Synthesis and Characterization of Sb2S3 Nanorods via Complex Decomposition Approach

Based on the complex decomposition approach, a simple hydrothermal method has been developed for the synthesizing of Sb2S3 nanorods with high yield in 24 h at 150◦C. The powder X-ray diffraction pattern shows the Sb2S3 crystals belong to the orthorhombic phase with calculated lattice parameters a = 1.120 nm, b = 1.128 nm, and c = 0.383 nm. The quantification of energy dispersive X-ray spectrometric analysis peaks give an atomic ratio of 2 : 3 for Sb : S. TEM and SEM studies reveal that the appearance of the as-prepared Sb2S3 is rod-like which is composed of nanorods with the typical width of 30–160 nm and length of up to 6 μm. High-resolution transmission electron microscopic (HRTEM) studies reveal that the Sb2S3 is oriented in the [10-1] growth direction. The band gap calculated from the absorption spectra is found to be 3.29 ev, indicating a considerable blue shift relative to the bulk. The formation mechanism of Sb2S3 nanostructures is proposed.


Introduction
Recently, metal chalcogenides have attracted considerable attention due to their proven and potential applications in electronic, optical, and superconductor devices.Among these materials, antimony sulfide (Sb 2 S 3 ) is a kind of semiconductor with its interesting high photosensitivity and high thermoelectric power.Antimony sulfide is a layer-structured direct bandgap semiconductor with orthorhombic crystal structure [1].Sb 2 S 3 is considered as a promising material for solar energy due to its band gap which covers the range of the solar spectrum [2].Sb 2 S 3 has been extensively investigated for its special applications as a target material for microwave devices [3], television cameras and switching devices [4], rechargeable storage cell [5], and various optoelectronic devices [6].Over the past two decades, many methods have been employed to prepare Sb 2 S 3 including thermal decomposition [7], solvothermal reaction [8][9][10][11], microwave irritation [12], hydrothermal reaction [13,14], and vacuum evaporation [15].Besides an elemental reaction and vacuum evaporation, Sb 2 S 3 can be prepared by chemical routes.SbCl 3 reacts with different sulfide ion sources, such as ammonium sulfide, thiourea, sodium thiosulfate, and thioacetamide as well as with complexing agents in aqueous or nonaqueous solutions [16,17].However, most of the asprepared Sb 2 S 3 materials are amorphous, and they need to be annealed at high temperature in air or in N 2 atmosphere in order to crystallize.In addition, crystalline Sb 2 S 3 can be obtained directly via two-heater method [18] and liquidmediated metathetical reactions [19].But different method has its disadvantage.For the vacuum evaporation and direct elemental reaction methods, it is difficult to obtain exact stoichiometric compositions because of the differences in the vapor pressures of the reaction species.Consequently, exploring a convenient synthesis method is significant [20].Recently, we have reported a new method via redox mechanism by using starting materials in elemental form [14]. Several morphologies of Sb 2 S 3 have been reported, for example, microspheres, microtubes [21], dendrite or feather [22], dumbbell-like [23], and also peanut-shaped superstructures [24].In this study, Sb 2 S 3 nanorods were prepared by complex decomposition approach via hydrothermal method.spectroscopy detector).Optical measurements were carried out by a Perkin-Elmer lambda UV/Vis spectrophotometer (model specord 400) and the photoluminescence were done by a perkin-Elmer Ls 55 luminescence spectrometer.

Results and Discussion
A typical XRD of the as-prepared Sb 2 S 3 is shown in Figure 1.
All the peaks in the pattern can be indexed to an orthorhombic phase with lattice parameters a = 1.122 nm, b = 1.128 nm, and c = 0.384 nm.The intensity and positions of the peaks are in good agreement with the values reported in the literature (JCPDS card File: 42-1393).No characteristic peaks are observed for other impurities such as antimony oxides, or SbOCl.Figure 2 shows a typical EDXA spectrum recorded on single crystals, whose peaks are assigned to Sb and S. The EDX analysis of the product confirms the ratio of Sb/S to be 2 : 3, as expected.According to EDX analysis, no impurity such as elemental antimony, antimony oxides or SbOCl is observed.
The crystal size (CS) is calculated from X-ray diffraction patterns using Scherer's formula (CS = Kλ/β cos θ, where β is the full width at the half maximum of peak corrected for instrumental broadening, λ is the wavelength of the Xray and K is Scherrer's constant) [25].The grain size was 22 nm.The morphology of the prepared Sb 2 S 3 was examined by scanning electron microscopy.SEM images with different magnification shows that the length of Sb 2 S 3 nanorods is up to 6 μm and 30-160 nm as diameter (Figures 3(a) and 3(b)).Also, Figure 4 shows atomic force microscopic image of as-prepared Sb 2 S 3 with rode like structure and phase homogeneity.
Figure 5(a) shows TEM image of as-prepared Sb 2 S 3 nanorods.Also, the typical HRTEM image recorded from the same nanorods is shown in Figure 5(b).The crystal lattice fringes are clearly observed and average distance between the neighboring fringes is 0.79 nm, corresponding to the [1 1 0] plane lattice distance of orthorhombic-structured Sb 2 S 3 , which suggests that Sb 2 S 3 nanorods grow along the [1 0 −1] direction.The SAED pattern of the nanorods indicates that its single-crystal nature and long axis is [1 0 −1] (Figure 5(c)).
To explain the synthesis process, possible chemical reaction involved in the synthesis of Sb 2 S 3 could be listed in Scheme 1.
First, EDTA was reacted with CS 2 in water for 12 h to give a clear solution, which was precipitated in ethanol.The product was recrystallized in methanol: chlorophorm (1 : 1) mixture and characterized by FTIR spectroscopy.This is a thiocarbonate ester of EDTA, which seems to act as a ligand to form an intermediate complex of Sb 3+ , as confirmed by similar FTIR spectroscopy.Such an intermediate complex is isolated by heating of a reaction mixture of CS 2 , EDTA, NaOH, and SbCl 3 in water under hydrothermal condition for 1 h.The resultant mixture was filtered and the obtained precipitate was identified by FTIR spectroscopy.
Comparison of the FTIR spectra shows that the same bands indicate some shift due to the complexation of the ligand.The line positions (in cm −1 ) of ν = 691 C-S stretching, ν = 1174 esteric band, ν = 1250 C-N stretching (tertiary amine) in case of ligand shifts to ν = 888 C-S stretching, ν = 1119 esteric band, ν = 1283 C-N stretching (tertiary amine) due to complexation.After 24 h exposing to heat and pressure, the resultant Sb 3+ complex will be degraded completely to form the Sb 2 S 3 compound.The EDX result (see Figure 2) shows that no organic compound remains in the sample.In semiconductors, band gaps have been found to be particle-size dependent and increase with decreasing of particle size [26].As Sb 2 S 3 is a narrow band gap semiconductor (Eg is 1.7 ev for bulk), with decreasing in diameter into nanoscale, novel optical properties may be observed.The photoluminescence (PL) spectrum of synthesized antimony sulfide, shown in Figure 6, has an excitation peak at 390 nm (Figure 6(a)), and the emission peak can be observed at 415, 442 and 475 nm (Figure 6(b)).
The absorption spectra of Sb 2 S 3 (prepared by dispersion of Sb 2 S 3 nanorods in ethanol) show an intense absorption band at 315 nm with band gap around 3.29 ev (Figure 7).A blue shift phenomena is seen for Sb 2 S 3 nanorods.
Most of the materials have different structural defects that create defect energy levels between band gaps of material.These defects result in difference of the UV absorption and PL excitation spectra.

Conclusion
In summary, a complex decomposition approach in hydrothermal condition has been developed to prepare Sb 2 S 3 nanorods with high yield.The length of the nanorods is up to 6 μm and their diameter is around 30-160 nm.Single crystals could be obtained by increasing of heating time up to 48 h.High-resolution transmission electron microscopic (HRTEM) studies reveal that the Sb 2 S 3 is oriented in the [10-1] growth direction.A blue shift was observed in the case of optical absorption and PL, common feature for nanomaterials.

Scheme 1 :
Scheme 1: Possible chemical reaction in the synthesis of Sb 2 S 3 nanorods.