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Tuning electronic structures of non-precious ternary alloys encapsulated in graphene layers for optimizing overall water splitting activity Yang Yang, Zhiyu Lin, Shiqi Gao, Jianwei Su, Zheng-yan Lun, Guoliang Xia, Jitang Chen, Ruirui Zhang, and Qianwang Chen ACS Catal., Just Accepted Manuscript • DOI: 10.1021/acscatal.6b02573 • Publication Date (Web): 02 Dec 2016 Downloaded from http://pubs.acs.org on December 2, 2016
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Tuning electronic structures of non-precious ternary alloys encapsulated in graphene layers for optimizing overall water splitting activity Yang Yang,a Zhiyu Lin,a Shiqi Gao,a Jianwei Su,a Zhengyan Lun,a Guoliang Xia,a Jitang Chen,a Ruirui Zhang,a and Qianwang Chen*a,b a
Hefei National Laboratory for Physical Science at Microscale, Department of Materials Science & Engineering & Collaborative Innovation Center of Suzhou Nano Science and Technology, University of Science and Technology of China, Hefei 230026, China. E-mail:
[email protected] b
High Magnetic Field Laboratory, Hefei Institutes of Physical Science, Chinese Academy of Sciences, Hefei 230031, China
Keywords: water splitting, ternary alloy, graphene, tuning electronic structure
ABSTRACT: Electrochemical water splitting is considered as the most promising technology for hydrogen production. Considering overall water splitting for practical applications, the catalysts for oxygen evolution reaction (OER) and hydrogen evolution reaction (HER) should be performed in the same electrolyte, especially in alkaline solutions. However, designing and searching high active and inexpensive electrocatalysts for both OER and HER in basic media still remains a significant challenge. Herein, we report a facile and universal strategy to synthesize non-precious transition metals, binary alloys as well as ternary alloys encapsulated in graphene layers by direct annealing of metal-organic frameworks. Density functional theory
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(DFT) calculations prove that by increasing freedom degrees of alloys or altering metal proportions in FeCoNi ternary alloys, the electronic structures of materials can also be tuned intentionally through changing number of transferred electron between alloys and graphene. The optimal materials alloys FeCo and FeCoNi exhibited remarkable catalytic performance for HER and OER in 1.0 M KOH, reaching a current density of 10 mA cm−2 at low overpotentials of 149 mV for HER and 288 mV for OER, respectively. What’s more, as an overall alkaline water electrolysis, they were comparable to that of Pt/RuO2 couple, along with long cycling stability.
Electrochemical water splitting is considered as the most promising technology for hydrogen production.1-4 The overall water splitting consists of oxygen evolution reaction (OER) on the anode and hydrogen evolution reaction (HER) on the cathode, both of which need high active catalysts to reduce the energy expense needed for water splitting via reducing their overpotential.5 Precious metals and metal oxides such as Pt/C and Ir/C (or RuO2) are the state-ofthe-art catalysts for HER and OER, however, their widespread practical applications are hindered by high cost and metal scarcity. Plenty of efforts have been made during the past decades in search of non-precious catalysts for HER or OER, but this area still lacks promising efficient catalysts that can realize commercialization in large-scale.4,5 What’s more, to realize continual overall water splitting for real applications, the catalysts for OER and HER should be operated under the same electrolyte, especially in an alkaline solution.2 Nevertheless, it still remains challenges for most of the earth-abundant catalysts due to their incoordination with the PH ranges in which they exhibit an excellent stability and activity.1,3,6 In spite of some progress in
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recent years, high active and cost-effective catalysts that are efficient to both HER and OER in alkaline electrolytes with excellent activity and stability are still in great demand.2,3 Among many non-precious materials, transition metals such as Fe, Co and Ni and their alloys are regarded as potential substitutes for precious catalysts.7-10 The combination of transition metals with graphene layers is beneficial for improving of catalytic activity as well as stability.11,12 Even though some studies have successfully synthesized various transition metal or alloys as efficient HER or OER catalysts, most of them are pure metals or binary alloys which can only catalyze one kind of electrochemical reaction in a certain solution, hindering their practical applications in full water electrolysis.9,11,13-15 Besides, the synergistic effects between Fe, Ni and Co in the alloy are rarely reported in those literatures. Previous studies have proved that incorporating transition metals into alloys will alter the lattice and bond length of crystal so as to change adsorption energies toward optimal catalytic activity.12,16 Furthermore, it might provide more chance to alter the catalytic activity through changing the relative metal proportion in alloys due to the increased freedom degrees of alloys than pure metals.17 Inspired by this, it can be anticipated that building more complex alloy compositions (from binary to ternary) would provide more possibilities to further enhance electrocatalytic performance via tuning metal compositions and proportions. However, hindered by the complex and tedious synthesizing process, few of studies are focused on the graphene encapsulated non-precious ternary alloys, especially elaborated tuning of electronic structure and systematic study of relationship between metal composition and overall water splitting activity. To synthesize various catalysts with similar morphologies from single precursor or method is of great significance,especially,towards building the relationship between composition and activity among different catalysts.18 Metal-organic frameworks (MOFs) with high surface area and
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tunable chemical structures have attracted tremendous attention recently.15,19-22 The tunable metal ion centers (such as Fe, Co, Ni, Cu) and designing organic ligands with different dopants (N, P, S atoms) endows itself a perfect precursor to synthesize encapsulated alloys with different metal compositions. Recently, our group have successfully synthesized FeCo alloys encapsulated in nitrogen doped graphene layers by direct annealing of Fe3[Co(CN)6]2 precursor, which shows excellent HER catalytic activity and stability.12 MOF precursors can also be modified in many ways to obtain more complex compositions and structures.23 Lou and his coworkers prepared Fe3C@N-CNT from a dual-metal–organic-framework, which exhibits excellent electrochemical activity.24 MOFs derived core-shell structures are also very popular recently, however, confined by single metal or bimetal organic framework precursor, most of the derived materials are pure metal or at most binary alloys. Furthermore, few of works are aiming to enhance electrochemical activity through increasing freedom degrees of alloys. In this communication, the available inherent MOF Fe3[Co(CN)6]2 surface was used as an active support to load another MOF precursor Ni3[Co(CN)6]2. During the calcination process, the different metal ions will migrate to each other to form ternary alloys with the increasing annealing temperature, meanwhile some CN− group in MOF precursor will be catalyzed to in situ form nitrogen doped graphene layers outside the alloy particles. Furthermore, the proportion of different metal ions can also be controlled by relative proportion of the core and shell precursor. The materials of various alloys and metal proportions exhibit different HER and OER performance. We have obtained the relationship between activity and composition as well as proportion of alloys through density function theory (DFT) calculations. It turns out the electronic structures of materials can also be tuned intentionally through changing number of transferred electron between alloys and graphene. The optimal alloy catalysts for overall water
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splitting are also obtained via tuning electronic structures, which is even better than the Pt/RuO2 counterpart. In order to synthesize different non-precious metals and alloys through same process, herein, we introduce a facile and universal method for the preparation of nitrogen doped graphene encapsulating uniform 3d transition metals, including pure metal, binary alloys as well as ternary alloys with various metal proportions by direct annealing of different MOFs. The samples obtained with different metal compositions were designated as Co, FeCo, FeNi, CoNi, FeCoNi, corresponding to different alloys encapsulated in nitrogen doped graphene layers. Meanwhile, FeCoNi-1, FeCoNi-2 and FeCoNi-3 referred to ternary alloys with different metal proportions. The detailed synthetic information and metal proportions can be seen in supporting information. The ternary alloys with different metal proportions were fabricated as illustrated in Scheme 1: First of all, Fe3[Co(CN)6]2 spheres were synthesized and used as core seeds to prepare encapsulated MOF structure (Scheme 1a). Due to the similar crystal structure and lattice constant of Prussian blue analogues, it is possible to deposit relative small Ni3[Co(CN)6]2 particles onto the large and clean spherical seeds to form a thin layer (Scheme 1b). In this process, poly vinyl pyrrolidone (PVP) surfactant will control the morphology of particles meanwhile slow down the coordination speed between the metal ions and ligands, providing the opportunity of nucleation at the seed. During the thermal treatment, because of the non-equilibrium interdiffusion process of metal atoms and porous structure of MOFs, the Fe, Co and Ni metal ions would migrate to each other to form FeCoNi alloys during calcinations as illustrated in Scheme 1c and d. At the same time, some CN− group linkers will serve as both carbon and nitrogen sources for the in situ formation of nitrogen doped graphene layers outside the alloy particles. Scheme 1e is an enlargement of one FeCoNi particle encapsulated by nitrogen doped graphene layers. Moreover,
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through altering the amount of seeds and Ni3[Co(CN)6]2 shell, the proportion of metals in ternary alloys can also be changed (Scheme 1f), thereby tuning electronic structure of material and optimizing its overall water splitting activity.
Scheme 1 The synthetic illustration of graphene layers encapsulated FeCoNi ternary alloys. (a) Fe3[Co(CN)6]2 sphere (b) Fe3[Co(CN)6]2 sphere encapsulated by Ni3[Co(CN)6]2 small particles (c) metal interdiffusion during annealing process, dashed lines are possible diffusion path of metal ions (d) finally FeCoNi tenary alloy aggregates derived from MOF precursor (e) enlarged model of an FeCoNi alloy particle encapsulated in nitrogen doped graphene layers (f) tuning electronic structures of graphene encapsulated alloys to optimize overall water splitting activity, the yellow, pink and green balls refer to Fe, Co and Ni atoms, respectively.
The sample of Fe3[Co(CN)6]2 seed showed a sphere-like morphology with a diameter of approximately 600–1000 nm with a clean surface (Figure 1a) according to the field emission scanning electron microscopy (FESEM) results. With the increasing addition amount of Ni3[Co(CN)6]2, the surfaces became more rough and the spherical seeds were encapsulated by more Ni3[Co(CN)6]2 precursors shell as shown in Figure 1b-d. The annealing temperature of precursors was set to 600℃, which was proved to be the optimal annealing temperature for prussian blue analogue.12 After annealing, all the samples (Figure 1e-h) retained the morphology
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of their precursors. However, the samples with more Ni content possessed more tubular margins at the edge of the sphere (Figure 1g and h). MOFs with high Ni content are likely to form carbon nanotubes during calcinations process.25 Figure 1 i-l are the transmission electron microscopy (TEM) images of FeCo, FeCoNi-1, FeCoNi-2 and FeCoNi-3, which reveals the spherical samples are composed of small encapsulated alloy particles. SEM and TEM images of Co, CoNi and FeNi are illustrated in Figure S1.
Figure 1 (a-d) The field emission scanning electron microscopy (SEM) of pure Fe3[Co(CN)6]2 and Fe3[Co(CN)6]2 sphere encapsulated by increasing amount of Ni3[Co(CN)6]2 (e-h) SEM images of FeCo, FeCoNi-1, FeCoNi-2 and FeCoNi-3 by annealing of their corresponding precursors (i-l) transmission electron microscopy (TEM) images of FeCo, FeCoNi-1, FeCoNi-2 and FeCoNi-3
High resolution transmission electron microscopy (HRTEM) characterizations for ternary FeCoNi alloys (Figure 2, Figure S2, S3) indicate the alloys were completely encapsulated by graphene layers. As shown in Figure 2a and 2b, the thickness of graphene layers is around
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1.71nm, corresponding to about 5 layers of graphene. Bao’s group and our previous study proved electron of metal core could penetrate several layers of graphene shell to promote catalytic process meanwhile the graphene layers is also beneficial to catalytic stability.12,16 Therefore, such an alloy core with graphene shell structure is desirable for electrocatalysts. In addition, FeCoNi-1 exhibits a d-spacing of 2.03 Å, in good agreement with the (110) plane of the FeCo alloy, indicating Ni atoms might be doped in the FeCo crystal lattice in FeCoNi-1. Figure 2c–f are the images of elemental mapping by energy filtered TEM (EFTEM), which reveals the Fe , Co and Ni elements are uniformly distributed in the particles, further confirming the alloy structure of FeCoNi-1. The same results also appear in Figure S2 and Figure S3, proving the successful fabrication of FeCoNi ternary alloys using MOFs precursor.
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Figure 2 (a–b) enlarged high resolution transmission electron microscopy (HRTEM) images of FeCoNi-1 where interplanar spacing of the alloy as well as the graphene layers were measured in the image, (c–f) STEM image of the single FeCoNi nanocrystal and the images of elemental mapping of Fe ,Co and Ni. The crystal structures of metals, binary alloys and ternary alloys were further confirmed by XRD results as illustrated in Figure 3. The graphite peaks in the XRD patterns are submerged due to the high intensity of alloy peaks. In fact, the enlarged patterns of ternary alloys in Figure 3 and XRD pattern of FeCoNi-2 after acid treatment are illustrated in Figure S4, which shows typical peak of C (002), indicating alloys are wrapped with graphene layers. The sample FeNi shows the characteristic peaks at 51.8 and 76.4, corresponding to (200) and (220) planes of the FeNi alloy, respectively. The characteristic peaks for sample FeCo are at 44.8 and 65.3, which are assigned to the (110) and (200) planes of FeCo alloy, respectively. The peaks of CoNi are similar to that of Co, indicating the Ni atoms might replace some of Co atoms in the crystal of CoNi. The atomic radius of Co (1.67 Å) are large than Ni (1.62 Å), after incorporation of Ni atoms, the peaks of CoNi move slightly to higher degree compared with Co. The XRD patterns of ternary alloys display characteristic reflections of the face centered cubic (black color) phase and the body centered cubic (blue color) phase of the FexCoyNi100−x−y alloy (especially for FeCoNi-2 and FeCoNi-3), which is consistent with previous literatures.26,27 Besides, the peak intensity ratio of body centered cubic (1 1 0) to face centered cubic (1 1 1) decreased from sample FeCoNi-1 to FeCoNi-3. The phenomenon indicates that the Fe content is decreased while Ni content is increased from FeCoNi-1 to FeCoNi-3. This tendency is also consistent with the corresponding metal amount of their MOF precursors.
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Figure 3 XRD patterns of various metal, binary alloys and ternary alloys derived from MOFs precursors. Black and blue colors refer to face centered cubic phase and body centered cubic phase, respectively.
The Raman spectra of ternary alloys and binary alloys are provided as illustrated in Figure S5. All the samples displayed three Raman peaks locating at around 1349 cm-1, 1583 cm-1 and 2700 cm-1, which corresponds to the D, G and 2D bands of carbon, respectively. The high ID/IG band intensity ratio of samples indicated the generation of large amounts of defects, suggesting a large amount of N atoms were doped in the graphene layers (The ID/IG ratio of CoNi is relative lower than others, this is because there are many carbon nanotubes in the sample of CoNi as illustrated in Figure S1e and h). The nitrogen doping has proved to be beneficial for improving the performance of OER and HER.12 Moreover, the second-order band in all samples is broad and weak, indicating the alloys are encapsulated by thin layers of graphene.19
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The chemical states of ternary alloys measured by X-ray photoelectron spectroscopy (XPS) were illustrated in Figure 4. Deconvolution of the complex Fe 2p, Co 2p and Ni 2p spectrum (Figure 4b, c and d) suggests the presence of two chemically distinct species: metallic state of Fe (707.3 eV, 719.8 eV), Co (778.5 eV, 793.8 eV), Ni (852.8 eV, 870.1 eV) and oxidation state of Fe (712.4 eV, 724.2 eV), Co (780.7 eV, 796.3 eV), Ni (854.7 eV, 872.1 eV). The result of metallic Fe, Co, Ni was consistent with our XRD analysis and HRTEM results while the oxidation state indicates the surface of alloys are partially oxidized or interacted with adsorbed O2. Some MOFs derived metals or alloys encapsulated by graphene also exhibited similar results.28-30 Besides, Li and his co-workers have proved that the majority of metal species maintained the metallic state in Prussian blue analogues derived core-shell structure through X-ray adsorption near edge structure (XANES) and extended X-ray absorption fine structure (EXAFS) analysis.28 Interestingly, the metal contents measured by XPS were very low (Table S1). This result is also reasonable, since XPS is sensitive to surface, and thereby is ineffective to detect signals of alloy core inside the graphene layers, further proving that alloys were completely encapsulated by graphene layers. The nitrogen contents of three samples were about 10 atom% and the N1s spectrum of them can be deconvoluted into four individual peaks (Figure S6) which can be assigned to pyridinic N (398.7 eV), pyrrolic N (399.3, 400.8 eV), and quaternary N (401.3 eV), respectively. However, it should be noted that some of nitrogen might bond with metal atoms in our materials. Especially, pyrrolic N has two binding energies here (399.3, 400.8 eV), which might be ascribed to the energy shift induced by the interaction of some pyrrolic N with metal atoms.31,32
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Figure 4 XPS spectra of FeCoNi-1, FeCoNi-2 and FeCoNi-3 (a) wide spectrum and high resolution spectra of (b) Co 2p; (c) Fe 2p; (d) Ni 2p.
In order to know the exact metal proportions in the ternary alloys, we also carried out Inductively Coupled Plasma (ICP) measurement (Table S2). According to the results, we could find that Co content keeps almost unchanged in three alloys. Besides, the Fe contents will decrease along with the increase of Ni content from sample of FeCoNi-1 to FeCoNi-3. This result is also consistent with the metal contents of their corresponding precursor as well as the XRD analysis, proving the successful control of metal proportions via altering amounts of precursors. It should be noted that the exact values of Fe, Co and Ni in the samples measured by EDX (Table S3 and Figure S7) were different from ICP results. This is reasonable, since ICP results are obtained through dissolution of whole materials, however, EDX results came from some particles near the
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edge of the sphere. As illustrated in Scheme 1c, even though there existing metal atoms interdiffusion during annealing process, the particles near the edge will still have higher Ni content and lower Fe content than the inner part due to the intrinsic different composition between core and the shell. However, the changing tendency of Fe and Ni contents is same from both ICP and EDX measurements, proving the successful controlling of metal proportions through tuning amounts of precursors. The specific surface of ternary alloys obtained using the Brunauer–Emmett–Teller (BET) method were listed in Table S4 and our previous study proved there was no direct relationship between electrochemical performance and difference of specific surface within that range.12
The performance of catalysts towards oxygen evolution reaction (OER) was explored in 1 M KOH solution by a typical three-electrode electrochemical cell. Ag/AgCl (3M KCl) and Platinum foil electrodes were used as reference electrode and counter electrode, respectively. As illustrated in Figure 5a, we conducted linear sweep voltammograms (LSV) to assess the activities of oxygen evolution reaction for metal, binary alloys and ternary alloys. We also measured the performance of Ir/C (20 wt% Ir on Vulcan carbon black purchased from Premetek Company) and RuO2 (Alfa aesar) as reference. In general, all catalysts except Co had much higher OER activity than RuO2. Ir/C is superior than most of our alloy samples, however, the overpotential to reach 10mA/cm2 of FeCoNi-2 is still lower than Ir/C, indicating excellent OER performance of FeCoNi-2. The overpotential of ternary alloys to reach current density of 10 mA cm-2 is lower than that of binary alloy and pure metal, indicating that incorporating transition metal and binary alloys into ternary alloys will improve their OER activity. Besides, FeCoNi-2 exhibits the best catalytic performance (overpotential of 325mV at 10 mA cm-2) among all ternary alloys, proving
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further altering metal proportions of ternary alloys could also enhance their property. The Tafel plot of FeCoNi-2 was recorded and compared with RuO2 (Figure 5b). The Tafel slope of FeCoNi-2 is 60 mV dec-1 which is much lower than that of RuO2 (92 mV dec-1), showing FeCoNi-2 a better catalyst to drive the OER process compared to RuO2 at a lower overpotential. The durability of FeCoNi-2 was also assessed by measuring polarization curves after particular cyclic voltammetric (CV) sweeps as illustrated in Figure 5c. The polarization curve of FeCoNi-2 after 10000 cycles retained an almost similar performance to the initial test, exhibiting excellent cycling stability. Moreover, from the potential values recorded at different current densities of 10 mA cm-2 and 40 mA cm-2 before and after the test (Figure 5d), FeCoNi-2 exhibits high stability, obviously superior to the durability of its counterpart RuO2. In order to further prove the material is wholly alloyed, we also obtained mixture by mechanical mixing of FeCo and CoNi with the same precursor ratio as FeCoNi-2. As shown in Figure S8, the mixture of FeCo and CoNi also exhibits obvious inferior OER activity than FeCoNi-2, indicating the core of our sample is also successfully alloyed. As illustrated in enlarged Figure 5a (Figure S9), a slight peak emerging around 1.4 V vs. RHE which might be ascribed to partially oxidation of alloys during cycling according to previous researches.33 However, the peak intensity is relative lower compared with other transition metal based OER catalysts without graphene layer protection. Besides the oxidation peak remained almost same after 1000th cycling, indicating the further oxidation process was prevented by graphene layer. We also used SCE (saturated calomel electrode) as reference electrode to verify the activity and stability of FeCoNi-2 as OER catalyst and the results were compared with Ag/AgCl electrode. The difference between two electrodes of measured overpotentials to reach current density of 10 mA cm-2 is only 5 mV as illustrated in Figure S10a. Besides, long cycling test used SCE electrode also shows similar result with
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Ag/AgCl electrode: the FeCoNi-2 exhibits negligible activity degradation even after 10000th cycling, indicating excellent stability of our catalyst (Figure S10b). The excellent activity as well as stability of FeCoNi-2 endows itself a promising alternative for high active non-precious metal electrocatalysts for oxygen evolution reaction.
Figure 5 Electrocatalytic OER performance tests of different metal, binary alloys and ternary alloys in 1 M KOH solution. (a) OER polarization curves for different metal, binary alloys and ternary alloys compared with Ir/C and RuO2 with same mass loading. (b) Tafel plots for FeCoNi2 and RuO2. (c) Durability test of FeCoNi-2 in alkaline electrolyte for 10000th cycles. (d) The overpotential changes of current densities at 40 mA cm-2 and 10 mA cm-2 for FeCoNi-2 and in comparison with RuO2 at 10 mA cm-2 during the durability test.
Utilizing a standard three-electrode electrochemical system, we assess the catalytic activity of samples for the HER in 1 M KOH. The electrocatalytic activity of 20wt% Pt/C (Sigma Aldrich) was also measured to make a comparison. The polarization curves of the samples were illustrated
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in Fig. 6a. The Pt/C is still one of the best HER catalysts in basic electrolyte, meanwhile, pure Co exhibited a relative poor HER activity. We chose potentials at 10 mA cm-2 current density as criteria to compare various catalysts’ activities. And the potentials are in the order of Pt < FeCo < FeCoNi-1 < FeCoNi-2< FeCoNi-3
