Vertically Aligned Ultrathin 1T-WS2 Nanosheets Enhanced the Electrocatalytic Hydrogen Evolution

Abstract Efficient evolution of hydrogen through electrocatalysis holds tremendous promise for clean energy. The catalytic efficiency for hydrogen evolution reaction (HER) strongly depends on the number and activity of active sites. To this end, making vertically aligned, ultrathin, and along with rich metallic phase WS2 nanosheets is effective to maximally unearth the catalytic performance of WS2 nanosheets. Metallic 1T polymorph combined with vertically aligned ultrathin WS2 nanosheets on flat substrate is successfully prepared via one-step simple hydrothermal reaction. The nearly vertical orientation of WS2 nanosheets enables the active sites of surface edge and basal planes to be maximally exposed. Here, we report vertical 1T-WS2 nanosheets as efficient catalysts for hydrogen evolution with low overpotential of 118 mV at 10 mA cm−2 and a Tafel slope of 43 mV dec−1. In addition, the prepared WS2 nanosheets exhibit extremely high stability in acidic solution as the HER catalytic activity and show no degradation after 5000 continuous potential cycles. Our results indicate that vertical 1T-WS2 nanosheets are attractive alternative to the precious platinum benchmark catalyst and rival MoS2 materials that have recently been heavily scrutinized for hydrogen evolution. Graphical Abstract Vertical 1T-WS2 for hydrogen evolution. Electronic supplementary material The online version of this article (10.1186/s11671-018-2570-x) contains supplementary material, which is available to authorized users.


Background
Hydrogen, as a clean fuel, has been considered as a promising alternative for traditional fossil fuels in the future [1,2]. A tremendous amount of effort thus has been made to pursue sustainable and efficient hydrogen production. The electrocatalytic hydrogen evolution reaction (HER) is considered one of the most important pathways to produce hydrogen efficiently [3][4][5]. The most effective HER electrocatalysts up to now are based noble metals (e.g., platinum and palladium) [6,7]. However, the high cost and scarcity of noble metals largely impede their practical utilization. Therefore, developing effective HER electrocatalysts with cheap and earth abundance still remains urgent.
Both experimental and computational studies confirm that the HER activity of TMDCs was mainly resulting from the rare edge surfaces, rather than basal planes [35,36]. Stimulated by this understanding, intense investigations have been concentrated on developing highly nanostructured TMDCs to maximize the number of exposed edge sites, including crystalline and amorphous materials [37][38][39][40][41], metallic 1T polymorph [42,43], vertically aligned structures [44,45], and molecular mimics [46]. Although outstanding accomplishment, many actual challenges yet need to enhance the activity and stability of WS 2 -based catalysts.
Herein, we highlight a pathway to fulfill the assignment. Ultrathin WS 2 nanosheets with perpendicular orientation and 1T metallic phase feature exhibit high activity and stability towards HER in acidic water. Its fast kinetic metrics (e.g., the Tafel slope of 43 mV dec −1 ) indicate superior electrocatalytic activity. This study hints at the promise of cheap and efficient HER electrocatalysts by one-step hydrothermal process.

Experimental Section
Synthesis of the Vertical 1T-WS 2 Nanosheets Vertical 1T-WS 2 nanosheets were manufactured by a simple hydrothermal method on titanium substrate. In a typical procedure, thiourea (CS(NH 2 ) 2 , i.e., 0.4104 g) and hexaammonium heptatungstate ((NH 4 ) 6 W 7 O 24 , i.e., 0. 267 g) were dissolved in 32 mL deionized water under vigorous stirring to form a homogeneous solution. Titanium substrate (1 × 4 cm) was carefully cleaned with concentrated hydrochloric solution, deionized water, and absolute ethanol in an ultrasound bath each for 10 min. The titanium substrate (against the wall) and the aqueous solution were transferred to a 40 mL Teflon-lined stainless steel autoclave. The autoclave was sealed and maintained at 200°C for 7 h and then enabled to cool down to room temperature within 15 min using cooling water. A dark thin film was extracted from the autoclave and subsequently rinsed with deionized water and absolute ethanol, and dried at 60°C under vacuum. The loading mass of WS 2 nanosheets was determined by weighing the titanium substrate before and after hydrothermal process; a surface density of approximately 100 μg cm −2 was obtained.

Synthesis of the Flat 1T-WS 2 Nanosheets
For the synthesis of flat 1T-WS 2 nanosheets, 0.267 g (NH 4 ) 6 W 7 O 24 and 0.4104 g CS(NH 2 ) 2 were dissolved in 32 mL deionized water under vigorous stirring to form a clear solution. Then, the solution was transferred into a 40 mL Teflon-lined stainless steel autoclave, maintained at 200°C for 7 h, and allowed to cool to room temperature naturally. The final product was washed with deionized water and absolute ethanol for several times and dried at 60°C under vacuum. Specifically, the obtained WS 2 catalyst was dispersed in an ethanol solution with a concentration of 0.8 mg ml −1 . Then, we loaded the WS 2 catalyst or Pt/C on titanium substrate by a drop-casting method with a mass loading of approximately 100 μg cm −2 as well. All the materials were purchased from SinoPharm and used without further purification.

Characterization
The morphologies and microstructures of WS 2 nanosheets were characterized via field emission scanning electron microscope (FESEM, Hitachi, Japan) and transmission electron microscopy (TEM, Tecnai F20). The energy-dispersive X-ray spectroscopy (EDS) mapping images were captured on a Tecnai G2 F20 S-TWIN atomic resolution analytic microscope. The binding energies of W and S were determined by X-ray photoelectron spectroscopy (XPS, K-Alpha 1063, Thermo Fisher Scientific, England) using an Al-Kα X-ray source.

Electrochemical Measurements
All electrochemical measurements were performed at room temperature on a standard three-electrode electrolytic system. The saturated calomel electrode (SCE), carbon stick electrode and titanium substrate growth directly with WS 2 nanosheets were served as reference electrode, counter and working electrode, respectively. As for reference, titanium substrate with deposited Pt/C and WS 2 nanosheets (approximately 100 μg cm −2 ) also was regarded as working electrode. The HER activities were conducted by linear sweep voltammetry (LSV) solution with a scan rate of 5 mV s −1 . The stability was tested by taking continuous cyclic voltammograms at a scan rate of 50 mV s −1 from − 0.4 to 0.1 V with 5000 cycles. The striking stability was further demonstrated by using chronoamperometry (j~t) at 160 mV. All the measurements were performed in 0.5 M H 2 SO 4 without iR compensated. The electrolyte solution was purged with high purity nitrogen (N 2 ) for half an hour to remove the dissolved oxygen before testing. Under without special emphasis, all the potentials were here referenced to the reversible hydrogen electrode (RHE) using the following equation:

Results and Discussion
Characterization Supports of Catalysts Figure 1a shows the scanning electron microscopy (SEM) image of the prepared vertical 1T-WS 2 nanosheets with dimensions of ca. 2 μm, which indicated that nanosheets were exceedingly large. As shown in Fig. 1b, the nanosheets are nearly perpendicular to the electrode Ti substrate, which facilitates the exposure of WS 2 edge sites as edge-oriented grapheme on carbon nanofiber [47]. The cross profile of vertical 1T-WS 2 nanosheets is shown in Additional file 1: Figure S1. Meanwhile, crisscross rather than stack occurred between nanosheets. Such an open structure is supposed to allow the fast transportation of proton throughout the catalyst and utilize the basal planet sites for HER as well. Vertical 1T-WS 2 nanosheets in Fig. 1c are extremely transparent, implying that formed nanosheets were ultrathin. The noticeable distortion of nanosheets ( Fig. 1d) helps to decrease their high surface energy to make the WS 2 stable as independent ultrathin nanosheet units. Meanwhile, the luminous line in Fig. 1c, d indicated that prepared WS 2 nanosheets hold excellent conductivity, which is vital for electrocatalytic HER.
The HAADF-SEM image (Fig. 2a) and homogeneously distributed W and S component elements from the corresponding energy-dispersive X-ray (EDX) mapping (Fig. 2b, c) further reveal the successful synthesis of WS 2 nanosheets. In addition, the elemental mapping overlapping of S and W (Fig. 2d)   homogeneous distribution of W and S in WS 2 nanosheets (Additional file 1: Figure S2).
The precise microscopic knowledge of nanostructure materials is of fundamental importance. In Fig. 3a, the high-resolution TEM image (HRTEM) shows the disordered structure of WS 2 nanosheets. Moreover, these WS 2 nanosheets with a thickness of about four layers are dominated by well-defined crystalline edges, thus increasing the density of active sites. To better understand the atomic structure, we have further utilized the Zcontrast. As shown in Fig. 3b, c, the crystal structure of the sheets is not the hexagonal packing usually observed for 2H-WS 2 but rather corresponding to 1T-WS 2 structure. It is obvious that S atoms are evenly distributed between the W and W sites to form a 1T phase, as shown in Fig. 3d. Meanwhile, metallic 1T phase could be converted into semiconducting 2H phase after 300°C annealing treatment, as shown in Additional file 1: Figure S3.
X-ray photoelectron spectroscopy (XPS) was able to confirm the chemical state and composition. All XPS spectra were calibrated using the C 1s peak at 284.8 eV. Meanwhile, XPS could distinguish 1T-and 2H-WS 2 as well. As shown in Fig. 4a, the 2H-WS 2 features two characteristic peaks at around 34.49 and 31.94 eV, corresponding to W4f 5/2 and W4f 7/2 of 2H-WS 2 components, respectively, while the 1T-WS 2 displays the presence of new chemical species clearly shifted toward lower binging energies (33.54 and 31.29 eV, corresponding to W4f 5/2 and W4f 7/2 of 1T-WS 2 components) [48]. The result suggests nanosheets were the mixture of 1T-and 2H-WS 2 . The nanosheets also contain a small amount of tungstate, as evidenced by the signal at 35.14 eV, which corresponds to a W4f 7/2 species. These results are consistent with the known metallic nature of 1T-WS 2 nanosheets, which are susceptible to oxidation [28]. It is worth noting that a slight oxidation of TMDs can improve the density of the active sites, which can enhance the catalytic activities of nanosheets. Nonetheless, exhaustive oxidation should be avoided [10]. The relative percentages of 1T-WS 2 and 2H-WS 2 obtained by integration of the W4f 7/2 peak were 70 and 30%, respectively. Such high concentration of the metallic phase in WS 2 nanosheets may lead to a dramatic enhancement in the catalytic activities [30]. Such phase conformation was desired in electrocatalytic hydrogen evolution. Simultaneously, S 2p region of the spectra (Fig. 4b), the peaks located at 161.6 and 162.7 eV, are assigned to S2p 3/2 and S2p 1/2 , respectively [49]. Moreover, the atom ratio of W and S in the vertical 1T-WS 2 nanosheets by XPS and ICP (in Additional file 1: Table S1) was 1:1.96 and 1:1.94, respectively.
Raman spectroscopy measurements were also performed to further confirm the phase classification. Figure 5a presents Raman spectra collected from vertical 1T-WS 2 nanosheets grown on Ti substrate. Due to the polarization dependence, out-of-plane A 1 g is preferentially excited for edge-terminated nanosheets, whereas the in-plane E 1 2g is preferentially excited for terrace-terminated nanosheets, as illustrated in Fig. 5b. The characteristic Raman shifts at 343 and 411 cm −1 expected for the E 1 2g and A 1 g were clearly observed, respectively [50]. In addition, the additional peaks in the lower frequency regions were previously referred as J1, J2, and J3, corresponding to modes that were only in 1T-type WS 2 and not allowed in 2H-WS 2 [22]. In the Additional file 1: Figure S4, the J1, J2, and J3 peaks after annealing were quenched, which also verify the transformation from 1T phase to 2H phase. These

Evaluation of Electrocatalytic Activity
To assess electrocatalytic performance of vertical 1T-WS 2 nanosheets in HER, measurements are performed in a 0.5 M H 2 SO 4 solution using a typical threeelectrode cell setup. For reference purposes, Ti substrate with a drop-cast commercial Pt benchmark (Pt/C) and WS 2 nanosheets catalysts has also been used as the working electrode.
The polarization curves of all samples are shown in Fig. 6a. The vertical 1T-WS 2 nanosheets exhibit a low overpotential of 118 mV (V vs RHE), compared to the overpotential of 230 mV for WS 2 nanosheets at 10 mA cm −2 . It indicated that rich metallic polymorph (~70%) in basal planes and exposed edge sites of vertical 1T-WS 2 nanosheets can significantly increase the electrochemical HER activity. In addition, the structure of vertical 1T-WS 2 nanosheets guarantees efficient charge flow from the conductive support to active surface site along individual layers. It is in fact a general consideration in designing TMDCs HER catalysts to minimizing ohmic loss, as the interlayer conductivity is 2 order of magnitude lower than intralayer conductivity [8,51]. Electrons are required to traverse the van der Waals gaps to move between the individual layers; therefore, vertical nanostructure does favor for electrons shuttle [44]. Besides, the vertical 1T-WS 2 nanosheets after annealing at 300°C were investigated as well (in Additional file 1: Figure S5), and the hydrogen evolution performance significantly decrease.
Tafel plot in Fig. 6b is used to determine the Tafel slope, which is an important parameter describing HER activity of catalysts. The linear part of vertical 1T-WS 2 nanosheets Tafel plot under small overpotential is fitted to give a Tafel slope of 43 mV dec −1 , which is smaller than those of previously reported values (in Table 1 and Additional file 1: Table S2, including WS 2 /MoS 2 -based catalysts). Tafel slope is associated with the elementary steps in HER. The first step of HER is a discharge step (Volmer reaction, Eq. 1) in which protons are adsorbed to active sites on the surface of the catalysts and combined with electrons to form adsorbed hydrogen atoms. It is followed by a desorption step (Heyrovsky    [52,53].
Under a special set of conditions, when the Volmer reaction is the rate-determining step of HER, a slop of ca. 120 mV dec −1 should result, while a rate-determining Heyrovsky of Tafel reaction should produce slope of ca. 30 and 40 mV dec −1 , respectively [52,53]. In this work, it seems that free energy barrier of discharge step is reduced to be comparable with that of the following desorption or combination step, resulting in the slope of 43 mV dec −1 for vertical 1T-WS 2 nanosheets. Meanwhile, the key step in HER is the adsorption of the proton on the active site. To asses this, we have varied the pH, as shown in Additional file 1: Figure S6. We found that the vertical 1T-WS 2 nanosheets are active over a wide range of pH although the activity decreases when increasing the pH from 0 to 7, which results from the strong diminution of the quantity of protons available.
Stability is another important criterion for electrocatalysts. To assess the long-term durability of vertical 1T-WS 2 nanosheets in an acid environment, continuous HER by CV in the cathodic potential window at an accelerated scanning rate of 5 mV/s were conducted. The polarization curves before and after cycling are recorded under quasi-equilibrium conditions. Polarization curves after the 5000 cycles almost overlay the curve of the initial cycle with negligible loss of cathodic current, as shown in Fig. 6c. It confirms that vertical 1T-WS 2 nanosheets are stable in acidic electrolyte and remain intact through repeated cycling. Meanwhile, vertical 1T-WS 2 nanosheets associated ability to continuously catalyze the generation of H 2 was examined using chronoamperometry (j-t). This quasi-electrolysis process was conducted at a constant of 160 mV in 0.5 M H 2 SO 4 (Fig. 6d). Remarkably, the H 2 evolution can proceed at a sustained current density of − 21 mA cm −2 even over 30 h of continuous operation, indicating the ultrahigh stability of vertical 1T-WS 2 nanosheets.

Conclusions
In summary, we have developed a simple, eco-friendly, and effective hydrothermal method for the synthesis of vertical 1T-WS 2 nanosheets. The vertical 1T-WS 2 nanosheets, with metallic polymorph and exposed edge sites, represent a novel structure of layered materials. The unique structure paves the ways to utilize the edges and planes of layered materials more effectively. Hence, such nanostructure catalysts combined with the scalability of the hydrothermal synthesis can be readily applied in diverse water electrolysis as low-cost, high-performance, and stable HER catalyst.

Additional file
Additional file 1: Fig S1. The cross profile SEM image of the prepared vertical 1T-WS 2 nanosheets on Ti substrate. Fig S2. Whole-energy spectra of vertical 1T-WS 2 nanosheets. Fig S3. (a) and (b) are false-color images responding to vertical 1T-WS 2 nanosheets transform into 2H-WS 2 nanosheets after 300°C annealing treatment, respectively. Fig S4. Raman spectrum of vertical 1T-WS 2 nanosheets (bottom) transform into 2H-WS 2 nanosheets (up) after 300°C annealing treatment. Fig S5. Polarization curves of vertical 1T-WS 2 nanosheets after annealing at 300°C in 0.5 M H 2 SO 4 at a scan rate of 5 mV/s. Fig S6. Variation of current density versus the potential as a function of the pH for the vertical 1T-WS 2 nanosheets. The highest current density is obtained for the lowest pH, consistent with the solution having the highest proton concentration. Table S1. Element analyses of the vertical 1T-WS 2 nanosheets.

Availability of Data and Materials
We declared that materials described in the manuscript, including all relevant raw data, will be freely available to any scientist wishing to use them for non-commercial purposes, without breaching participant confidentiality.

Authors' Contributions
The work presented here was carried out in collaboration between all the authors. QH, KY, and LW synthesized and characterized the prepared catalysts, analyzed the data, performed the statistical analysis, and wrote the manuscript. LW and SL conceived the idea of the study and carefully checked the manuscript. All authors discussed the results and commented on the manuscript. All authors read and approved the final manuscript.

Competing Interests
The authors declare that they have no competing interests.

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