1. INTRODUCTION
The growing demand for renewable and clean energy is becoming increasingly critical due to the rapid depletion of fossil fuels and the environmental pollution they cause. As petroleum reserves dwindle, the world faces a potential energy crisis of unprecedented scale. Therefore, developing sustainable energy alternatives is imperative to meet future energy needs. In this context, clean hydrogen production through overall water splitting stands out as one of the best alternatives to address future energy requirements [1]. Nevertheless, the zero-carbon goal via the exploration of clean energy is a desperate concern. To the context, production of hydrogen via the electrolysis may be the best sustainable solution. More precisely, the water splitting occurs via a simultaneous process of hydrogen evolution reaction (HER) at cathode and oxygen evolution reaction (OER) at anode [2]. However, the sluggish kinetics of complex four electron transfer mechanism in the electrochemical OER process is one of the bottlenecks. Moreover, the commercial electrode materials for the HER i.e., (Pt-based) and OER (Ru-based) are expensive with the limited reservoir, hiders the widespread application for the overall water splitting. So, the electrocatalyst in the adequate amount and cheap has the great potential for the generation of clean hydrogen. In this context, numerous transition metal-based electrocatalysts have been fabricated, including layered double hydroxides (LDH) and transition metal chalcogenides (TMS) such as phosphides, sulfides, and tellurides. These materials are favored due to their facile synthesis methods and cost-effectiveness [3,4]. More specifically, nickel and vanadium-based chalcogenides have significant potential for the hydrogen evolution reaction (HER), oxygen evolution reaction (OER), and overall water splitting (OWS). This is due to the optimal properties of first-row transition metals, such as variable oxidation states, a tendency for complex formation, and excellent electrical conductivity [5,6]. Among transition metal chalcogenides (TMS), nickel and vanadium-based phosphides exhibit a strong quantum size effect, outstanding electrical conductivity due to their shallow valence band, low toxicity, and ease of synthesis [7]. In this regard, both monometallic and polymetallic metal phosphides have been fabricated. However, single metallic tellurides exhibit relatively low electrochemical performance. Introducing more than one transition metal in functionally modified transition metal phosphides (TMPs) can significantly enhance their HER and OER potential [2,8]. In particular, synergistic activities across the multimetallic moieties are a key factor in enhancing electrochemical performance.
Herein, we have facilely synthesized a bimetallic cobalt vanadium phosphide (Co2P/VP) heterointerface-modulated structure through the rational manipulation of its electronic structure. The as-synthesized electrocatalyst demonstrates outstanding HER and OER performance in a 1.0 M alkaline electrolyte at 25°C, with overpotentials of 96 mV and 237 mV at current densities of 10 mA cm-2, respectively. The remarkable electrochemical activity of the synthesized Co2P/VP is attributed to the synergism between the metallic configurations and the tailored electronic structure.
2. EXPERIMENTAL
2.1 Chemicals and instruments
2.1 Chemicals and instruments Cobalt (II) nitrate hexahydrate (Co(NO3)2·6H2O; ≥99.0%), sodium orthovanadate dihydrate (Na3VO4·2H2O; ≥99.0%), ammonium fluoride (NH4F; ≥99.0%), urea (NH2CONH2; ≥99.0%), sodium phopsphite monohydrate (NaH2PO2·H2O ≥99.0%) ruthenium (IV) oxide (99.9% trace metal basis), Pt/C (10 wt.% loading) were purchased from Sigma-Aldrich and used without further purification. Numbers of modern and advanced instruments were used for the synthesis of materials and their characterizations. For the morphological inspection, field emission scanning electron microscopy (Marker: Supra 40 VP instrument Zeiss Co., Germany) was used. For the crystallographic characterization, X-ray diffraction meter (Marker: D/Max 2500 V/PC; Rigaku Co., Japan) was used at the Center for University-Wide Research Facilities (CURF), Jeonbuk National University (Republic of Korea). Cu target Kα X-ray (λ = 0.154 nm) was used as the source of X-ray. X-ray photo-electron spectrometry (marker: VG ESCALAB 220i, Thermo Fischer, UK) was used in the Jeonju center of KBSI (Republic of Korea). CHI660 electrochemical workstation (CH Instruments, Inc., USA) was used for the electrochemical measurements of as-prepared materials.
2.2 Preparation of cobalt vanadium layered double hydroxide (CoV-LDH)
The 2D CoV-LDH nanosheets were synthesized on nickel foam via a one-step hydrothermal method. In detail, 0.57 g cobalt nitrate hexahydrate, 0.22 g sodium orthovanadate dihydrate, 0.30 g urea, and 0.09 g ammonium fluoride were dissolved into 60 mL deionized water following continuous stirring for 15 min at room temperature to make a clear homogenous solution. Then a clean NF of size (2 × 5 cm2) was placed inside a 100 mL teflon-lined stainless-steel autoclave. After that, all 60 mL solution was poured followed by self-cooling to room temperature to complete the reaction and the formation of CoV-LDH. After the completion of reaction, the nickel foam was taken out and washed with deionized (DI) water followed by ethanol several times and dried at 60℃ under vacuum for 12 h.
2.3 Preparation of cobalt vanadium phosphide (Co2P/VP) heterostructure
The CoV-LDH loaded nickel foam was directly transformed to vanadium phosphide (Co2P/VP) heterostructure via simultaneous phosphorization process by a one-step controlled chemical vapor deposition (CVD) method. In detail, the CoV-LDH loaded NF was then placed in the upstream and 0.25 g NaH2PO2·H2O in the downstream side of the CVD boat, which was kept inside the glass tube of the CVD furnace. Next, the reaction was started with continuous flow of argon (Ar) gas with the ramping rate of 100 sscm at 400°C for 1 h. After the completion of the phosphorization, the Co2P/VP was washed with ethanol and kept in vacuum for 6 h to dry at 60°C. The mass loading of the Co2P/VP in nickel foam was determined as 4.1 mg cm-2.
2.4 Electrochemical characterization
The electrochemical performance of the prepared samples was analyzed using a CHI660D workstation. Linear sweep voltammetry (LSV) was evaluated on these samples using a three-electrode setup containing Ag/AgCl electrode as reference electrode, graphite rod as counter electrode, and nickel foam loaded with Co2P/VP (1 × 1 cm²) served as the binder free working electrode. 1.0 M KOH was used as electrolyte. The linear sweep voltammetry (LSV) was measured at the scan rate of 2 mV s-1, employing 100% iR compensation.
3. RESULTS AND DISCUSSION
The synthesis of CoV-LDH nanosheet arrays is achieved via hydrothermal approach. Herein, the ultrathin nanosheet was initially grown via facile hydrothermal approach at the optimum temperature at 12 h (details in the experimental section). Then the CoV-LDH was used as the sacrificial template for the post functionalization (phosphidation) by the controlled CVD method to synthesize Co2P/VP heterostructure as shown in Scheme 1.
Scheme 1. Schematic representation of the synthesis details of Co2P/VP electrocatalyst
Additionally, the phosphine gas produced from the sodium phosphide monohydrate at the operating temperature causes the solid-gas reaction to form the Co2P/VP [9] The ion exchange process between the (OH-) group of the LDH and the phosphide ion results in the formation of corresponding heterophasic bimetallic phosphide. The scanning electron microscopy (SEM) imagery shows the uniformly grown ultrathin nanosheet structure of the Co2P/VP morphology. The elongation of same morphology shows no over agglomeration throughout the nickel foam, featuring towards the good performance (Fig X). Additionally, the FE-SEM elemental color mapping of the Co2P/VP shows the presence of Co, V, and P, confirming the successful formation of the material (Fig. 1).
Fig. 1. FESEM images of (a-b) Co2P/VP and (c-e) corresponding EDS color maping of the Co2P/VP electrocatalyst
The crystalline structure and the formation of phases of the material was examined through the X-ray diffraction (XRD) examination (Fig. 2). The 2θ corresponding to the 40.7°, 43.2o, and 50.3° are ascribed to the (1 2 1), (2 1 1), and (3 1 0) planes of Co2P, respectively (PDF No. 00-032-0306) [10]. Similarly, the 2θ corresponding to the 28.68°, 32.48°, 35.6°, 43.14°, 57.95°, and 75.43° (002), (100), (101), (102), (110), and (202), are ascribed to the respectively of VP (JCPDS#96-153-9251). Overall, formation of the Co2P and VP phases confirms the formation of Co2P/VP heterostructure.
Fig. 2. XRD patterns of Co2P/VP electrocatalyst
3.1 Electrochemical measurement of the materials
The electrochemical HER performance o the as-synthesized Co2P/VP heterostructure material were evaluated in the typical three electrode system under room temperature using LSV measurement technique at 2 mV s-1 scan rate. The observations were made for CoV-LDH, RuO2, and Co2P/VP heterostructure. The Co2P/VP electrocatalyst performs superior to the comparison electrode materials with the significantly low overpotential η of 96 mV at the current density of 10 mA cm-2, which is close to the overpotential of Pt/C (52 mV) and significantly smaller than the CoV-LDH (131 mV) (Fig. 3a), proving the robustness of the Co2P/VP toward HER. The robustness of the electrode material was measured by evaluating the Tafel slopes (Fig. 3b) [11]. The Tafel slope of the as-prepared Co2P/VP heterostructure is (68.28 mV dec-1), showing the superiority over the comparison electrode materials like, CoV-LDH (110.21 mV dec-1) and closed to the Pt/C (49.14 mV dec-1). The significantly low Tafel slope indicates the robust kinetics of the material owing to the electronic modulation among the electronegative P atom of the entire bimetallic phosphide moiety, hastening the charge/mass transfer along the electrode-electrolyte interface.
Fig. 3. (a) iR-corrected LSV plot, and (b) Tafel plots of the various as-synthesized electrocatalysts for alkaline HER
The electrochemical OER Co2P/VP heterostructure material were evaluated in the identical condition of the three-electrode set up as in the case of HER. The OER performance of the as-synthesized Co2P/VP heterostructure, CoV-LDH, and commercial RuO2 were evaluated through the LSV measurements (Fig. 4a). The results reveals that the Co2P/VP heterostructure has outstanding performance of lower overpotential η of 237 mV, which is superior to the benchmark RuO2 (260 mV) and CoV-LDH (270 mV). The reaction kinetics of the electrode materials were through the Tafel plots after iR-compensation, which shows the lower value of Co2P/VP (116.54 mV dec-1) compared to the RuO2 (125.72 mV dec-1), and CoV-LDH (138.6 mV dec-1) (Fig. 4b). The results clearly indicate that the heterointerface modulated structure could facilitates the reaction kinetics towards the OER performance. Overall, the as-synthesized Co2P/VP is efficient owing to the multiple functional moieties integrated within a composite, which rationally manipulate the electronic structure via the high spin metal cations with the more electronegative P atom within the bimetallic phosphide.
Fig. 4. (a) iR-corrected LSV plot, and (b) Tafel slopes of the various as-synthesized electrocatalysts for alkaline OER
4. CONCLUSIONS
In this research, we have successfully fabricated the heterointerface modulated Co2P/VP ultrathin nanosheets based heterostructure. This unique composite architecture promotes synergistic effect of bimetal-based phosphide moiety in the nickel foam support. The outstanding performance of the material occurs via enhancement of physiochemical properties by creating the multiple active sites, outstanding stability, and hydrophilicity, offers robust HER and OER performances in an alkaline condition with lower overpotential of 96 mV and 260 mV towards HER and OER, respectively at the current density of 10 mA cm-2. This research offers a novel alternative of material engineering through the facile fabrication of bifunctional electrocatalyst for the overall water splitting.
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