13Fe13 (150) catalyst. (d) HAADF-STEM image and STEM-EDX maps for (e) Co–K, (f) Ni–K, (g) Fe–K, (h) O–K. (i) Metal composition ratio of oxyhydroxide and spinel oxide constituting the Co74Ni13Fe13 (150) catalyst. | |
Effects of crystalline structure on OER and ORR performances
We applied the Co74Ni13Fe13 (T) catalysts to ORR and OER to investigate the effects of crystal structure on catalytic performances. Fig. 4(a) shows polarization curves of the Co74Ni13Fe13 (T) catalysts and a commercial Pt/C, which is the representative ORR catalyst, for ORR in an O2-saturated 4 mol dm−3 KOH solution. The Co74Ni13Fe13 (200) showed superior electrocatalytic activities toward ORR with an onset potential of 0.93 V vs. RHE and a half-wave potential (E1/2) of 0.89 V vs. RHE, much more positive than those of Co74Ni13Fe13 (150) (onset potential, 0.92 V vs. RHE; E1/2, 0.87 V vs. RHE) and Co74Ni13Fe13 (100) (onset potential, 0.87 V vs. RHE; E1/2, 0.81 V vs. RHE). The difference in half-wave potential between the Co74Ni13Fe13 (200) and the commercial Pt/C (onset potential, 1.02 V vs. RHE; E1/2, 0.94 V vs. RHE) was only about 0.05 V. The Co74Ni13Fe13 (200) exhibited smaller Tafel slope (33 mV dec−1) than those of Co74Ni13Fe13 (150) (44 mV dec−1) and Co74Ni13Fe13 (100) (56 mV dec−1) (Fig. S3†). All Co74Ni13Fe13 (T) catalysts showed high electron transfer numbers (n > 3.5) (Fig. S4†). For ORR activity, the order of activity was Co74Ni13Fe13 (200) > Co74Ni13Fe13 (150) > Co74Ni13Fe13 (100). Fig. 4(b) shows polarization curves of the catalysts and a commercial RuO2 for OER in a 4 mol dm−3 KOH solution. The Co74Ni13Fe13 (100) exhibited the lowest overpotential (0.25 V) at 10 mA cm−2 among the catalysts, followed by Co74Ni13Fe13 (150) (0.28 V) and Co74Ni13Fe13 (200) (0.33 V). The Co74Ni13Fe13 (100) and Co74Ni13Fe13 (150) showed higher activity than that of even RuO2. Moreover, the Tafel slope of Co74Ni13Fe13 (100) (38 mV dec−1) and Co74Ni13Fe13 (150) (41 mV dec−1) were smaller than those of the Co74Ni13Fe13 (200) (62 mV dec−1) and RuO2 (61 mV dec−1) (Fig. S5†), also indicating higher activities of the Co74Ni13Fe13 (100) and Co74Ni13Fe13 (150). For OER activity, the order of activity was Co74Ni13Fe13 (100) > Co74Ni13Fe13 (150) > Co74Ni13Fe13 (200). Therefore, the higher the calcination temperature, the higher the activity for ORR, and the lower the activity for OER.
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| Fig. 4 Polarization curves of the calcined Co74Ni13Fe13 catalysts, Pt/C and RuO2 for (a) ORR and (b) OER in an O2-saturated 4 mol dm−3 KOH solution. | |
It has been reported that multi-metal oxyhydroxides containing Co and Fe or Ni and Fe show high OER activities, but low ORR activities,44 while spinel oxides show high ORR activities.45 Some spinel oxides have exhibited high OER activity; however, multi-metal oxyhydroxides have exhibited higher OER activities than spinel oxides in many reports.46,47 Since the Co74Ni13Fe13 (100) and (150) containing the oxyhydroxide showed lower overpotential and Tafel slopes than the Co74Ni13Fe13 (200) composed only of spinel oxide, OER activities of the oxyhydroxides were higher than those of spinel oxides in this catalyst system. The unary Co oxyhydroxide, Co100 (100), showed higher OER and lower ORR activity than the unary Co spinel oxide, Co100 (200) (Fig. S6†). Therefore, the results indicated that the composite catalysts calcined at lower temperature with larger part of oxyhydroxide showed higher OER and lower ORR activity, and the catalysts calcined at higher temperature with larger part of spinel oxide showed higher ORR and relatively lower OER activity. The catalytic performances of a physically mixed sample of spinel oxide and oxyhydroxide was evaluated to compare with the activities of composite catalyst (Fig. S7†). The Co74Ni13Fe13 (150) showed higher ORR and OER activities than those of the physically mixed sample. The results were probably attributed to the difference in dispersion of spinel oxide and oxyhydroxide in the catalysts. The Co74Ni13Fe13 (150) was the composite of well-dispersed primary nanoparticles of spinel oxide and oxyhydroxide (Fig. 3), while the simply mixed sample would be composed of their secondary particles. Therefore, the spinel oxide and oxyhydroxide composite catalysts formed from the composite precursors provided superior bifunctional ORR and OER performances.
The overall oxygen electrode activities are often evaluated by the value of ΔE, which is defined as a potential difference between an OER potential at 10 mA cm−2 (Ej=10) and E1/2 for ORR. A lower ΔE value indicates better bifunctional catalytic performances. The Co74Ni13Fe13 (150) showed the smaller ΔE of 0.64 V than those of the Co74Ni13Fe13 (100) (ΔE = 0.67 V) and Co74Ni13Fe13 (200) (ΔE = 0.67 V). Therefore, the Co74Ni13Fe13 (150) showed both high ORR and OER activities due to coexisting of the oxyhydroxide and spinel oxide.
Effects of metal composition on OER and ORR activities
Because the composite catalysts with oxyhydroxide and spinel oxide showed high bifunctional activities for OER and ORR, we investigated the influences of metal composition on catalytic activities. Fig. 5 shows polarization curves of the composite catalysts with different metal compositions for ORR and OER in a 4 mol dm−3 KOH aqueous solution. The composite catalysts showed different ORR and OER activities depending on the metal composition. Comparing Co74Ni13Fe13 (150) and Co80Ni6Fe14 (150), of which the Fe content was almost the same and the Ni content was different, the Co74Ni13Fe13 (150) showed higher ORR and OER activities (E1/2 = 0.87 V, Ej=10 = 1.51 V vs. RHE) than those of Co80Ni6Fe14 (150) (E1/2 = 0.84 V, Ej=10 = 1.53 V vs. RHE). The results suggested that inclusion of Ni enhanced activities for both ORR and OER. Comparing Co74Ni13Fe13 (150) and Co84Ni12Fe4 (150), of which the Ni content was almost the same and the Fe content was different, the Co74Ni13Fe13 (150) catalysts showed lower ORR activities and higher OER activities than those of Co80Ni6Fe14 (150) (E1/2 = 0.89 V, Ej=10 = 1.54 V vs. RHE). The activity trends suggested that inclusion of Fe increased OER activities but decreased ORR activities. Comparing the bifunctional activities based on ΔE, the Co74Ni13Fe13 (150) catalyst showed higher bifunctional performances (ΔE = 0.64 V) than those of Co80Ni6Fe14 (150) (ΔE = 0.69 V) and Co84Ni12Fe4 (150) (ΔE = 0.65 V). The Co74Ni13Fe13 (150) catalyst showed the highest bifunctional performances among the catalysts in this study, which was even comparable to the state-of-the-art bifunctional catalysts (Table S3†). Therefore, control of metal composition achieved the excellent bifunctional OER and ORR performances of the oxyhydroxide and spinel oxide composite catalyst.
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| Fig. 5 Polarization curves of the composite catalysts with different composition ratio for (a) ORR and (b) OER in an O2-saturated 4 mol dm−3 KOH solution. | |
Air-electrode performances
For practical application of bifunctional OER and ORR catalysts to ZABs, gas diffusion air-electrodes were fabricated to achieve high reaction rates using O2 in the atmosphere. We applied the Co74Ni13Fe13 (150) catalyst to the air-electrode and examined the bifunctional performances and durability of the catalyst. Fig. 6(a) shows the charge–discharge cycle performance of Co74Ni13Fe13 (150) in a 4 mol dm−3 KOH aqueous electrolyte at 40 °C. The durability of the Co74Ni13Fe13 (150) catalyst was evaluated by chronopotentiometry approaches at the constant anodic and cathodic current density of 20 mA cm−2. The fabricated air-electrode exhibited initial charge (OER) and discharge (ORR) potentials of 1.48 and 0.76 V vs. RHE, respectively, demonstrating a small total overpotential of 0.72 V. The total overpotential was maintained without any obvious deterioration even after more than 550 hours (260 cycles), showing excellent durability of the electrode for OER and ORR. Table S4† summarizes the comparison of the air-electrode performances with other recently reported results, indicating the superior activity and durability of the Co74Ni13Fe13 (150) catalyst.
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| Fig. 6 (a) Charge–discharge cycle performance of the Co74Ni13Fe13 (150) air-electrode at 20 mA cm−2 in 4 mol dm−3 KOH aqueous solution. Back scattering electron SEM images of the surface of the Co74Ni13Fe13 (150) air-electrode (b) before and (c) after cycle test. Cross-section secondary electron SEM images of the catalyst layer (d) before and (e) after cycle test and gas-diffusion layer (f) before and (g) after cycle test. | |
After 1000 hours, there was a performance deterioration, especially, the ORR performance significantly decreased (Fig. S8†). We conducted the XRD measurement and SEM observation for the electrode after the cycle test to clarify the cause of performance deterioration. The catalyst layer of air-electrode showed similar patterns assignable to the oxyhydroxide, spinel oxide and carbon conductive additive before and after the cycle test, indicating negligible change in crystalline structures of the catalyst (Fig. S9†). On the other hand, the intensity of the peak assignable to carbon at 26° was decreased. Fig. 6(b)–(g) shows surface and cross-section SEM images of the electrode before and after the cycle test. A large amount of carbon black disappeared, and more catalysts were exposed on the surface after the cycle test. The cross-section SEM observation after the cycle test revealed that more voids were formed in the catalyst layer of the electrode than before the test. Moreover, the morphology of carbon black in the gas diffusion layer was changed from a dense spherical to a hollow irregularly shape. The results clearly suggested that the carbon black was decomposed during the cycle test. Because carbon materials are thermodynamically decomposed under anodic conditions above 0.207 V vs. NHE,48 the carbon black in the catalyst and gas diffusion layers corroded during the reaction. On the other hand, the change in the Co74Ni13Fe13 (150) catalyst was negligible before and after the cycle test. The STEM observation clarified that oxyhydroxide and spinel oxide nanoparticles with corroded carbon conductive additives existed and no other compounds were observed after the cycle test (Fig. S10†). The ratio of metals in the oxyhydroxide and spinel oxide nanoparticles measured by STEM-EDX analysis was consistent with those before the reaction (Fig. S11†), and homogenous metal distribution in the nanoparticles was observed in the elemental mapping after the cycle test as well (Fig. S12†). We analyzed residual metals in the electrolyte after durability test by ICP-AES and only a trace amount of dissolved metals, up to approximately 0.21% of the total catalyst, was detected even after long-term test of 1000 h (Table S5†). The results indicated that the effect of metal dissolution on the performance deterioration was negligible and the Co74Ni13Fe13 (150) catalyst has high stability in the long-term test. Based on the results, the decrease in ORR performances was attributed to not the deterioration of the catalyst but corrosion of carbons in the catalyst and gas-diffusion layers. The corrosion of the carbon black in the catalyst and gas-diffusion layers caused the electrolyte solution to gradually penetrate through the air electrode to the gas phase during the cycle test, resulting in insufficient O2 diffusion and a considerable decrease of ORR performances due to immersion of active sites at the three-phase boundary.38 For OER process, OH− is the substrate and the O2 produced in the reaction was released not only to the gas side but also to the solution. Thus, the OER performances were not decreased as significantly as the ORR performances. The Co74Ni13Fe13 (150) catalyst did not show significant change in the structure and composition after the cycle test, indicating excellent stability for OER and ORR. Therefore, the composite catalysts of oxyhydroxide and spinel oxide exhibited superb bifunctional activities and durability for OER and ORR, and fabrication with anti-corrosive conductive materials instead of carbons will achieve a longer lifetime for air-electrode performances.
Furthermore, we assembled an aqueous ZAB with Zn foil as the anode and Co74Ni13Fe13 (150) as the air cathode in a solution containing 6 mol dm−3 KOH and 0.2 mol dm−3 zinc acetate. Fig. 7(a) shows the charge–discharge polarization curves of the Co74Ni13Fe13 (150) and a physical mixture sample of Pt/C and RuO2 (Pt–RuO2). The ZAB with Co74Ni13Fe13 (150) exhibited superior charge and discharge curves compared to those of the ZAB with Pt–RuO2. The peak power density of Co74Ni13Fe13 (150) and Pt–RuO2 were 195 and 31.7 mW cm−2, respectively, indicating that the Co74Ni13Fe13 (150) electrode showed higher performances compared to the Pt–RuO2 sample (Fig. 7(b)). The long-term durability of the rechargeable ZABs was evaluated through galvanostatic charge–discharge cycling (Fig. 7(c)). The total charge–discharge overpotential of Co74Ni13Fe13 (150) upon cycling was only 0.65 V, which was much smaller than that of Pt–RuO2 (0.89 V). The charge–discharge profile of Co74Ni13Fe13 (150) was retained after 430 h (1270 cycles) while the performance of Pt–RuO2 was rapidly deteriorated within 8 h. The performance of the ZAB with Co74Ni13Fe13 (150) was comparable to that with state-of-the-art catalysts (Table S6†), demonstrating that the Co74Ni13Fe13 (150) was highly suitable for rechargeable ZABs as a bifunctional electrocatalyst. The excellent bifunctional ORR and OER performances of the composite catalyst of oxyhydroxide and spinel oxide may be due to synergistic effects of the combination of materials. Elucidation of the synergistic effects would be a next challenge.
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| Fig. 7 (a) Charge and discharge polarization curves, (b) corresponding powder densities and (c) charge and discharge voltage profiles of ZABs with the Co74Ni13Fe13 (150) (red) and Pt–RuO2 (gray) air-electrodes. | |
Conclusion
In summary, we synthesized bifunctional OER and ORR composite electrocatalysts of metal oxyhydroxide and spinel oxide containing Co, Ni and Fe by calcination of hydroxide and LDH composite precursors prepared by a precipitation method. The composite precursors of metal hydroxide and LDH were prepared when both the Ni and Fe metal composition ratio was below 15 at%, and then calcination of the precursors at 150 °C yielded the composite catalysts of multi-metal oxyhydroxide and spinel oxide. The activities of composite catalysts depended on the metal composition; the inclusion of Ni enhanced activities for both ORR and OER and the inclusion of Fe increased OER activities but decreased ORR activities. The Co74Ni13Fe13 (150) showed superb bifunctional performances with a small potential difference of 0.64 V due to high OER and ORR activities originating from the oxyhydroxide and spinel oxide, respectively. The Co74Ni13Fe13 (150) also exhibited excellent durability of more than 550 h (260 cycles) for the air-electrode charge–discharge cycle evaluation with negligible change in crystalline structure and composition. The ZAB with Co74Ni13Fe13 (150) demonstrated the power density of 195 mA cm−2 and excellent durability of 430 hours (1270 cycles) for the charge–discharge cycle test. The synthetic procedure of composite catalyst will contribute to opening up new opportunities for the development of air-electrodes for ZABs.
Author contributions
S. Kitano; conceptualization, supervision, visualization, resources, writing – review & editing, funding acquisition, methodology: Y. Sato; investigation, data curation, methodology: R. Tagusari; investigation: R. Zhu; investigation: D. Kowalski; investigation, methodology: Y. Aoki; investigation, methodology: H. Habazaki; conceptualization, supervision, visualization, resources, writing – review & editing, funding acquisition, methodology. All authors have given approval to the final version of the manuscript.
Conflicts of interest
The authors declare no competing financial interest.
Acknowledgements
Part of this study was conducted at the Multi-Quantum Beam High Voltage Electron Microscope Laboratory at Hokkaido University, supported by the Nanotechnology Platform Program of the Ministry of Education, Culture, Sports, Science and Technology (MEXT), Japan (A-19-HK-0003, A-20-HK-0002, A-21-HK-0035). We acknowledge funding by JSPS KAKENHI (22K05295) and the New Energy and Industrial Technology Development Organization (NEDO) grant number JPNP16001 (Research and Development Initiative for Scientific Innovation of New Generation Batteries (RISING2)), Japan. A part of this work was conducted at Laboratory of XPS analysis, Joint-use facilities, Hokkaido university.
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