TiO2 films have been widely applied in photovoltaic conversion techniques. TiO2 nanotube arrays (TiO2 NAs) can be grown directly on the surface of metal Ti by the anodic oxidation method. Bi2S3 and PbS nanoparticles (NPs) were firstly co-sensitized on TiO2 NAs (denoted as PbS/Bi2S3(n)/TiO2 NAs) by a two-step process containing hydrothermal and sonication-assisted SILAR method. When the concentration of Bi3+ is 5 mmol/L, the best photoelectrical performance was obtained under simulated solar irradiation. The short-circuit photocurrent (Jsc) and photoconversion efficiency (η) of PbS/Bi2S3(5)/TiO2 NAs electrode were 4.70 mA/cm and 1.13 %, respectively.
1 Introduction
Industrial development and population growth have led to a surge in the global energy demands. Solar energy is an important source of renewable energy and has been widely applied in various fields including transport. Solar-powered cars [1] and aircrafts [2] depend on solar cells to convert sunlight into electricity to drive electric motors. In the future, they are expected to play a key role in reducing consumption of burning fossil fuels. Currently, crystalline silicon is the most common material used for solar cells. However, a large number of toxic substances are generated during the production of crystalline silicon.
Dye-sensitized solar cells (DSSCs) [3] have been well developed over the past two decades. With the advantages of facile preparation and low cost, nanoscale inorganic semiconductors are considered as ideal substitutes for organic dyes. Moreover, their band gaps can be conveniently tailored by controlling the size of nanoparticles [4]. PbS [5], Bi2S3 [6], and other inorganic semiconductors have been used to sensitize n-type wide-band gap semiconductor, such as TiO2. TiO2 nanotube arrays (TiO2 NAs) are attracting considerable interest, because they can provide direct and efficient transport channels for photogenerated electrons, and promote the separation of photogenerated electrons and holes [7]. TiO2 NAs can be grown directly on the surface of metal Ti by the anodic oxidation method [8]. Ti alloy with lightweight and high-strength is considered an ideal material for solar-powered cars and aircrafts. Therefore, we intend to sensitize TiO2 NAs with inorganic semiconductors to construct solar cells, and study their photoelectric properties.
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Previously, we had demonstrated that both Bi2S3 and PbS nanoparticles are efficient sensitizers for TiO2 NAs [6, 9]. Nevertheless, the strategy of TiO2 sensitized by the single inorganic semiconductor limited the further improvement of the photoelectric performance and light absorption property. As a result, co-sensitized strategy has been adopted by many researchers. On the other hand, it has been reported that the bulk nano-heterojunction structure formed by Bi2S3 and PbS quantum dots can enhance the carrier lifetime resulting from the separation of nanoscale phase, and then the photoelectric properties can be improved [10]. Thus, in this work, we first prepared PbS and Bi2S3 nanoparticles to co-sensitize TiO2 NAs, and studied their photoelectric properties. The preparation process and photoelectric properties of PbS and Bi2S3 nanoparticles co-sensitized on TiO2 NAs were discussed.
2 Methods
2.1 Preparation of TiO2 NAs
An anodic oxidation method was used to grow TiO2 NAs on the surface of Ti foil. In brief, Ti foil (3 cm × 1 cm × 0.25 mm) was anodized in ethylene glycol containing 0.25 wt% NH4F at a constant voltage of 60 V for 6 h, while a larger Pt foil (3 cm × 4 cm) was used as the counter electrode. All experiments were carried out at room temperature. The as-prepared samples were annealed at 450 °C for 3.5 h.
2.2 Preparation of Bi2S3/TiO2 NAs
Bi2S3 was deposited into anatase TiO2 NAs by a hydrothermal method. At first, Bi(NO3)3 (100 mL) and Na2S2O3 (100 mL) aqueous solutions with certain concentrations were prepared, respectively. The molar ratio of Bi3+ to S2O32− was fixed at 2:3. In this work, three concentrations of Bi3+ were chosen, 1, 5, and 10 mmol L−1. And then, both of Bi(NO3)3 and Na2S2O3 aqueous solutions were mixed and stirred thoroughly to obtain precursor solution. The aforementioned precursor solution was transferred to a 25-mL Teflon-lined stainless steel autoclave containing anatase TiO2 NAs sample. The autoclave was sealed and maintained at 100 °C for 24 h. The obtained sample is designated as Bi2S3(n)/TiO2 NAs, where n represents the concentration of Bi3+.
2.3 Preparation of PbS/Bi2S3(n)/TiO2 NAs
PbS nanoparticles (PbS NPs) were attached to Bi2S3(n)/TiO2 NAs using a sonication-assisted successive ionic layer adsorption and reaction (SILAR) method. In other words, the as-prepared Bi2S3(n)/TiO2 NAs electrode was successively immersed into 5 mmol/L Pb(NO3)2 aqueous solution, D.I. water, 5 mmol L−1 Na2S aqueous solution, and D.I. water again for 20 s each. According to our previous study [9], the SILAR cycles were carried out five times under ultrasonic waves of 20 kHz and 100 W to form PbS NPs of lower 4 nm. The sample was denoted as PbS/Bi2S3(n)/TiO2 NAs.
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2.4 Characterization
The morphologies and structure of all samples were examined using a field emission scanning electron microscope (FESEM, JSM 7001F, JEOL, Japan) and powder X-ray diffraction (XRD, PANalytical diffractometer), respectively. Energy dispersive X-ray analysis (EDX) attached to FESEM was used to qualitatively and quantitatively analyze the chemical composition of samples.
A surface photovoltage (SPV) measurement system was used to characterize the transport characteristics of photogenerated electron–holes pairs. For more details, please refer to Refs [6, 9, 11].
Photoelectric property of electrodes was studied using electrochemical work-station (Lanlike 2006A, China) in 0.5 mol/L Na2S electrolyte. PbS/Bi2S3(n)/TiO2 NA (on Ti foil) was used as the working electrode, while Pt foil and SCE were used as counter and reference electrode, respectively. The electrodes were tested under simulated sunlight at AM 1.5 (100 mW/cm2) from a 500 W xenon lamp and an AM 1.5 filter. The effective surface area of the electrode was 1.0 × 1.5 cm for illumination.
3 Results and discussion
Previously, Bi2S3 NPs had successfully been deposited into TiO2 NAs by hydrothermal method at 100 °C [6]. And PbS NPs also can be attached to TiO2 NAs by a sonication-assisted SILAR method [9]. So, we believed that nanoscale Bi2S3 and PbS can be successively deposited on TiO2 NAs using two methods mentioned above. Figure 1 shows the XRD pattern of PbS/Bi2S3(1)/TiO2 NAs. Besides Ti and anatase TiO2, X-ray diffraction peaks of orthorhombic Bi2S3 and cubic PbS can also be found. Symbols T, A, B, and P in Fig. 1 represent the peaks of Ti, TiO2, Bi2S3, and PbS, respectively. The XRD result confirms that PbS/Bi2S3(n)/TiO2 NAs composite can be formed.
Fig. 1
XRD pattern of PbS/Bi2S3(1)/TiO2 NAs. Symbols T, A, B, and P represent the peaks of metal Ti, anatase TiO2, orthorhombic Bi2S3, and cubic PbS, respectively
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Figure 2 shows the typical top-view FESEM images of pure TiO2 NAs and PbS/Bi2S3(n)/TiO2 NAs. The regularly arranged TiO2 NAs fabricated by anodic oxidation are shown in Fig. 2a; its diameter and wall thickness are about 140 and 20 nm, respectively. The views of PbS/Bi2S3(n)/TiO2 NAs (Fig. 2b, c, and d) illustrate that some nanoparticles are decorated into TiO2 nanotubes, including interior of nanotubes and outside of nanotube walls. According to the XRD result, we confirm that these nanomaterials are Bi2S3 and PbS. The filling degrees of TiO2 NAs increased along with the concentration of Bi3+. We assume that the content of PbS in all samples remains unchanged, because PbS NPs were synthesized using the same conditions. The content of Bi2S3 in TiO2 NAs was determined by EDX experiments, as shown in Fig. 3. The results of EDX analysis show that the mass fractions of the Bi element are 4.18 %, 14.24 %, and 30.36 % with respect to that of PbS/Bi2S3(n)/TiO2 NAs, respectively for n = 1, 5, and 10.
Fig. 2
FESEM images: top-view of a pure TiO2 NAs and b, c, and d PbS/Bi2S3(n)/TiO2 NAs composites (n = 1, 5, and 10, respectively)
Fig. 3
EDX spectra of PbS/Bi2S3(n)/TiO2 NAs. a, b, and c for n = 1, 5, and 10, respectively
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TiO2 is an important n-type semiconductor with a wide-band gap (Eg = 3.2 eV), while n-type Bi2S3 has a narrow Eg of 1.3 eV. Photogenerated electrons can easily transfer from the Bi2S3 surface to TiO2, because Bi2S3 has a more negative conduction band (CB) [12]. The Eg of bulk PbS is only 0.41 eV, but is directly dependent on the size of nanoparticles. According to Refs. [13] and [14], PbS NPs of 4 nm or lower has a more negative CB than that of TiO2. Previously, we found that PbS NPs (<4 nm) can be fabricated using a sonication-assisted SILAR method when cycle number (n) is 5 [9]. Figure 4a schematically illustrates energy band diagram of PbS, Bi2S3, and TiO2. Thus, we hope to construct PbS/Bi2S3/TiO2 NAs heterojunction to promote the separation and transport of photogenerated electron–hole pairs.
Fig. 4
Energy band diagram of PbS, Bi2S3, and TiO2 before a and after b forming heterojunction. The dotted lines indicate the position of Fermi level
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SPV system is an effective tool to investigate the behavior of photogenerated charge carriers. SPV spectra of PbS/Bi2S3(n)/TiO2 NAs are shown in Fig. 5. Simultaneously, corresponding SPV spectrum of pure Bi2S3 is shown in the inset of Fig. 5. The signal of SPV is due to the difference of surface potential barriers before and after light illumination [15]. Noticeable SPV response ranging from 300 to 400 nm is found for TiO2 NAs attributed to its wide Eg. For pure Bi2S3, it has a strong response in the whole-tested wave spectrum, especially 400–800 nm, because Bi2S3 has a narrow Eg (1.3 eV). The SPV response of PbS/Bi2S3(n)/TiO2 NAs increases gradually with the amount of Bi2S3 in the range over 400 nm. This is because SPV response is directly related to the amount of semiconductor. However, in the range of 300–400 nm, PbS/Bi2S3(5)/TiO2 NAs has strongest SPV response intensity in all PbS/Bi2S3(n)/TiO2 NAs. This result suggests that there is one or more heterojunction among PbS, Bi2S3, and TiO2 NAs, which aids the separation of photogenerated electrons and holes. Both Bi2S3 and TiO2 are n-type semiconductors, the direction of an internal electric field in Bi2S3 (n)/TiO2 heterojunction is opposite to that of built-in electric field in p-type PbS. Thus, when PbS NPs are coupled with Bi2S3(n)/TiO2 NAs, the SPV response in 300–400 nm spectral range appears to decline.
Fig. 5
Surface photovoltage (SPV) spectra of pure TiO2 NAs and PbS/Bi2S3(n)/TiO2 NAs (n = 1, 5, and 10, respectively), and pure Bi2S3 (inset)
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The J–V and P–V characteristics of pure TiO2 NAs and PbS/Bi2S3(n)/TiO2 NAs electrodes in 0.5 mol L−1 Na2S electrolyte are shown in Fig. 6a, b, respectively. And then, the corresponding parameters of photoelectrical performances are summarized in Table 1. The plain TiO2 NAs electrode exhibits a negligible photoelectrical property. The short-circuit photocurrent (Jsc) and photo conversion efficiency (η) of plain TiO2 NAs electrode are 1.01 mA/cm2 and 0.26 %, respectively. For PbS/Bi2S3(n)/TiO2 NA electrodes, the Jsc firstly increases and then decreases with the concentration of Bi3+ (n, n = 1, 5, and 10), reaching 2.88, 4.70, and 1.51 mA/cm2, respectively. Accordingly, the highest η of 1.13 % is obtained from PbS/Bi2S3(5)/TiO2 NAs electrode, which is around four times higher than that of plain TiO2 NAs electrode. This result indicates that PbS and Bi2S3 nanoparticles co-sensitized on TiO2 NAs can remarkably improve their photoelectric property.
Fig. 6
J–V (a) and P–V (b) characteristics of pure TiO2 NA and PbS/Bi2S3(n)/TiO2 NA electrodes (n = 1, 5, and 10, respectively)
Table 1
Parameters of photoelectric property of TiO2 NA and PbS/Bi2S3(n)/TiO2 NA electrodes
Sample
Jsc (mA/cm2)
Voc (V)
FF
η (%)
Pure TiO2 NAs
1.04
0.90
0.28
0.26
PbS/Bi2S3(1)/TiO2 NAs
2.88
0.72
0.31
0.65
PbS/Bi2S3(5)/TiO2 NAs
4.70
0.72
0.33
1.13
PbS/Bi2S3(10)/TiO2 NAs
1.52
0.70
0.42
0.45
Jsc, Voc, FF, and η are the short-circuit current density, open-circuit voltage, fill factor, and overall power conversion efficiency, respectively
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The improved photoelectrical property of PbS/Bi2S3(n)/TiO2 NAs electrodes may be attributed to several reasons. Firstly, the light response of TiO2 NAs electrodes is extended from the UV to visible region after being co-sensitized by PbS and Bi2S3 NPs. This means that more sunlight can be used to generate the photocurrent. Secondly, as shown in Fig. 4b, Bi2S3/TiO2 and PbS/Bi2S3/TiO2 heterojunctions have been formed, and then the Fermi levels of TiO2, Bi2S3, and PbS tend to reach balance, producing efficient charge transfer channel. Thirdly, the interfacial electric field in Bi2S3/TiO2 and PbS/Bi2S3/TiO2 heterojunction may prevent the recombination of photogenerated electron–hole pairs. However, higher concentration of Bi3+ would cause conglomeration of the crystal nucleus, and moreover, excess Bi2S3 would act as potential barrier for charge transfer. As a result, the photoelectric properties of PbS/Bi2S3(n)/TiO2 NAs would not be further improved. The best photoelectrical performance is obtained from PbS/Bi2S3(5)/TiO2 NAs electrode, in which Jsc and η are 4.70 mA/cm2 and 1.13 %, respectively.
4 Conclusions
PbS/Bi2S3/TiO2 NAs has been fabricated by a three-step process containing hydrothermal and sonication-assisted SILAR method. PbS NPs were attached to Bi2S3(n)/TiO2 NAs, in which the size of PbS NPs was maintained lower than 4 nm by controlling the SILAR cycles. PbS and Bi2S3 NPs were co-sensitized on TiO2 NAs to enhance their photoelectric property. When the concentration of Bi3+ was 5 mmol/L, the best photoelectric property was obtained. Jsc and η of PbS/Bi2S3(5)/TiO2 NAs were respectively 4.70 mA/cm2 and 1.13 % under an illumination of 100 mW/cm2.
Acknowledgments
The research was supported by Program of International S&T Cooperation (2013 DFA51050), National Magnetic Confinement Fusion Science Program (2013GB110001), the 863 Program (2014AA032701), the National Natural Science Foundation of China (11405138, 51302231), and the Western Superconducting Technologies Co., Ltd.
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