Abstract
Highly (001)-textured, photoactive WSe2 thin films have been prepared by an amorphous solid-liquid-crystalline solid process promoted by palladium. By increasing the thickness of the Pd promoter film (≥10 nm) the structure and texture of the WSe2 films can be improved significantly. However, these as-crystallized WSe2 films are only weakly photoactive in a 0.5 М H2SO4 electrolyte under AM 1.5 solar irradiation which we attribute to an inefficient photogenerated charge transfer across the WSe2/electrolyte interface via the prevailing van der Waals planes of the WSe2 crystallites. In this work photochemically deposited platinum on the p-type WSe2 photocathode is used for an efficient electron transfer thus inducing the hydrogen evolution reaction. Upon illuminating the WSe2 photocathodes in a Pt-ion containing electrolyte, the photogenerated electrons reduce Pt+ to Pt leading to the precipitation of Pt islands, preferentially at edge steps of the WSe2, i.e. at the grain boundaries of the WSe2 crystallites. The increasing amount of Pt islands at the grain boundaries linearly enhances the photocurrent density up to 2.5 mA cm−2 at 0 VRHE in sulfuric acid, the highest reported value up to now for WSe2 thin films.
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Introduction
Photoelectrolysis has attracted considerable attention as an alternative method to the well-known electrolysis to generate solar hydrogen in order to solve the storage problem for solar energy during dark calms1,2,3,4,5. An inherent advantage of photoelectrolysis is that it avoids the use of fossil fuels and thus the emission of carbon dioxide which is the main cause of the climate change observed since many decades.
Among the photocathode materials for the hydrogen-evolution reaction (HER), tungsten diselenide (WSe2) is a very promising semiconductor due to its band gap energy (indirect: Eg = 1.4 eV; direct: Eg = 1.7 eV6), well-matched to the solar spectrum7,8,9 and its high stability in acidic or alkaline solutions10. WSe2 exhibits a layered hexagonal structure11, in common with other transition metal dichalcogenides (TMDC), in which a tungsten monolayer is sandwiched between two chalcogen layers forming a triple layer of Se-W-Se by strong covalent bonding12. These triple layers are stacked over each other along the (001) axis, bonded by weak van der Waals forces.
In former investigations a high photoactivity of WSe2 was only found when single crystalline samples were used13. Prasad and Srivastava demonstrated that photoetching of n-WSe2 reduces surface defects and improves photoactive properties leading to an energy conversion efficiency in polyhalide-based redox systems of more than 17%14. Recently, McKone et al. showed that a p-type, niobium-doped WSe2 single crystal, coated with a Pt/Ru catalyst, splits water with a solar-to-hydrogen conversion efficiency of more than 7%15. They found that bare WSe2 crystals without a catalyst showed only a very small photocurrent, i.e. a low conversion of light to H2. A thin catalytically active Pt/Ru metal film on the WSe2 crystal surface significantly promoted the charge (electron) transfer from the cathode into the electrolyte, leading to a photocurrent density of up to 25 mA cm−2 at 0 VRHE in an acidic solution.
In the past, it was difficult to prepare photoactive WSe2 films on a conducting substrate which is needed for a functioning photocathode16,17,18. Furthermore, for the large-scale application of photoelectrochemical water splitting thin film photoelectrodes are required, i.e. methods have to be developed which allow a cost-effective preparation of semiconductors on large areas19.
Yu et al. demonstrated hydrogen evolution using solution-processed WSe2 thin films coated with a Pt catalyst18. They achieved a maximum photocurrent density of about 1 mA cm−2. But their film deposition method is complex and leads to randomly oriented WSe2 flakes with large areas of thicker films, which results in a low efficiency of the photocathode. Another preparation method, first reported by Tenne et al., relies on a metal-promoter assisted formation of transition metal chalcogenides16. Here, the drawback also was, that the films could not be prepared on a conductive back contact.
Recently, we reported the two-step synthesis of p-type WSe2 thin films on conductive TiN:O back contacts by an amorphous solid–liquid-crystalline solid (aSLcS) process20. This method allows the preparation of highly (001)-textured thin films over a large area for a prospective large-scale solar energy conversion. We have shown that the (metal M) promoter MSex enhances the crystallization of amorphous WSe2+x films considerably and improves the (001) texture and photoactivity of the WSe2 films21,22,23,24,25.
A higher photoelectrochemical cell efficiency can be achieved by improving the morphological properties, i.e. by elimination of cracks and short circuits in the film as well as of structural defects in the WSe2 crystallites that lead to recombination of photoexcited electron-hole pairs. Another challenge of these semiconductors with van der Waals surfaces is the charge transfer to water molecules adsorbed at the surface as shown recently by McKone et al.15. For MoS2, Jaramillo et al. have shown that the most active sites for electrochemical H2 evolution are the edges of MoS2 nanoparticles, where the electrocatalytic activity correlated linearly with the number of edge sites on the hexagonal MoS2 platelets26. This points to the effect of specific sites (at the non-van-der-Waals planes) that mediate an efficient charge transfer at the semiconductor/electrolyte interface.
In the present work we demonstrate the highly textured crystallization of WSe2 films on a conductive back contact and that the photodeposition of Pt islands improves the photoactive properties of polycrystalline WSe2 thin films significantly, allowing the application of these films for solar hydrogen generation. Additionally, the Pt deposition mechanisms on WSe2 and its influence on the solar-to-hydrogen evolution are discussed.
Results and Discussion
Structural and morphological properties
The structural properties of WSe2 films grown by the aSLcS process were reported already in our recent paper20. In the following only the dependence of the structural film parameters on the Pd-promoter thickness is shown, see Fig. 1. With increasing thickness of the Pd-promoter film the crystalline quality of the WSe2 films is considerably improved, which is obvious from the increase of the (002 l)-peak (l = 1–5) intensities by several orders of magnitude, and the corresponding decrease of the full widths at half maximum (FWHM) of the (002) diffraction peaks. Both parameters saturate for promoter thicknesses above 10 nm. The intensity and FWHM of the (002) diffraction peaks of Pd-promoted films almost approach the values for standard LaB6 powder (NIST, SRM 660B) emphasizing a perfect texturized structure of the films (see Fig. S1). The FWHM is only twice as large as the instrumental width of the diffractometer pointing to the large coherently diffracting domains in (001) direction. The average grain sizes, i.e. the size of the coherently diffracting domains, are larger for films, promoted at the highest promoter thicknesses. The (002)-peak positions of the WSe2 films asymptotically approaches the peak position for a standard powder diffraction pattern of WSe2 (JCPDS no. 38–1388), which means that the lattice parameters of the WSe2 film are close to the parameters of a WSe2 single crystal. The structure of the WSe2 films is slightly Se-deficient, since the position of the (002)-peak is shifted slightly to larger 2θ values with respect to the positions of the standard powder WSe2 diffraction pattern, which was also observed for the WSe2 films in our previous work20. As the Pd thickness is increased from 10 nm up to 20 nm the lateral size of the crystallites is enlarged, demonstrating the promotion effect of the Pd, see Fig. 2a,b. The average lateral size for the best crystallized WSe2 films is about 1–2 µm, inferred from the SEM pictures. Regula et al. studied the peak width of the (002) diffraction peak of a Ni promoted WS2 film crystallized at 850 °C as a function of the Ni thickness21. Here, the FWHM decreased from 0.8° down to 0.18°, as the thickness of Ni was increased from 0 to 10 nm. We observe a similar decrease in FWHM from 1° to 0.14° as the thickness of Pd is increased from 0 to 20 nm. The schematic cross section of the WSe2 films, crystallized with Pd-promoter on Ti/TiN:O/SiO2/Si substrates is depicted in Fig. 2c.
The degree of the (001) texture of the crystallites was investigated by rocking curve measurements of the (002) reflection at θ = 6.84°, see Fig. 3a. All films, crystallized with Pd-promotion, show very narrow rocking curve widths pointing to the excellent structural quality of the WSe2 crystallites. The FWHM of the rocking curves reaches a minimum of 0.07°, which is comparable to values typically obtained for epitaxial thin films27.
Optical and photoactive properties
The optical absorption properties of the tungsten selenide films were studied in the photon energy range of 1.2–4 eV (Fig. 4a). After annealing at 550 °C, the thickness of an amorphous 340 nm WSe2+x film is dramatically changed to 70 nm (5 times) caused by the evaporation of the excess Se. This was proved by Rutherford backscattering spectroscopy studies in our previous paper20, where the Se-to-W ratio changed significantly from about 10 to 2 (i.e. WSe2) after annealing above 300 °C. As can be seen in Fig. 4a the absorbance of the film is reduced with decreasing WSe2 thickness. The crystallization of amorphous WSe2+x films with 10 and 20 nm Pd layers, respectively, leads to larger thicknesses than that of the films crystallized without Pd-promoter due to the formation of larger WSe2 domains (see Fig. 1b) and PdSex crystallites. Therefore, the absorption of the thicker WSe2 films crystallized with the 20 nm of Pd layer tends to have larger absorbance values in the photon energy range of 1.2 to 2.3 eV. At higher Pd layer thickness (20 nm) a sharpening of the A exciton peak at 1.63 eV is observed, which is attributed to the direct transitions from the split valence band to the conduction band12, demonstrating the improved electronic structure of the film. The maximum measured absorption coefficient of the films is in the order of 105 cm−1 (Fig. S2). This extraordinarily high absorption coefficient of the films is caused by the characteristic bandgaps for the TMDC like MoS(e)2 and WS(e)26 in the range of 1.5–1.9 eV.
The increase of the Pd promoter thickness (>20 nm) leads to an improvement of the crystaline structure of the WSe2 films (Figs S3 and S4) and to the formation of the Pd-rich metallic phase PdSex, which can act as recombination centers and/or short circuits20. The absorbance spectra of the WSe2 films, crystallized with the increasing Pd thicknesses from 10 to 50 nm, do not change considerably, however the photoactivity of the WSe2 films varies much, which was proved by time resolved microwave conductivity (TRMC) mesurements28. The lifetimes of the charge carriers for the fast and slow decay components of the WSe2 films (50 ns and 0.5 µs) are of the same order of magnitude as for MoS2 and WS2 nanopowders, measured by the pulsed cathodoluminescence method9,29,30. The short lifetime is attributed to band-to-band recombination, whereas the slow component is connected with trap states in the bandgap. Increasing the Pd thickness from 20 nm to 50 nm results in a significant reduction of the mobility of the carriers from 34 to 3 cm2 V−1s−1 and their diffusion lengths DL1 from 2 to 0.5 µm (DL2 from 6.7 to 1.8 µm) due to the recombination of the photoexcited electron-holes at the metallic PdSex phase. Thus, the optimum Pd thickness for crystallization of WSe2 film can be concluded to be 20 nm, which leads to films with better structural and electronic qualities (Figs 1 and 4).
Photoelectrochemical performance
The WSe2 films in the as-crystallized state, though exhibiting a highly (001)-textured morphology, showed only a marginal photocurrent (less than 0.1 mAcm−2 at 0 V vs. RHE). This is in accordance with a recent measurement of the photoactivity of WSe2 single crystals where also only a tiny photocurrent was observed for a bare WSe2 crystal15. Yu et al., on the other hand, observed for their nanoflake WSe2 films, which exhibit a large number of grain boundaries, a low photocurrent also in the as deposited state, i.e. without applying a catalyst18. This indicates that the surface and morphology of our WSe2 films is comparable to that of WSe2 single crystals with respect to the role of crystallographic defects, i.e. grain boundaries, for the charge transfer from the solid to the electrolyte.
In order to increase the photocurrent of our WSe2 films, Pt nanoislands were precipitated on top of the WSe2 films, at first by electron beam evaporation at room temperature (Fig. 5a). Instead of a homogenous thin film, Pt islands were formed which are distributed quite homogenously on the WSe2 surface. However, we could not observe an increase of the photocurrent. On the other hand, the photodeposition of Pt islands at open circuit potential in an electrolyte (0.1 M HCl with Pt salt) led to a significant increase of the photocurrent density (Fig. 5). At light on conditions, the open circuit potential (OCP) is raised up to its maximum value due to the increasing number of photogenerated electron-hole pairs; at light off conditions the electron-holes pairs recombine, and consequently the OCP decreases (Fig. 5b). During the illumination of the WSe2 photocathode the Pt ions in the electrolyte react with the photogenerated electrons and are deposited at the most active sides of the WSe2 crystallites, i.e. at the grain boundaries (see Figs 5c and S6). At OCP conditions the electric field induced at the surface of the WSe2 film by electrons causes the Pt ion flow from the electrolyte to the photocathode surface (local flow), i.e. there is no current flowing in the external circuit. Due to the strong crystallographic and electrical anisotropy of the WSe2 crystallites, the photogenerated charge carriers are transported within the basal {001}-planes, i.e. perpendicular to the (001)-direction, eventually reaching the grain boundaries where they can be transferred to the electrolyte inducing an electrochemical reaction. Thus, the Pt islands are growing in the regions of the highest electron current, i.e. at the edges/grain boundaries of the WSe2 crystallites. An increase of the Pt-deposition time (number of photodeposition cycles) leads to an increase of the number and the size of the Pt islands on the WSe2 films (see Fig. 5c,d), which results in an increase of the photocurrent density. This is clearly visible from Fig. 5c which shows photochemically deposited Pt islands after a deposition time of 180 s, preferentially formed at edges/grain boundaries. After 360 sec photodeposition (Fig. 5d) bigger Pt-islands were grown on top of the crystallites as well as at the grain boundaries.
The morphology of the WSe2 films varies considerably in dependence on the crystallization pressure of the H2Se gas (Figs 2b and 5c). The crystallization at a lower pressure (1.25 Pa) leads to films with smaller crystallite sizes (1–2 µm) compared to that (4–5 µm) of films crystallized at higher pressures (10 Pa). This is obviously due to the compensation (suppression) of the evaporation pressure of Se from the WSex films by higher H2Se gas pressures resulting in the formation of larger crystallites. Etching of the films in aquaregia (for 30 sec) increases the number of edge sides and decreases the crystallite size (Fig. 5a).
In Fig. 6 the chopped (light/dark) I-V curves of the pure and Pt-deposited WSe2 films are displayed. The pure WSe2 film exhibited only a very small photocurrent in sulfuric acid. This can be attributed to the fact that the edge sites (i.e. the grain boundaries) of the crystallites are the sites where the photocurrent is transferred to the WSe2/electrolyte interface, the density of which is quite low in our large-grained WSe2 films. This is in agreement with a recent publication of Jaramillo et al.26 who identified the edge sites of MoS2 crystallites, also a layer-type semiconducting material, structurally very similar to WSe2, as the catalytically active sites. The increase of the photocurrent with increasing Pt deposition time shows that the Pt catalyst improves the reaction kinetics, i.e. the rate of electron transfer to the electrolyte. The fast decrease of the photocurrent (see the spikes in Fig. 6) after switching on the light, indicates a recombination of charge carriers.
Due to the small discrete islands compared with the area measured, it is difficult to exactly determine the sizes of the islands. Nevertheless, we tried to evaluate the average Pt thickness by energy dispersive X-ray fluorescence spectroscopy (EDX). The average thickness of the platinum on the WSe2 film, assuming a homogenous distribution over the entire surface area, equals to about 1 nm, which is in the range of the sensitivity limit of the method (Fig. S7 and Tables S2–S5). Since the surface coverage is in the order of 4% only, the size of each Pt island is in the order of 90 nm. The maximum photocurrent density is reached after 12 cycles of Pt deposition. Further increasing the Pt thickness leads to a decrease of the photocurrent, which we attribute to the increased shadowing of the WSe2 film by the opaque Pt islands (see below).
A continuous Pt-photodeposition under open circuit conditions leads to a better performance of the WSe2 films (Fig. 6d), since each I-V testing in 0.5 M H2SO4 after each Pt-deposition cycle influences the further formation of Pt nanoislands. We assume that an interruption of Pt-deposition followed by IV-testing (charge transfer through Pt nanoislands) in 0.5 M H2SO4 leads to precipitation of unfunctionalized Pt nanoislands (see Fig. 6a,b). The highest photocurrent density of 1.4 mA cm−2 is reached after 12 continuous cycles, which is significantly higher than the value of 0.56 mA cm−2 shown in Fig. 6a. An increase in the WSe2 film thickness from 100 nm to 150 nm resulted in a further increase in the photocurrent density from 1.4 mA cm−2 to 2.5 mA cm−2 (Fig. 6c), which is due to a better absorption of the light (Fig. 4) and consequent generation of a higher concentration of the electron-hole pairs. For this film we also observed the shadowing effect by increasing the number of Pt nanoislands at maximum deposition time (Fig. S8), which leads to a gradual decrease of the photocurrent density.
IPCE spectrum
The incident-photon-to-current (IPCE) spectrum for a WSe2 film with a catalyst (ammonium thiomolybdate-ATM31), comparable to platinum, is shown in Fig. 7. The conversion efficiency is low (7–17%), pointing to the still improvable intrinsic quality of our WSe2 films; for comparison, the WSe2 single crystals of McKone et al. exhibit an external quantum effiency of 50 to 60%15.
The spectral features of the IPCE curve (Fig. 7) resemble that of the absorption spectrum of WSe2, i.e. the observed photocurrent is due to the absorption in the WSe2 film. Especially remarkable is the appearance of the A exciton at about 1.6 eV7. This exciton has a high binding energy of about 55 meV, explaining its visibility at room temperature. The photocurrent density of the WSe2 photocathode, calculated from the IPCE curve is about 3.1 mA cm−2, which is close to the 2.5 mA cm−2 measured under AM1.5 illumination.
H2 evolution
The H2 production of the WSe2 photocathode under AM1.5 illumination was measured with a two burette system with manual pressure compensation according to King and Bard32, see Fig. 8. For the H2 evolution, 2 electrons and for O2 production 4 electrons are required, respectively, i.e. the volume of evolved H2 must be twice as much as the O2 volume33. This relation is fulfilled in our case where we obtain a volume ratio of 2.2. The WSe2 photocathode was operated at a lower photocurrent density of about 1.25 mA cm−2 due to the high serial resistance between the two burettes, which were connected with a narrow 8 cm long glass tube. The overall electrical charge transferred, was about 9 Coulomb, which had produced 1.8 ml of H2 gas under illumination of a 2 cm2 photocathode area during 2 hours, see Fig. 8. From these data a Faradaic efficiency of 81% can be calculated, which shows a high transition rate of electrons to produce hydrogen H2 from the H+ ions.
Surface analysis
The surface properties of the WSe2 films were tested by the X-ray photoelectron spectroscopy (XPS), see Fig. 9a,b. The XPS spectra of the WSe2 film show the presence of two tungsten-containing phases: the prominent peaks at 32.25 eV and 34.4 eV can be attributed to the WSe2, the weaker peaks at 35.7 eV and 37.85 eV are due to a small amount of tungsten oxide similar to other reports34,35. The doublet peaks at 54.5 eV and 55.3 eV correspond to only selenium environment present in the film. The XPS spectra of the as-prepared and the photoelectrochemically tested WSe2 films revealed an oxidation of the film after 13 cycles of IV-testing (Fig. 6), where both W and Se peaks are shifted to higher energies (ΔE = 0.5 eV). Azcatl et al.36 studied the surface of WSe2 upon ultraviolet (UV)–O3 exposure by in situ XPS, where the WSe2 layer was oxidized to WSexOy. Similar to this report we observe the shifted Se 3d and W 4f peaks at 55.8 eV and 32.8 eV assigned to the WSexOy phase (55.4 eV and 33.1 eV), which actually proves the photocorrosion of the WSe2 film after IV-testing in 0.5 М H2SO4 acid upon illumination.
Conclusions
We have improved the structural quality and the photoactivity of highly (001)-textured WSe2 films on quartz glass and on TiN:O back contacts, prepared by the amorphous solid-liquid-crystalline solid crystallization process, assisted by a Pd promoter layer, which was reported recently by us20. Increasing the thickness of the Pd film improves the structure and the photoactivity of the WSe2 films. However, the as-crystallized WSe2 films are only weakly photoactive at AM 1.5 solar irradiation in a 0.5 М H2SO4 electrolyte which we attribute to an inefficient photogenerated charge transfer to the WSe2/electrolyte interface via the dominating van der Waals planes of the WSe2 crystallites.
Only after photochemical deposition of Pt, resulting in Pt nanoislands deposited preferentially at the WSe2 grain boundaries, a significant photocurrent was observed that is attributed to hydrogen evolution. This result can be explained by the fact that WSe2 edge sites (i.e. mostly the grain boundaries) of the crystallites are the active sites where the photogenerated electrons are transferred to the WSe2/electrolyte interface. This is in agreement with a recent publication of Jaramillo et al.26 who identified the edge sites of MoS2 crystallites, also a layer-type semiconducting material, isostructural with WSe2, as the catalytically active sites.
An interplay between deposition parameters like the film and metal-promoter thicknesses, crystallization pressure and temperature, obviously influences on the grain sizes and their orientation, crystal structure, optical and electronic qualities of the WSe2 films. Our Pt-coated WSe2 films exhibit a photocurrent density in an acidic electrolyte (0.5 М H2SO4) up to 2.5 mA cm−2 under AM1.5 illumination, the highest photocurrent density reported up to now for thin WSe2 films. These encouraging results open a new large-area-scalable preparation route for photocathodes for solar hydrogen evolution.
Methods
Synthesis of the WSe2 films
The highly (001)-textured tungsten diselenide thin films have been prepared by the amorphous solid-liquid-crystalline solid (aSLcS) process on pure quartz glass (QG) and on oxidized Si substrates coated with a TiN:O metallic back contact. The preparation details have been reported recently; therefore only a short description is given here20,24. At first, X-ray amorphous, Se-rich WSe2+x (x ≫ 1) films were deposited by reactive magnetron sputtering from a tungsten target in an Ar/H2Se atmosphere at room temperature onto a thin Pd-promoter film onto the chemically inert TiN:O back contact layer. Afterwards these amorphous films were crystallized by the aSLcS process in an H2Se atmosphere at a pressure of about 10 Pa at a substrate temperature of 550 °C during 10 min. In order to improve the adhesion of the WSe2 film a 2 nm thin Ti or Cr film was deposited by electron beam evaporation (EBE) onto the TiN:O back contact. The surface temperatures of the quartz and the TiN:O/SiO2/Si substrates were calibrated relative to the heater temperature (Fig. S9). A schematic cross section of the Pt-WSe2:PdSex/TiN:O/SiO2/Si photocathode is shown in Fig. 2c.
Film characterization methods
The film structure, the phase composition and the texture quality (derived from rocking curves) were characterized by X-ray diffraction (XRD) using a PANalytical XPert MPD diffractometer with CuKα radiation (0.15408 nm), while the film morphology and the element distribution were analyzed by scanning electron microscopy (SEM) and energy dispersive X-ray fluorescence analysis (EDX) with a LEO GEMINI 1530 electron microscope.
UV−vis measurements were carried out with a PerkinElmer Lambda 950 double-beam spectrophotometer in the wavelength range from 300 to 1000 nm.
Time resolved microwave conductivity (TMRC) measurements of the films were carried out by a 10 ns (FWHM) frequency-doubled Q-switched Nd:YAG laser pulse using a 532 nm wavelength and at an intensity of 1.28 × 1011 photons cm−2.
The chemical composition of the WSe2 film surface was studied by X-ray photoelectron spectroscopy (XPS) using a monochromatic Al Kα source (1486.74 eV).
Photochemical Pt deposition
1 mM K2PtCl4 was dissolved in 0.1 M HCl solution in order to deposit Pt on top of WSe2/Pd/TiN:O layer stack. The photodeposition of Pt was carried out at open circuit potential (≈0.2 V) under continuous or periodic light exposure. In the latter case, the shutter was opened and closed every 30 seconds.
Photoelectrochemical measurements
These measurements were performed in a three-electrode set-up using a potentiostat (EG&G Princeton Applied Research, model 273 A) with an Ag/AgCl (saturated KCl and AgCl solution) reference electrode and a Pt coil as counter electrode. The illumination was provided by a solar simulator (WACOM, model WXS-505-5H; AM1.5, 100 mWcm−2). For contacting the WSe2 film, a metallic wire was attached to the TiN:O back contact with an adhesive Ag metal sheet. In order to improve the contact, an In-Ga (liquid) eutectic was added between the metal sheet and the back contact TiN:O. The cyclic voltagrams were taken in the potential range from 0.5 V to −0.3 V with a scan rate of 20 mV s−1. Polycrystalline films of WSe2/Pd with thicknesses from 100 to 150 nm were the working electrode (cathode). The sample was periodically illuminated with an exposure and dark time of 2 sec each. The exposed electrode area was 0.24 cm2.
Change history
25 May 2018
A correction to this article has been published and is linked from the HTML and PDF versions of this paper. The error has been fixed in the paper.
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Acknowledgements
The authors would like to thank Fanxing Xi for SEM analysis and the ATM deposition, Moritz Kölbach for SEM/EDX analysis, Paul Plate for XPS, and Sean Berglund for his help with the PEC measurements. The research association Optotransmitter-Umweltschutz-Technologie e.V. (Berlin, Germany) is acknowledged for the preparation of the TiN:O back contact layers. F.B. acknowledges the Ministry of Education and Science of the Republic of Kazakhstan for a research fellowship under the program no. 0115РК03029 “NU-Berkeley strategic initiative in warm-dense matter, advanced materials and energy sources for 2014–2018” and grants from Tomsk (Russia) Polytechnic University Competitiveness Enhancement Program and National Nanotechnology Laboratory of open type of Al-Farabi Kazakh National University, Almaty (Kazakhstan), 0263/PSF.
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K.E. and F.B. conceived the study. F.B. and K.H. performed the deposition experiments. F.B. did the XRD and PEC measurements of the films. C.Z. and D.F. measured and analyzed the TRMC data. F.B. and K.E. analyzed the data. F.B. drafted the manuscript and K.E. finished the manuscript using the contributions from the other authors.
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Bozheyev, F., Harbauer, K., Zahn, C. et al. Highly (001)-textured p-type WSe2 Thin Films as Efficient Large-Area Photocathodes for Solar Hydrogen Evolution. Sci Rep 7, 16003 (2017). https://doi.org/10.1038/s41598-017-16283-8
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DOI: https://doi.org/10.1038/s41598-017-16283-8
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