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Scalable Low-Bandgap Sb2Se3 Thin-Film Photocathodes for Efficient Visible-Near-Infrared Solar Hydrogen Evolution Li Zhang, Yanbo Li, Changli Li, Qiao Chen, Zhen Zhen, Xin Jiang, Miao Zhong, Fuxiang Zhang, and Hongwei Zhu ACS Nano, Just Accepted Manuscript • DOI: 10.1021/acsnano.7b07512 • Publication Date (Web): 22 Nov 2017 Downloaded from http://pubs.acs.org on November 23, 2017
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Scalable Low-Bandgap Sb2Se3 Thin-Film Photocathodes for Efficient Visible-NearInfrared Solar Hydrogen Evolution Li Zhang1, Yanbo Li2, Changli Li1, Qiao Chen1, Zhen Zhen1, Xin Jiang1, Miao Zhong3, Fuxiang Zhang4, Hongwei Zhu1* 1
State Key Laboratory of New Ceramics and Fine Processing, School of Materials Science and Engineering, Tsinghua University, Beijing 100084, China 2 Institute of Fundamental and Frontier Sciences, University of Electronic Science and Technology of China, Chengdu 610054, China. 3 Department of Electrical and Computer Engineering, University of Toronto, 35 St. George Street, Toronto, Ontario M5S 1A4, Canada. 4 State Key Laboratory of Catalysis, iChEM, Dalian Institute of Chemical Physics, Chinese Academy of Sciences, Dalian National Laboratory for Clean Energy, Dalian, 116023, China.
Abstract A highly efficient low-bandgap (1.2−0.8 eV) photoelectrode is critical for accomplishing efficient conversion of visible-near-infrared sunlight into storable hydrogen. Herein, we report Sb2Se3 polycrystalline thin film photocathode having a low-bandgap (1.2−1.1 eV) for efficient hydrogen evolution for wide solar-spectrum utilization. The photocathode was fabricated by a facile thermal evaporation of single Sb2Se3 powder source onto the Mo-coated soda-lime glass substrate, followed by annealing under Se vapor and surface modification with antiphotocorrosive
CdS/TiO2
bilayer
and
Pt
catalyst.
The
fabricated
Sb2Se3(Se-
annealed)/CdS/TiO2/Pt photocathode achieves a photocurrent density of ca. −8.6 mA cm−2 at 0 VRHE, an onset potential of ca. 0.43 VRHE, a stable photocurrent for over 10 h, and a significant photoresponse up to near-infrared region (ca. 1040 nm) in near-neutral pH buffered solution (pH 6.5) under AM 1.5G simulated sunlight. The obtained photoelectrochemical performance is attributed to the reliable synthesis of micrometer-sized Sb2Se3 (Se-annealed) thin film as photoabsorber and the successful construction of appropriate p-n heterojunction at the electrode-liquid interface for effective charge separation. The demonstration of low-bandgap and high-performance Sb2Se3 photocathode with facile fabrication might facilitate the development of cost-effective PEC devices for wide solar-spectrum utilization. Keywords: antimony selenide, photocatalysis, surface modification, thin films, water splitting
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Effective utilization of solar energy requires a reliable energy storage technique to tackle the dilute and intermittent nature of sunlight.1,2 Hydrogen, regarded as a storable and clean fuel, is potentially one of the most reliable energy carriers for carbon-neutral and sustainable society if it can be produced from renewable energy resources such as solar energy.3−5 Photoelectrochemical (PEC) hydrogen production via water splitting, which employs semiconducting materials as photoelectrodes for the direct conversion of solar energy into storable hydrogen, represents one of the most promising but challenging techniques for sustainable solar energy storage.6−9 Among various types of PEC configurations,6,10 stacked dual-electrode PEC cell, consisting of a high-bandgap and a low-bandgap photoelectrodes with optimal bandgap combination of approximately 2.0−1.6 and 1.2−0.8 eV, respectively, which are suitable for their respective ultra-violet-visible and visible-near-infrared sunlight absorption, has been identified as one of the most attractive approaches to achieve solar-to-hydrogen (STH) conversion efficiency of around 20%.11,12 In recent years, impressive progress has been achieved on the high-bandgap photoelectrode materials, which include a multitude of n-type semiconductors such as BiVO4,13,14 Fe2O3,15−17 TiO2,18,19 WO3,20,21 (Ca,Sr,Ba,La)(Ti,Ta,Nb)(O,N)3,22−24 and Ta3N5,25−27 as well as several p-type semiconductors
such
as
GaInP2,28,29
(Ag,Cu)GaSe2,30,31
Cu(In,Ga)S2,32,33
Cu2(Zn,Ba)Sn(S,Se)4,34,35 and Cu2O.36−39 However, studies on ideal low-bandgap (1.2−0.8 eV) photoelectrode materials well-suited for stacked dual-electrode PEC cell are almost limited to n-/p-Si9,40−43 and p-Cu(In,Ga)Se2 (or its solid solution with ZnSe)44,45 owing to the scarcity of suitable low-bandgap photoelectrode materials. This situation, therefore, brings our attention to exploring new low-bandgap photoelectrodes, which ideally should be based on simple semiconducting materials with characteristics of inexpensive elements and facile production at large scale.
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In this regard, antimony selenide (Sb2Se3) belongs to V2−VI3 (V = As, Sb, Bi; VI = S, Se, Te) binary materials that have been attracting tremendous research interests owing to their potential applications in thermoelectric and photovoltaic areas,46−48 as well as Li- and Na-ion batteries.49 Sb2Se3 appears to be a promising candidate as a lowbandgap photoelectrode for the stacked duel-electrode cell because of the following advantageous features: (1) Sb2Se3 has an ideal low-bandgap value (1.2−1.0 eV) and a high optical absorption coefficient (around 105 cm−1 near the absorption onset),47,48 which permits a strong visible-near-infrared sunlight absorption. (2) The constituent elements of Sb and Se in Sb2Se3 are relatively earth-abundant, inexpensive, and lowtoxic.48 (3) The Sb−Se phase diagram has only one simple binary compound, 50 namely, the orthorhombic Sb2Se3, indicating the phase and defects of Sb2Se3 could be much easier to control than the typical multinary chalcogenides such as the Cu(In,Ga)(S,Se) 2 and Cu2ZnSn(S,Se)4.51,52 (4) Sb2Se3 has a low melting point (ca. 600oC) and a high saturated vapor pressure (ca. 1200 Pa at 550°C).50 These two characteristics enable the preparation of the high-quality Sb2Se3 polycrystalline thin films at a relatively low temperature using thermal sublimation of powder source, which is a facile and highthroughput deposition technique that has been successfully adopted in the welldeveloped CdTe photovoltaics.53,54 For instance, only ca. 10 g of Sb2Se3 powder source (assuming material utilization of 50%−90%) is needed to make a 1 m2 Sb2Se3 thin film with a thickness of 1 m. (5) As an intrinsically p-type semiconductor, Sb2Se3 has the conduction band minimum (CBM) locating at −4.15 eV55 (i.e., −0.29 VNHE at pH=0). Thus, it is suitable as a photocathode for hydrogen evolution. In addition, Sb 2Se3 polycrystalline thin film as an emerging photoabsorber for solar cells has achieved a solar conversion efficiency of around 6%,47 which is an encouraging initial step towards the Shockley-Queisser theoretical maximum efficiency of around 30% (using bandgap of 1.2−1.0 eV).56 Therefore, it is promising to achieve an outstanding performance of 3
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Sb2Se3 polycrystalline thin-film photocathode for hydrogen evolution. All these highly appealing merits encourage the systematic investigation of Sb 2Se3 polycrystalline thin film as a low-bandgap photocathode for solar-driven hydrogen evolution. However, to date, there is no attempt on Sb2Se3 polycrystalline thin-film photocathode coupled with appropriate p-n junction for efficient and stable solar hydrogen evolution in benign neutral electrolyte (i.e., close to the naturally-available seawater and rainwater), except that very few reports have disclosed the utilization of Sb2Se3 nanoneedles/nanowires as photocathodes for hydrogen evolution under harsh acidic electrolyte.57,58 Herein, we demonstrated that the large-scale Sb2Se3 polycrystalline thin-film photocathode, prepared by facile thermal evaporation of single Sb 2Se3 powder source coupled with suitable annealing under the Se vapor and rational surface-engineering by the CdS/TiO2 bilayer and Pt catalyst, afforded a stable photocurrent density of ca. −8.6 mA cm−2 at 0 VRHE and an onset potential of ca. 0.43 eV in near-neutral pH buffered solution (pH 6.5) under simulated sunlight, thus enabling the fabricated Sb 2Se3 photocathode to exhibit one of the highest PEC performance ever reported for Sb2Se3based electrodes in water splitting.57,58 Moreover, the obtained PEC performance of Sb2Se3 photocathode in this study was comparable to the state-of-the-art polycrystalline thin-film photocathodes based on earth-abundant binary photoabsorbers such as Cu2O,36−39 CuO,59 and WSe2.60 The highly efficient PEC performance combined with the straightforward, inexpensive, and scalable process, demonstrated the great potential of low-bandgap Sb2Se3 in fabricating cost-effective PEC devices with a wide solarspectrum utilization for water splitting.
Results and discussion Fabrication and surface modification of Sb2Se3 thin films
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As shown in Figure 1a, Sb2Se3 thin film was prepared by facile thermal evaporation of single Sb2Se3 powder source onto Mo-coated soda-lime glass (SLG/Mo) substrate, followed by annealing to obtain a high-quality polycrystalline thin film. The surface of the annealed-Sb2Se3 thin film was then modified with n-type CdS to form a p-n heterojunction. The SLG/Mo substrate (Figure 1b), as-deposited Sb2Se3 (Figure 1c), 450oC-annealed Sb2Se3 (Figure 1d), and CdS-modified 450oC-annealed Sb2Se3 (Figure 1e) were all homogeneous in appearance over large area ( 20 cm2). This result indicated the employed process for Sb2Se3 thin films is straightforward, high-throughput, and potentially feasible to scale-up. Scanning electron microscopy (SEM) image revealed that the sputtered Mo (Figure 1f) exhibited typical fish-like grains, a prerequisite to avoid possible peeling-off of the Sb2Se3 thin films from the Mo substrate when annealing is performed. The as-deposited Sb2Se3 thin films (Figure 1g) were amorphous, whereas the 450oC-annealed Sb2Se3 sample (Figure 1h) was polycrystalline consisting of micrometer-sized elongated grains that packed tightly to form the thin-film Sb2Se3. The observed pin-holes in Figure 1h were probably due to the slight re-evaporation of Sb2Se3 during the annealing process. The CdS-modified 450oC-annealed Sb2Se3 (Figure 1i) exhibited a homogenous coverage by CdS overlayer. The cross-sectional SEM image of as-deposited Sb2Se3 on the SLG/Mo substrate (Figure 1j) indicated that the Sb2Se3 densely covered on the Mo substrate with a thickness of ca. 1.5 m. The cross-sectional view of CdS-modified 450oCannealed Sb2Se3 (Figure 1k) revealed the Sb2Se3 layer consisting of large columnar grains are uniformly covered by CdS overlayer (ca. 80 nm). It is noteworthy that the obtained the Sb2Se3 thin film with large columnar grains is benefited from the low melting temperature of Sb2Se3 (ca. 600oC) and is a highly desirable microstructure for high-performance polycrystalline thinfilm solar cells61 and photocathodes.62,63
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(a)
Substrate Mo/SLG
Amorphous Sb2Se3 Sb2Se3 depositing
Surface modification Sb2Se3/CdS
Polycrystalline Sb2Se3 Annealing
CdS coating
(b)
(c)
(d)
(e)
(f)
(g)
(h)
(i)
1 m
1 m
1 m
(j)
(k)
1 m
CdS
Sb2Se3
Mo 1 m
SLG
1 m
Figure 1. (a) Schematic of fabrication process for CdS-modified Sb2Se3 thin films. (b−e) Optical images of the SLG/Mo substrate, as-deposited Sb2Se3, 450oC-annealed Sb2Se3, and CdS-modified 450oC-annealed Sb2Se3. (f−i) Top-view SEM images of the SLG/Mo substrate, as-deposited Sb2Se3, 450oC-annealed Sb2Se3, and CdS-modified 450oC-annealed Sb2Se3. (j, k) Cross-sectional SEM images of the as-deposited Sb2Se3 and CdS-modified 450oC-annealed Sb2Se3.
PEC properties of Sb2Se3-based electrodes Figure 2 displays the PEC performance of Sb2Se3-based electrodes under AM 1.5G simulated sunlight illumination (Figure S1, Supporting Information). As shown in Figure 2a, the bare Sb2Se3 electrodes annealed at 350−450oC under Ar atmosphere exhibited cathodic photocurrents, whereas the bare Sb2Se3 annealed at 300oC showed a
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weak anodic photocurrent, indicating appropriate annealing temperature is required to obtain p-type Sb2Se3. Meanwhile, the observed low cathodic photocurrent on all of the p-type Sb2Se3 electrodes (350−450oC) implies the poor PEC performance of bare Sb2Se3 photocathodes, suggesting the indispensability of further improvement through rational engineering of the Sb2Se3/liquid interface. After the surface decoration of Pt nanoparticles as the hydrogen evolution catalyst (Sb2Se3/Pt, Figure 2b), a significant enhancement in photocurrent was observed for all Sb2Se3 photocathodes. With inserting an n-type CdS layer between Sb2Se3 and Pt (Sb2Se3/CdS/Pt, Figure 2c), a drastic enhancement in photocurrent was further obtained owing to the formation of a p-n heterojunction between Sb2Se3 and CdS. In particular, the fabricated Sb2Se3/CdS/Pt photocathodes with Sb2Se3 annealed at 400oC achieved the highest photocurrent density of ca. −2.3 mA cm−2 at 0 VRHE and an onset potential of ca. 0.35 VRHE (defined as the potential where a photocurrent density exceeds −0.05 mA cm−2, similarly hereinafter) in neutral electrolyte under AM 1.5G simulated sunlight. Notably, the time course of photocurrent for Sb 2Se3 (Figure 2d) and Sb2Se3/Pt (Figure 2e) showed a stable cathodic photocurrent, whereas the Sb2Se3/CdS/Pt (Figure 2f) exhibited a gradual decay within 1 h, which could be attributed to the partial photocorrosion of CdS and the accompanying loss of Pt catalyst.63 The obtained promising PEC performance of Sb2Se3/CdS/Pt electrode highlights the great potential of Sb2Se3 as photocathodes for hydrogen evolution because largescale Sb2Se3 polycrystalline thin films with micrometer-sized grains can be readily produced by facile thermal evaporation of Sb2Se3 powder source along with a moderate annealing. However, further enhancement on the photocurrent and stability is needed to demonstrate a PEC performance that can be comparable to the state-of-the-art and emerging binary photocathodes. Thus, the further enhancement was pursued through
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annealing of Sb2Se3 in the presence of Se vapor and protective coating of CdS surface by anti-photocorrosive TiO2, as discussed in the following paragraphs.
Figure 2. (a−c) Current-potential curves of bare Sb2Se3, Sb2Se3/Pt, and Sb2Se3/CdS/Pt electrodes under chopped illumination by AM 1.5G simulated sunlight. The Sb2Se3 samples were annealed at the different temperatures under Ar atmosphere. (d−f) Currenttime curves of 400oC-annealed bare Sb2Se3, Sb2Se3/Pt, and Sb2Se3/CdS/Pt electrodes at 0 VRHE under AM 1.5G simulated sunlight, a chopped illumination was applied to the bare Sb2Se3 for a better observation of the extremely low cathodic photocurrent. All measurements were carried out in near-neutral pH buffered solution (pH=6.5, 0.5 M Na2SO4 buffered with 0.25 M Na2HPO4 and 0.25 M NaH2PO4).
Structural analysis of Sb2Se3 thin films Before the evaluation of PEC performance of Sb2Se3-based photocathodes with Sb2Se3 annealed in the presence of Se vapor, structural properties of the Ar-annealed Sb2Se3 thin films were studied. As shown in Figure 3a, the X-Ray diffraction (XRD) patterns of as-deposited Sb2Se3 thin films did not show distinct diffraction peaks except for the peak associated with the Mo substrate, suggesting the as-deposited Sb2Se3 thin films were amorphous. All of the 8
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annealed samples showed strong diffraction patterns corresponding to the orthorhombic Sb2Se3 (PDF No. 15-0861), indicating thermal annealing is a requisite for the transition from amorphous to polycrystalline. In addition, all of the annealed Sb2Se3 samples exhibited desirable orientations for (211) and (221) planes rather than the undesirable (120) plane.47 The Raman spectra of all Sb2Se3 samples (Figure 3b) exhibited two peaks centered at around 189 and 252 cm−1, corresponding to the characteristic Sb−Se and Sb−Sb vibrations of Sb2Se3,55 respectively, which further confirmed the presence of desired Sb2Se3 phase. Figure 3c shows a typical energy-dispersive X-ray spectrum (EDX) of the 400oCannealed Sb2Se3, in which the average atomic ratio (over five random areas) of Se/Sb was measured to be 58.6/41.4, implying a significant deficiency of Se. The direct optical bandgap of 400oC-annealed Sb2Se3 was determined to be ca. 1.16 eV from optical transmittance results (Figure 3d). The Se/Sb ratio and optical bandgap of Sb2Se3 as a function of annealing temperature are plotted in Figure 3e (the corresponding data are shown in Table S1 and Figure S2, Supporting Information). It turned out that all of the annealed Sb2Se3 samples had relatively lower Se/Sb ratios compared with the as-deposited one, suggesting a partial loss of Se during the annealing process. The determined optical bandgap values revealed that all of the annealed Sb2Se3 samples had a bandgap value of around 1.2−1.1 eV, much lower than that of the sample without annealing (ca. 1.4 eV). The SEM images of annealed Sb2Se3 (Figure 3f−h for 300−400oC, Figure 1h for 450oC, and Figure S3 in Supporting Information for additional low-magnification SEM images) showed a gradual grain growth with increasing annealing temperature. Apparently, more uniform and large grains were obtained for the sample with the annealing temperature of 400oC, indicating only moderate annealing temperature is suitable to achieve micrometer-sized grains for Sb2Se3 polycrystalline thin films. It should be noted that a significant re-evaporation would be observed if the annealing temperature exceeds 500oC (not shown here) because of the low melting point of Sb2Se3. 9
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(b)
(a)
(e)
(d)
(c)
(g) 350oC
(f) 300oC
(h) 400oC
1 m
1 m
1 m
Figure 3. (a, b) XRD patterns and Raman spectra of Sb2Se3 annealed at different temperatures. (c, d) EDX spectrum and Tauc plot of 400oC-annealed Sb2Se3. Inset corresponds to the transmittance spectrum. (e) Plots of Se/Sb ratio and bandgap values of Sb2Se3 as a function of the annealing temperature. (f−h) SEM images of Sb2Se3 annealed at 300, 350, and 400oC under Ar atmosphere.
Based on these results, we speculated the observed significant deficiency of Se might reduce the PEC performance of Ar-annealed Sb2Se3 electrodes because significant deficiency of Se could lead to the formation of a large amount of Se vacancies, which could in principle act as n-type donors (reducing the p-type conductivity of photoabsorbers) and recombination centers (trapping the photogenerated carriers) to deteriorate the device performance as previously encountered in the Ar-annealed Sb2Se3 thin-film solar cells.64 Annealing in the 10
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presence of selenium (or sulfur) vapor was demonstrated to be an effective strategy to reduce the Se (or S) vacancies and improve the solar conversion efficiency of Sb2Se3 (or SnS) thinfilm solar cells.64,65 Since a significant Se deficiency was observed for Ar-annealed Sb2Se3 in this work, an additional Se was introduced into Sb2Se3 through annealing in the presence of Se vapor, which led to an obvious improvement of device performance, as demonstrated below.
Enhanced PEC performance of Sb2Se3 through Se-annealing and TiO2-coating: structural properties The Sb2Se3 sample annealed at 400oC under Se vapor is abbreviated as Sb2Se3(Se). The obtained Sb2Se3(Se) adhered firmly to the SLG/Mo substrate and was homogeneous over large scale (Figure 4a) with a surface color similar to that of Ar-annealed Sb2Se3 (Figure 1d). The contact between Mo and Sb2Se3(Se) thin film was measured to be ohmic (Figure S4, Supporting Information). The XRD pattern and Raman spectrum of Sb2Se3(Se) confirmed the high purity of Sb2Se3 phase (Figure S5, Supporting Information). The bandgap of Sb2Se3(Se) was determined to be ca. 1.15 eV (Figure S6, Supporting Information), which is similar to that of Ar-annealed Sb2Se3 at 400oC. As shown in Figure 4b (and Figure S7 in Supporting Information for additional low-magnification SEM images), the SEM image of Sb2Se3(Se) exhibited large rod-shaped grains packed randomly and densely to form the polycrystalline thin film. The grain size of Sb2Se3(Se) was larger than that of Ar-annealed Sb2Se3 at 400oC(Figure 3h), suggesting that the treatment with Se vapor during annealing promotes the grain growth. It is worth noting that directly annealing of the metallic Sb thin films under same Se vapor failed to obtain highpurity Sb2Se3 polycrystalline thin films in large scale (Figure S8, Supporting Information), indicating annealing of as-deposited Sb2Se3 in the presence of Se vapor is much easier than direct selenization of metallic Sb to form high-quality Sb2Se3 polycrystalline thin films. The average atomic composition (over five random areas) of Se/Sb was determined by EDX to be 59.7/40.3, which was very close to the 3/2 stoichiometry and thus implied a higher composition 11
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of Se for Sb2Se3(Se) than that of Ar-annealed Sb2Se3 (58.6/41.4) at the same temperature. As shown in Figure 4c, the high-resolution transmission electron microscopy (HRTEM) image of Sb2Se3(Se) and selected area electron diffraction (SAED) pattern indicated Sb2Se3(Se) films had a good crystalline quality, in which the measured interplanar distances of 2.521 Å and 2.753 Å corresponded to the (321) and (3-30) planes of the orthorhombic Sb2Se3 (PDF No. 150861), respectively. The STEM-EDX elemental mappings of Sb and Se (Figure 4d) exhibited a homogeneous distribution, further confirmed the superb crystal quality of Sb2Se3(Se). The surface of obtained Sb2Se3(Se) was then modified by CdS and further coated by atomic layer deposition (ALD) of TiO2. The top and cross-sectional SEM images of the resulting Sb2Se3(Se)/CdS/TiO2 sample (Figure 4e and f) indicated that the large columnargrained Sb2Se3(Se) underlayer was conformally coated by CdS (ca. 80 nm) and TiO2 (ca. 15 nm) overlayers. As shown in Figures 4g and h, the typical auger electron spectrum (AES) and corresponding elemental mappings of Ti and O further confirmed a complete coverage of TiO2 on the surface of Sb2Se3(Se)/CdS. The Sb2Se3(Se)/CdS/TiO2 sample was further studied by the time of flight secondary ion mass spectroscopy (TOF-SIMS) as shown in Figure 4i, which further corroborated the presence of well-defined multilayer structure consisting of Sb2Se3(Se)/CdS/TiO2 on the Mo substrate.
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(a) Sb2Se 3(Se)
(c)
(b) Se/Sb = 59.7/40.3
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(3-30) (321)
(d) 1 m Sb
1 m
2 nm
Se
Sb Se
(e) Sb2Se3(Se)/CdS/TiO2 (f)
TiO2 1 m (g)
CdS 100 nm
500 nm (h)
Ti
O (i)
1 m
Figure 4. (a) Optical image of Sb2Se3(Se). (b) SEM image of Sb2Se3(Se). (c) HRTEM image of Sb2Se3(Se). Inset is the SAED pattern. (d) STEM image of Sb2Se3(Se) and the corresponding elemental mappings of Sb and Se. (e, f) Top and cross-sectional SEM images of Sb2Se3(Se)/CdS/TiO2 sample. (g, h) Typical AES spectrum and the corresponding elemental mappings of Ti and O on the surface of Sb2Se3(Se)/CdS/TiO2 sample. (i) SIMS depth profile of Sb2Se3(Se)/CdS/TiO2 sample.
Enhanced PEC performance of Sb2Se3 through Se-annealing and TiO2-coating: PEC properties As shown in Figure 5a, the Sb2Se3(Se)/CdS/Pt electrode exhibited a photocurrent density of ca. −6.2 mA cm−2 at 0 VRHE and an onset potential of ca. 0.40 VRHE, which was a significant enhancement compared with the Ar-annealed Sb2Se3/CdS/Pt (−2.3 mA cm−2 at 0 VRHE, onset potential of 0.35 VRHE). In addition, the Sb2Se3(Se)/Pt electrode also exhibited an enhanced PEC performance compared with Sb2Se3/Pt (Figure S9, Supporting Information). Therefore, it is evident that annealing of Sb2Se3 in the presence of Se vapor could effectively improve the
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PEC performance of Sb2Se3. The Mott-Schottky plots (Figure 5b, details are presented in Supporting Information) reveal that the Sb2Se3(Se) had a significantly higher acceptor density (NA, 4.71016 cm−3) than that of Ar-annealed Sb2Se3 (4.21015 cm−3), accompanied by a slightly more positive flat-band potential (Efb, shifted to 0.59 from 0.47 VRHE). The increased acceptor density of Sb2Se3(Se) sample is likely attributed to the effective reduction of donor-like Se vacancies resulting from the additional Se incorporation during annealing under the Se vapor.64 Thus, the observed enhanced PEC performance of Sb2Se3(Se)-based electrodes might benefit from the successful passivation of Se vacancies. After further modification by inserting TiO2 between CdS and Pt, the resulting Sb2Se3(Se)/CdS/TiO2/Pt exhibited an obvious PEC enhancement (Figure 5c), showing a cathodic photocurrent density of ca. −8.6 mA cm−2 at 0 VRHE, an onset potential of ca. 0.43 VRHE, and a half-cell solar-to-hydrogen efficiency (HC-STH) of ca. 0.68% at ca. 0.2 VRHE in near-neutral pH buffered solution (pH 6.5) under AM 1.5G simulated sunlight. The average PEC performance of Sb2Se3(Se)/CdS/TiO2/Pt (over five samples) was ca. −8.8 mA cm−2 at 0 VRHE with onset potential of ca. 0.41 VRHE (Figure S10, Supporting Information). It should be noted that the deposited Pt was nanoparticles with particle size of ca. 40 nm (Figure S11, Supporting Information). Furthermore, the Sb2Se3(Se)/CdS/TiO2/Pt photocathode (Figure 5d) demonstrated a stable photocurrent for over 10 h (ca. 85% of initial photocurrent remained), which displayed a dramatically improved stability compared with Sb2Se3(Se)/CdS/Pt (Inset of Figure 5a, where ca. 50% of initial photocurrent remained after only 1 h). This result suggested that the highly efficient PEC performance could be achieved through the modification of CdS/TiO2 bilayer. In addition, the gas products produced in a time course of photocurrent measurement (Figure S12, Supporting Information) were quantified by gas chromatography (GC). As shown in Figure 5e, the Faradaic efficiencies of hydrogen evolved from Sb2Se3(Se)/CdS/TiO2/Pt photocathode and oxygen evolved from the counter electrode were
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approximately 100%, indicating the observed stable photocurrent is indeed originated from the hydrogen evolution via water splitting.
Figure 5. (a) Current-potential curves of Sb2Se3(Se)/CdS/Pt and Sb2Se3/CdS/Pt electrodes under AM 1.5G simulated sunlight. Inset corresponds to current-time curve of Sb2Se3(Se)/CdS/Pt at 0 VRHE. (b) Mott-Schottky plots of Sb2Se3(Se) and Sb2Se3. (c, d) Currentpotential and current-time curves of Sb2Se3(Se)/CdS/TiO2/Pt electrode under AM 1.5G simulated
sunlight.
Inset
corresponds
to
the
HC-STH.
(e)
GC
analysis
of
Sb2Se3(Se)/CdS/TiO2/Pt at 0 VRHE under 300 Xe lamp (ca. 350-780 nm). (f) IPCEs of Sb2Se3(Se)/CdS/TiO2/Pt
electrode
at
0 VRHE.
(g)
Schematic
band
alignment
of
Sb2Se3(Se)/CdS/TiO2 heterojunction. (h) PEC performance of state-of-the-art photocathodes made of emerging binary photoabsorbers. All electrochemical measurements were carried out in near-neutral pH buffered solution (pH=6.5, 0.5 M Na2SO4 buffered with 0.25 M Na2HPO4 and 0.25 M NaH2PO4). 15
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Figure 5f displays the wavelength dependence of incident photon-to-current conversion efficiencies (IPCEs) for the Sb2Se3(Se)/CdS/TiO2/Pt sample measured at 0 VRHE. The IPCEs of Sb2Se3(Se)/CdS/TiO2/Pt reached ca. 20−30% in the 440−800 nm range. It started to decrease gradually to nearly zero at ca. 1040 nm, a wavelength close to the expected spectral response of Sb2Se3(Se) according to the determined bandgap ca. 1.2 eV. A photocurrent density of ca. 8.3 mA cm−2 was then evaluated by integrating the measured IPCEs of Sb2Se3(Se)/CdS/TiO2/Pt over the spectrum of simulated sunlight. As a result, the integrated photocurrent density correlated very well with the observed photocurrent density of 8.6 mA cm−2 at 0 VRHE. Notably, a theoretical maximum photocurrent density of ca. 40 mA cm−2 was calculated (Figure S13, Supporting Information), indicating that there is still ample space for further improvement. To elucidate the dramatically enhanced PEC performance caused by CdS/TiO2 bilayer modification, we calculated the band alignment of Sb2Se3(Se)/CdS/TiO2/Pt photocathode. As shown in Figure 5g, the valence band offset (VBO) of Sb2Se3(Se)/CdS interface was measured by X-ray photoelectron spectroscopy (XPS) to be a cliff of 1.02 eV (the details are described in Supporting Information and Figure S14). In contrast, the reported cliff VBO of 1.1 eV was used for CdS/TiO2 interface.66 According to these two VBO values and the determined bandgap values of Sb2Se3(Se) (1.15 eV), CdS (2.42 eV, Figure S15) and TiO2 (3.32 eV, Figure S16), the conduction band offset (CBO) of Sb2Se3(Se)/CdS and CdS/TiO2 interfaces were determined to be a spike of 0.25 eV and a cliff of 0.2 eV, respectively. The resulting band alignment of Sb2Se3(Se)/CdS/TiO2 heterojunction exhibited a large cliff-like VBO (sequentially formed by CdS and TiO2) and a little spike-like CBO at Sb2Se3(Se)/CdS interface. In such a scenario, the formed large cliff-like VBO creates a desirable energy barrier that effectively prevents the transfer of photo-generated holes in the valence band of Sb2Se3(Se) towards the electrode-liquid interface for recombination. As a result, more photo-generated holes move to the back contact and later to the counter electrode through an external circuit for oxygen evolution. Meanwhile, 16
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the formed little spike-like CBO (0.25 eV) at Sb2Se3(Se)/CdS interface, which is within the optimal value of a high quality p-n heterojunction (between a cliff of ca. 0.2 eV and a spike of 0.4 eV),67,68 could allow the selective transfer of photo-generated electrons in the conduction band of Sb2Se3(Se) to reach electrode-liquid interface through the CdS/TiO2 bilayer for hydrogen evolution with the assistance of Pt catalyst. In addition to form a p-n heterojunction with desirable band alignment to promote charge separation and collection, the CdS/TiO2 bilayer provides a stable surface because of the anti-photocorrosive nature of TiO2 overlayer.69 As plotted in Figure 5h, the PEC performance of surface-modified Se-annealed Sb2Se3 polycrystalline thin-film photocathode in this report (−8.6 mA cm−2 at 0 VRHE, 0.43 VRHE, 85% of photocurrent remained after 10 h) was higher than that of previously reported Sb2Se3/TiO2/Pt nanoneedle photocathode (−2 mA cm−2 at 0 VRHE, 0.4 VRHE, 5% remained after 3 h).57 Furthermore, the PEC performance is comparable to the state-of-the-art photocathodes based on the emerging binary photoabsorbers, including Cu2O,36−39 CuO,59 WSe2,60 and ZnTe,70 as illustrated in Table S2. Although the present PEC performance of Sb2Se3-based photocathode is still lower than those well-studied binary photocathodes based on the commercial materials such as InP71 and CdTe,72 further improvement of Sb2Se3-based photocathode for cost-effective PEC devices is highly promising because of its high theoretical efficiency (i.e., 30%) and capability for facile fabrication at large-scale using inexpensive and non-toxic elements.
Conclusions In conclusion, we have developed a highly efficient low-bandgap Sb2Se3 polycrystalline thinfilm photocathode for durable hydrogen evolution with a significant photoresponse up to nearinfrared region (ca. 1040 nm). Sb2Se3 polycrystalline thin films with micrometer-sized grains were fabricated in large scale by using thermal evaporation of single Sb2Se3 powder source onto the Mo-coated SLG substrates followed by moderate annealing (400oC) under Ar or Se+Ar atmosphere. The PEC performance of Sb2Se3 polycrystalline thin-film electrodes was 17
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dramatically enhanced by the construction of p-n heterojunction with anti-photocorrosive CdS/TiO2 bilayer and surface decoration with Pt catalyst. The Se-annealed Sb2Se3(Se) electrodes with surface modification showed a significantly enhanced PEC performance compared with the Ar-annealed analogs likely because of the reduced recombination by Se vacancies. Benefited from the desirable large grains of Sb2Se3(Se) and anti-photocorrosive p-n heterojunction, the fabricated Sb2Se3(Se)/CdS/TiO2/Pt electrode achieved a cathodic photocurrent density of ca. −8.6 mA cm−2 at 0 VRHE with a photocurrent onset of ca. 0.43 VRHE and a stable photocurrent for over 10 h in neutral electrolyte under simulated sunlight. This PEC performance is close to the state-of-the-art thin-film photocathodes made of other earthabundant binary photoabsorbers, such as Cu2O, CuO, and WSe2. Overall, the results of this study demonstrate that Sb2Se3-based electrode could be utilized as a promising low-bandgap photocathode for constructing standalone dual-electrode cells for cost-effective visible-nearinfrared solar hydrogen production in large scale, although a further improvement in the photocurrent density and onset potential through additional interfacial engineering and careful optimization (including the thickness and post-treatment) are required.
Experimental Section Thermal deposition of Sb2Se3 thin films. Sb2Se3 thin films were deposited by facile thermal evaporation of single Sb2Se3 (99.99%) powder source onto the Mo-coated soda-lime glass substrates at a base pressure of around 10−4 Pa. The Sb2Se3 powder source was loaded into a molybdenum boat that positioned around 20 cm away from the sample holder. The deposition rate was kept at approximately 2 nm s−1 and deposition thickness was fixed at 1.5 m monitored using a microcrystalline quartz balance. No intentional heating of the Mo substrates was applied during the deposition. The as-deposited Sb2Se3 thin films were then annealed in a horizontal quartz tube furnace at different temperature (300−450oC) for 1 h under a flowing Ar atmosphere (500 sccm), followed by cooling down to room temperature naturally. Some of the as-deposited 18
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Sb2Se3 thin films were annealed (400oC, 1 h) under Se+Ar atmosphere with Ar (500 sccm) as the carrier gas. The Se vapor was introduced by placing the excess amount of Se (99.99%, loaded in a quartz boat) at the furnace upstream (around 30 cm away from the samples) and kept around 330oC during the annealing process. Chemical bath deposition (CBD) of CdS. Prior to CBD process, the surface of the sample was pretreated in a bath solution of 0.01 M Cd(CH3COO)2·2H2O (98%, Alfa Aesar) and 5 M NH4OH (Alfa Aesar, 28 wt.%) at around 65oC for 15 min. The CBD of CdS was performed by immersing the pretreated sample into a bath solution containing 0.01 M Cd(CH3COO)2, 0.5 M SC(NH2)2 (99%, Alfa Aesar) and 5 M NH4OH for 10 min, during which the bath temperature gradually increased from room temperature to around 65oC. After CdS deposition, the sample was rinsed immediately by deionized water, and then annealed at 200oC for 1 h under an air atmosphere. Atomic layer deposition (ALD) of TiO2. ALD of TiO2 was performed at 150oC using a Beneq TFS-200 system and employing titanium tetrachloride TiCl4 and H2O as the Ti and O precursors, respectively. Each ALD cycle consisted of a 0.5 s pulse of TiCl4 and a 0.5 s pulse of H2O. A 5 s purging of N2 was performed between each precursor pulse to remove extra precursor materials. These conditions exhibited a growth rate per cycle (GPC) of around 0.5 Å, as measured on the Si witness sample. The depositing thickness of TiO2 was fixed at around 15 nm by controlling the cycle numbers. Photo-assisted electrodeposition of Pt. Prior to electrochemical measurements, the sample was fabricated into an electrode by soldering a lead wire onto the Mo back contact and sealing the needless parts with epoxy. The photo-assisted electrodeposition of Pt was controlled by a CHI660D electrochemical workstation under a 3-electrode configuration. A specimen, a Pt wire and an Ag/AgCl electrode (saturated with aqueous KCl solution) were employed as the working, counter, and reference electrodes, respectively. The measured potential (VAg/AgCl) was converted to the reversible hydrogen electrode potential (VRHE) according to the Nernst 19
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equation (VRHE=VAg/AgCl + 0.059 pH + 0.197). The deposition of Pt was performed in a solution containing 0.1 mM H2PtCl6·6H2O (99.9% metals basis, Alfa Aesar), 0.5 M Na2SO4 (99%, Alfa Aesar), 0.25 M Na2HPO4 (99+%, Acros), and 0.25 M NaH2PO4 (99%, Acros) with pH at 6.5 measured by a pH meter (FE-20K, Mettler Toledo). Each deposition was performed at a fixed potential of 0 VRHE under illumination (ca. 350−780 nm light, 300 W Xe lamp) with magnetic stirring and Ar purging. The deposition was kept until the saturation of cathodic photocurrent. Photoelectrochemical measurements. The PEC measurements were carried out using 3electrode cell configuration (a Pt wire as the count electrode, an Ag/AgCl electrode as the reference electrode) in near-neutral pH buffered solution (pH 6.5, containing 0.5 M Na2SO4, 0.25 M Na2HPO4 and 0.25 M NaH2PO4) with magnetic stirring and Ar purging. A commercial AM 1.5G solar simulator (92250A-1000, Newport Oriel) was employed as the simulated sunlight. A standard Si solar cell (P/N 91150V, Newport Oriel) and a spectroradiometer (LS100, EKO instruments) were applied to calibrate the solar simulator. The Mott–Schottky measurements were carried out using a 10 mV AC voltage signal at a frequency of 2 kHz. A gas chromatography (GC 2014, Shimadzu) was employed for gas products analysis. A monochromator equipped with a 1000 W Xe lamp and a calibrated Si photodiode (FDS100CAL, Thorlabs) were used to measure the incident-photon-to-current-conversion efficiency (IPCE). Structural characterization. The samples were characterized by scanning electron microscopy (SEM; MERLIN VP Compact, Carl Zeiss) attached with energy dispersive X-ray spectroscopy (EDX), X-ray diffraction (XRD; Smartlab, Rigaku), Raman spectroscopy (LabRAM HR Evolution, Horiba) under 532 nm excitation, transmittance spectroscopy (Cary 5000 UV-vis-NIR, Agilent Technologies), X-ray photoelectron spectroscopy (XPS; Escalab 250Xi, Thermo Scientific), Auger electron spectroscopy (AES; PHI-710, ULVAC-PHI), transmission electron microscopy (TEM; JEM-2010, JEOL), and time of flight secondary ion mass spectroscopy (TOF-SIMS, TOF.SIMS 5-100, ION-TOF GmbH) with Cs+ beam for the 20
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depth sputtering (2 keV, 350×350 μm2) and Bi+ beam for the analysis (30 keV, 80×80 μm2). For TOF-SIMS measurements, the intensities of the MCs+ clusters were analyzed, where M denotes the matrix components of the multi-layered sample.
ASSOCIATED CONTENT *Address correspondence to
[email protected]. Supporting Information. Supporting Information is available free of charge on the ACS Publications website at DOI: 10.1021/xxxx. Additional experimental images (Figures S1−S16) and tables (Table S1, S2), as well as the detailed experimental methods (PDF) The authors declare no competing financial interest.
ACKNOWLEDGMENT This work was supported by the National Science Foundation of China (51372133), and the China Postdoctoral Science Foundation (2015M571019 and 2016M600083). This work made use of the resources of the Beijing National Center for Electron Microscopy at Tsinghua University.
References 1. Lewis, N. S.; Nocera, D. G. Powering the Planet: Chemical Challenges in Solar Energy Utilization. Proc. Natl. Acad. Sci. U.S.A. 2006, 103, 15729–15735. 2. Lewis, N. S. Research Opportunities to Advance Solar Energy Utilization. Science 2016, 351, 1920. 3. Chen, S.; Takata, T.; Domen, K. Particulate Photocatalysts for Overall Water Splitting. Nat. Rev. Mater. 2017, 2, 17050.
21
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Page 23 of 29 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60
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4. Wang, Y.; Kong, B.; Zhao, D.; Wang, H.; Selomulya, C. Strategies for Developing Transition Metal Phosphides as Heterogeneous Electrocatalysts for Water Splitting. Nano Today, 2017, 15, 26–55. 5. Kong, D.; Wang, H.; Lu, Z.; Cui, Y. CoSe2 Nanoparticles Grown on Carbon Fiber Paper: An Efficient and Stable Electrocatalyst for Hydrogen Evolution Reaction. J. Am. Chem. Soc. 2014, 136, 4897–4900. 6. Walter, M. G.; Warren, E. L.; McKone, J. R.; Boettcher, S. W.; Mi, Q.; Santori, E. A.; Lewis, N. S. Solar Water Splitting Cells. Chem. Rev. 2010, 110, 6446–6473. 7. Osterloh, F. E. Inorganic Nanostructures for Photoelectrochemical and Photocatalytic Water Splitting. Chem. Soc. Rev. 2013, 42, 2294–2320. 8. Sivula, K.; van de Krol, R. Semiconducting Materials for Photoelectrochemical Energy Conversion. Nat. Rev. Mater. 2016, 1, 15010. 9. Ding, Q.; Song, B.; Xu, P.; Jin, S. Efficient Electrocatalytic and Photoelectrochemical Hydrogen Generation Using MoS2 and Related Compounds. Chem 2016, 1, 699–726. 10. Ager, J. W.; Shaner, M. R.; Walczak, K. A.; Sharp, I. D.; Ardo, S. Experimental Demonstrations of Spontaneous, Solar-Driven Photoelectrochemical Water Splitting. Energy Environ. Sci. 2015, 8, 2811–2824. 11. Hu, S.; Xiang, C.; Haussener, S.; Berger, A. D.; Lewis, N. S. An Analysis of the Optimal Band Gaps of Light Absorbers in Integrated Tandem Photoelectrochemical Water-Splitting Systems. Energy Environ. Sci. 2013, 6, 2984–2993. 12. Fountaine, K. T.; Lewerenz, H. J.; Atwater, H. A. Efficiency Limits for Photoelectrochemical Water-Splitting. Nat Commun. 2016, 7, 13706. 13. Kim, T. W.; Choi, K. S. Nanoporous BiVO4 Photoanodes with Dual-Layer Oxygen Evolution Catalysts for Solar Water Splitting. Science 2014, 343, 990–994. 14. Kuang, Y.; Jia, Q.; Ma, G.; Hisatomi, T.; Minegishi, T.; Nishiyama, H.; Nakabayashi, M.; Shibata, N.; Yamada, T.; Kudo, A.; Domen, K. Ultrastable Low-Bias Water Splitting Photoanodes via Photocorrosion Inhibition and in situ Catalyst Regeneration. Nat. Energy 2016, 2, 16191. 15. Kment, S.; Riboni, F.; Pausova, S.; Wang, L.; Wang, L.; Han, H.; Hubicka, Z.; Krysa, J.; Schmuki, P.; Zboril, R. Photoanodes Based on TiO2 and α-Fe2O3 for Solar Water Splitting – Superior Role of 1D Nanoarchitectures and of Combined Heterostructures. Chem. Soc. Rev. 2017, 46, 3716–3769.
22
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16. Kim, J. Y.; Jang, J.-W.; Youn, D. H.; Magesh, G.; Lee, J. S. A Stable and Efficient Hematite Photoanode in a Neutral Electrolyte for Solar Water Splitting: Towards Stability Engineering. Adv. Energy Mater. 2014, 4, 1400476. 17. Guan, J.; Ding, C.; Chen, R.; Huang, B.; Zhang, X.; Fan, F.; Zhang, F.; Li, C. CoOx Nanoparticle Anchored on Sulfonated-Graphite As Efficient Water Oxidation Catalyst. Chem. Sci. 2017, 8, 6111–6116. 18. Wang, G.; Wang, H.; Ling, Y.; Tang, Y.; Yang, X.; Fitzmorris, R. C.; Wang, C.; Zhang, J. Z.; Li, Y. Hydrogen-Treated TiO2 Nanowire Arrays for Photoelectrochemical Water Splitting. Nano Lett. 2011, 11, 3026–3033. 19. Zhang, K.; Ravishankar, S.; Ma, M.; Veerappan, G.; Bisquert, J.; Fabregat-Santiago, F.; Park, J. H. Overcoming Charge Collection Limitation at Solid/Liquid Interface by a Controllable Crystal Deficient Overlayer. Adv. Energy. Mater. 2017, 7, 1600923. 20. Cai, L.; Zhao, J.; Li, H.; Park, J.; Cho, I. S.; Han, H. S.; Zheng, X. One-Step Hydrothermal Deposition of Ni:FeOOH onto Photoanodes for Enhanced Water Oxidation. ACS Energy Lett. 2016, 1, 624–632. 21. Ma, M.; Zhang, K.; Li, P.; Jung, M. S.; Jeong, M. J.; Park, J. H. Dual Oxygen and Tungsten Vacancies on a WO3 Photoanode for Enhanced Water Oxidation. Angew. Chem. Int. Ed. 2016, 55, 11819–11823. 22. Minegishi, T.; Nishimura, N.; Kubota, J.; Domen, K. Photoelectrochemical Properties of LaTiO2N Electrodes Prepared by Particle Transfer for Sunlight-Driven Water Splitting. Chem. Sci. 2013, 4, 1120–1124. 23. Ueda, K.; Minegishi, T.; Clune, J.; Nakabayashi, M.; Hisatomi, T.; Nishiyama, H.; Katayama, M.; Shibata, N.; Kubota, J.; Yamada, T.; Domen, K. Photoelectrochemical Oxidation of Water Using BaTaO2N Photoanodes Prepared by Particle Transfer Method. J. Am. Chem. Soc. 2015, 137, 2227–2230. 24. Seo, J.; Moriya, Y.; Kodera, M.; Hisatomi, T.; Minegishi, T.; Katayama, M.; Domen. K. Photoelectrochemical Water Splitting on Particulate ANbO2N (A = Ba, Sr) Photoanodes Prepared from Perovskite-Type ANbO3. Chem. Mater. 2016, 28, 6869–6876. 25. Li, Y.; Zhang, L.; Torres-Pardo, A.; González-Calbet, J. M.; Ma, Y.; Oleynikov, P.; Terasaki, O.; Asahina, S.; Shima, M.; Cha, D.; Zhao, L.; Takanabe, K.; Kubota, J.; Domen, K. Cobalt Phosphate-Modified Barium-Doped Tantalum Nitride Nanorod Photoanode with 1.5% Solar Energy Conversion Efficiency. Nat. Commun. 2013, 4, 2566. 26. He, Y.; Thorne, J. E.; Wu, C. H.; Ma, P.; Du, C.; Dong, Q.; Guo, J.; Wang, D. What Limits the Performance of Ta3N5 for Solar Water Splitting? Chem 2016, 1, 640–655. 23
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27. Zhong, M.; Hisatomi, T.; Sasaki, Y.; Suzuki, S.; Teshima, K.; Nakabayashi, M.; Shibata, N.; Nishiyama, H.; Katayama, M.; Yamada, T.; Domen, K. Highly Active GaN-Stabilized Ta3N5 Thin-Film Photoanode for Solar Water Oxidation. Angew. Chem. Int. Ed. 2017, 56, 4739–4743. 28. Britto, R. J.; Benck, J. D.; Young, J. L.; Hahn, C.; Deutsch, T. G.; Jaramillo, T. F. Molybdenum Disulfide As a Protection Layer and Catalyst for Gallium Indium Phosphide Solar Water Splitting Photocathodes. J. Phys. Chem. Lett. 2016, 7, 2044–2049. 29. Gu, J.; Aguiar, J. A.; Ferrere, S.; Steirer, K. X.; Yan, Y.; Xiao, C.; Young, J. L.; Al-Jassim, M.; Neale, N. R.; Turner, J. A. A Graded Catalytic–Protective Layer for an Efficient and Stable Water-Splitting Photocathode. Nat. Energy 2017, 2, 16192. 30. Moriya, M.; Minegishi, T.; Kumagai, H.; Katayama, M.; Kubota, J.; Domen, K. Stable Hydrogen Evolution from CdS-Modified CuGaSe2 Photoelectrode under Visible-Light Irradiation. J. Am. Chem. Soc. 2013, 135, 3733–3735. 31. Zhang, L.; Minegishi, T.; Nakabayashi, M.; Suzuki, Y.; Seki, K.; Shibata, N.; Kubota, J.; Domen, K. Durable Hydrogen Evolution from Water Driven by Sunlight Using (Ag,Cu)GaSe2 Photocathodes Modified with CdS and CuGa3Se5. Chem. Sci. 2015, 6, 894–901. 32. Zhao, J.; Minegishi, T.; Zhang, L.; Zhong, M.; Gunawan; Nakabayashi, M.; Ma, G.; Hisatomi, T.; Katayama, M.; Ikeda, S.; Shibata, N.; Yamada, T.; Domen, K. Enhancement of Solar Hydrogen Evolution from Water by Surface Modification with CdS and TiO 2 on Porous CuInS2 Photocathodes Prepared by an Electrodeposition–Sulfurization Method. Angew. Chem. Int. Ed. 2014, 53, 11808–11812. 33. Guijarro, N.; Prévot, M. S.; Yu, X.; Jeanbourquin, X. A.; Bornoz, P.; Bourée, W.; Johnson, M.; Le Formal, F.; Sivula, K. A Bottom-Up Approach toward All-Solution-Processed HighEfficiency Cu(In,Ga)S2 Photocathodes for Solar Water Splitting. Adv. Energy Mater. 2016, 6, 1501949. 34. Yang, W.; Oh, Y.; Kim, J.; Jeong, M. J.; Park, J. H.; Moon, J. Molecular ChemistryControlled Hybrid Ink-Derived Efficient Cu2ZnSnS4 Photocathodes for Photoelectrochemical Water Splitting. ACS Energy Lett. 2016, 1, 1127–1136. 35. Ge, J.; Yu, Y.; Yan, Y. Earth-Abundant Orthorhombic BaCu2Sn(SexS1-x)4 (x ≈ 0.83) Thin Film for Solar Energy Conversion. ACS Energy Lett. 2016, 1, 583–588. 36. Paracchino, A.; Laporte, V.; Sivula, K.; Grätzel, M.; Thimsen, E. Highly Active Oxide Photocathode for Photoelectrochemical Water Reduction. Nat. Mater. 2011, 10, 456–461.
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37. Tilley, S. D.; Schreier, M.; Azevedo, J.; Stefik, M.; Graetzel, M. Ruthenium Oxide Hydrogen Evolution Catalysis on Composite Cuprous Oxide Water-Splitting Photocathodes. Adv. Funct. Mater. 2014, 24, 303–311. 38. Li, C.; Hisatomi, T.; Watanabe, O.; Nakabayashi, M.; Shibata, N.; Domen, K.; Delaunay, J.-J. Positive Onset Potential and Stability of Cu2O-Based Photocathodes in Water Splitting by Atomic Layer Deposition of a Ga2O3 Buffer Layer. Energy Environ. Sci. 2015, 8, 1493–1500. 39. Son, M.-K.; Steier, L.; Schreier, M.; Mayer, M. T.; Luo, J.; Grätzel, M. A Copper Nickel Mixed Oxide Hole Selective Layer for Au-Free Transparent Cuprous Oxide Photocathodes. Energy Environ. Sci. 2017, 10, 912–918. 40. Zhou, X.; Liu, R.; Sun, K.; Papadantonakis, K. M.; Brunschwig, B. S.; Lewis, N. S. 570 mV Photovoltage, Stabilized n-Si/CoOx Heterojunction Photoanodes Fabricated Using Atomic Layer Deposition. Energy Environ. Sci. 2016, 9, 892–897. 41. Yang, J.; Cooper, J. K.; Toma, F. M.; Walczak, K. A.; Favaro, M.; Beeman, J. W.; Hess, L. H.; Wang, C.; Zhu, C.; Gul, S.; Yano, J.; Kisielowski, C.; Schwartzberg, A.; Sharp, I. D. A Multifunctional Biphasic Water Splitting Catalyst Tailored for Integration with HighPerformance Semiconductor Photoanodes. Nat. Mater. 2017, 16, 335–341. 42. Seger, B.; Pedersen, T.; Laursen, A. B.; Vesborg, P. C. K.; Hansen, O.; Chorkendorff, I. Using TiO2 As a Conductive Protective Layer for Photocathodic H2 Evolution. J. Am. Chem. Soc. 2013, 135, 1057–1064. 43. Zhang, H.; Ding, Q.; He, D.; Liu, H.; Liu, W.; Li, Z.; Yang, B.; Zhang, X.; Lei, L.; Jin, S. A p-Si/NiCoSex Core/Shell Nanopillar Array Photocathode for Enhanced Photoelectrochemical Hydrogen Production. Energy Environ. Sci. 2016, 9, 3113–3119. 44. Chae, S. Y.; Park, S. J.; Han, S. G.; Jung, H.; Kim, C.-W.; Jeong, C.; Joo, O.-S.; Min, B. K.; Hwang, Y. J. Enhanced Photocurrents with ZnS Passivated Cu(In,Ga)(Se,S)2 Photocathodes Synthesized Using a Nonvacuum Process for Solar Water Splitting. J. Am. Chem. Soc. 2016, 138, 15673–15681. 45. Kaneko, H.; Minegishi, T.; Nakabayashi, M.; Shibata, N.; Domen, K. Enhanced Hydrogen Evolution
under
Simulated
Sunlight
from
Neutral
Electrolytes
on
(ZnSe)0.85(CuIn0.7Ga0.3Se2)0.15 Photocathodes Prepared by a Bilayer Method. Angew. Chem. Int. Ed. 2016, 55, 15329–15333. 46. Venkatasubramanian, R.; Siivola, E.; Colpitts, T.; O’Quinn, B. Thin-Film Thermoelectric Devices with High Room-Temperature Figures of Merit. Nature 2001, 413, 597–602.
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47. Zhou, Y.; Wang, L.; Chen, S.; Qin, S.; Liu, X.; Chen, J.; Xue, D.-J.; Luo, M.; Cao, Y.; Cheng, Y.; Sargent, E. H.; Tang, J. Thin-Film Sb2Se3 Photovoltaics with Oriented OneDimensional Ribbons and Benign Grain Boundaries. Nat. Photonics 2015, 9, 409–415. 48. Zeng, K.; Xue, D.-J.; Tang, J. Antimony Selenide Thin-Film Solar Cells. Semicond. Sci. Technol. 2016, 31, 063001. 49. Luo, W.; Calas, A.; Tang, C.; Li, F.; Zhou, L.; Mai, L. Ultralong Sb2Se3 Nanowire-Based Free-Standing Membrane Anode for Lithium/Sodium Ion Batteries. ACS Appl. Mater. Interfaces 2016, 8, 35219–35226. 50. Ghosh, G. The Sb-Se (Antimony-Selenium) System. J. Phase Equilib. 1993, 14, 753–763. 51. Siebentritt, S.; Igalson, M.; Persson, C.; Lany, S. The Eelectronic Structure of Chalcopyrites - Bands, Point Defects and Grain Boundaries. Prog. Photovoltaics 2010, 18, 390–410. 52. Chen, S.; Walsh, A.; Gong, X.-G.; Wei, S.-H. Classification of Lattice Defects in the Kesterite Cu2ZnSnS4 and Cu2ZnSnSe4 Earth-Abundant Solar Cell Absorbers. Adv. Mater. 2013, 25, 1522–1539. 53. Chu T. L.; Chu, S. S. Recent Progress in Thin-Film Cadmium Telluride Solar Cells. Prog. Photovoltaics 1993, 1, 31–42. 54. Major, J. D.; Treharne, R. E.; Phillips, L. J.; Durose, K. A Low-Cost Non-Toxic PostGrowth Activation Step for CdTe Solar Cells. Nature 2014, 511, 334–337. 55. Liu, X.; Chen, J.; Luo, M.; Leng, M.; Xia, Z.; Zhou, Y.; Qin, S.; Xue, D.-J.; Lv, L.; Huang, H.; Niu, D.; Tang, J. Thermal Evaporation and Characterization of Sb2Se3 Thin Film for Substrate Sb2Se3/CdS Solar Cells. ACS Appl. Mater. Interfaces 2014, 6, 10687–10695. 56. Polman, A.; Knight, M.; Garnett, E. C.; Ehrler, B.; Sinke, W. C. Photovoltaic Materials: Present Efficiencies and Future Challenges. Science 2016, 352, aad4424. 57. Kim, J.; Yang, W.; Oh, Y.; Lee, H.; Lee, S.; Shin, H.; Kim, J.; Moon, J. Self-Oriented Sb2Se3 Nanoneedle Photocathodes for Water Splitting Obtained by a Simple Spin-Coating Method. J. Mater. Chem. A 2017, 5, 2180–2187. 58. Kwon, Y. H.; Jeong, M.; Do, H. W.; Lee, J. Y.; Cho, H. K. Liquid-Solid Spinodal Decomposition Mediated Synthesis of Sb2Se3 Nanowires and Their Photoelectric Behavior. Nanoscale 2015, 7, 12913–12920. 59. Septina, W.; Prabhakar, R. R.; Wick, R.; Moehl, T.; Tilley, S. D. Stabilized Solar Hydrogen Production with CuO/CdS Heterojunction Thin Film Photocathodes. Chem. Mater. 2017, 29, 1735–1743. 60. Yu, X.; Prévot, M. S.; Guijarro, N.; Sivula, K. Self-Assembled 2D WSe2 Thin Films for Photoelectrochemical Hydrogen Production. Nat. Commun. 2015, 6, 7596. 26
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61. Jackson, P.; Hariskos, D.; Lotter, E.; Paetel, S.; Wuerz, R.; Menner, R.; Wischmann, W.; Powalla, M. New World Record Efficiency for Cu(In,Ga)Se2 Thin-film Solar Cells beyond 20%. Prog. Photovoltaics 2011, 19, 894–897. 62. Zhang, L.; Minegishi, T.; Kubota, J.; Domen, K. Hydrogen Evolution from Water Using AgxCu1-xGaSe2 Photocathodes under Visible Light. Phys. Chem. Chem. Phys. 2014, 16, 6167– 6174. 63. Zhang, L.; Li, Y.; Li, X.; Li, C.; Zhang, R.; Delaunay, J.-J.; Zhu, H. Solution-Processed CuSbS2 Thin Film: A Promising Earth-Abundant Photocathode for Efficient Visible-LightDriven Hydrogen Evolution. Nano Energy 2016, 28, 135–142. 64. Leng, M.; Luo, M.; Chen, C.; Qin, S.; Chen, J.; Zhong, J.; Tang, J. Selenization of Sb 2Se3 Absorber Layer: An Efficient Step to Improve Device Performance of CdS/Sb2Se3 Solar Cells. Appl. Phys. Lett. 2014, 105, 083905. 65. Sinsermsuksakul, P.; Sun, L.; Lee, S. W.; Park, H. H.; Kim, S. B.; Yang, C.; Gordon, R. G. Overcoming Efficiency Limitations of SnS-Based Solar Cells. Adv. Energy Mater. 2014, 4, 1400496. 66. Luo, J.; Ma, L.; He, T.; Ng, C. F.; Wang, S.; Sun, H.; Fan, H. J. TiO2/(CdS, CdSe, CdSeS) Nanorod Heterostructures and Photoelectrochemical Properties. J. Phys. Chem. C 2012, 116, 11956–11963. 67. Minemoto, T.; Matsui, T.; Takakura, H.; Hamakawa, Y.; Negami, T.; Hashimoto, Y.; Uenoyama, T.; Kitagawa, M. Theoretical Analysis of the Effect of Conduction Band Offset of Window/CIS Layers on Performance of CIS Solar Cells Using Device Simulation. Sol. Energy Mater. Sol. Cells 2001, 67, 83–88. 68. Minemoto, T.; Hashimoto, Y.; Satoh, T.; Negami, T.; Takakura, H.; Hamakawa, Y. Cu(In,Ga)Se2 Solar Cells with Controlled Conduction Band Offset of Window/Cu(In,Ga)Se2 Layers. J. Appl. Phys. 2001, 89, 8327–8330 69. Hu, S.; Lewis, N. S.; Ager, J. W.; Yang, J.; McKone, J. R.; Strandwitz, N. C. Thin-Film Materials for the Protection of Semiconducting Photoelectrodes in Solar-Fuel Generators. J. Phys. Chem. C 2015, 119, 24201–24228. 70. Jang, Y. J.; Lee, J.; Lee, J.; Lee, J. S. Solar Hydrogen Production from Zinc Telluride Photocathode Modified with Carbon and Molybdenum Sulfide. ACS Appl. Mater. Interfaces 2016, 8, 7748–7755. 71. Gao, L.; Cui, Y.; Vervuurt, R. H. J.; van Dam, D.; van Veldhoven, R. P. J.; Hofmann, J. P.; Bol, A. A.; Haverkort, J. E. M.; Notten, P. H. L.; Bakkers, E. P. A. M.; Hensen, E. J. M. High-
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ACS Nano
Efficiency InP-Based Photocathode for Hydrogen Production by Interface Energetics Design and Photon Management. Adv. Funct. Mater. 2016, 26, 679–686. 72. Su, J.; Minegishi, T.; Domen, K. Efficient Hydrogen Evolution from Water Using CdTe Photocathodes under Simulated Sunlight. J. Mater. Chem. A 2017, 5, 13154–13160.
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