Optical Constant and Electrical Resistivity of Annealed Sn3Sb2S6 Thin Films

doi:10.1007/s40195-016-0391-4

Abstract

Abstract:

In this study, we report the annealing effects on the physical properties of Sn₃Sb₂S₆ thin films. Sn₃Sb₂S₆thin films were prepared onto non-heated glass substrates via thermal evaporation technique. The as-deposited films were annealed in air for 1 h in the temperature range from 100 to 300 °C. X-ray diffraction results show that the crystallinity of the thin films increased after annealing. The microstructure parameters crystallite size, dislocation density, lattice strain and stacking fault probability were calculated. The optical properties were obtained from the analysis of the experimental recorded transmittance and reflectance spectral data over the wavelength range 300-1800 nm. High absorption coefficient (10⁵ cm^-1) reached to the visible and near-IR spectral range. A decrease in optical band gap from 1.92 to 1.71 eV by increasing the air annealing temperature was observed. Oscillator energy E _o and dispersion energy E _d of the films after annealing were estimated according to the model of Wemple-DiDomenico single oscillator. Spitzer-Fan model was applied to determine the electron free carrier susceptibility and the ratio of carrier concentration to the effective mass. The layers annealed at temperatures >150 °C undergo abrupt changes in their electrical properties and exhibit a resistive hysteresis behavior. These properties confer to the material interest perspectives for its application in diverse advanced technologies such as photovoltaic applications and optical storage.

Key words: Thin, films, Sn3Sb2S6, Optical, constants, Resistivity, Hysteresis

Y. Fadhli, A. Rabhi, M. Kanzari. Optical Constant and Electrical Resistivity of Annealed Sn₃Sb₂S₆ Thin Films[J]. Acta Metallurgica Sinica (English Letters), 2016, 29(3): 287-294.

Figures/Tables 14

Fig. 1 XRD patterns of Sn3Sb2S6 thin films as-deposited and annealed at different temperatures

Table 1 Estimated values of the microstructural parameters of Sn3Sb2S6 thin films annealed at different temperatures

T (°C)	D (nm)	ε	δ (10^-3 nm^-2)	α
200	20	0.38	2.50	0.01
250	23	0.36	1.80	0.20
300	24	0.31	1.70	0.25

Fig. 2 Transmittance a and reflectance spectra b of Sn3Sb2S6 thin films as-deposited and annealed at different temperatures

Fig. 3 Absorption coefficient spectra of Sn3Sb2S6 thin films as-deposited and annealed at different temperatures

Fig. 4 Plots of (αhν)2 versus hν for Sn3Sb2S6 thin films as-deposited and annealed at different temperatures

Fig. 5 Variation in Eg with the temperature of annealing for the Sn3Sb2S6 thin films

Fig. 6 Variation in the extinction coefficient, k with wavelength for Sn3Sb2S6 thin films as-deposited and annealed at different temperatures

Fig. 7 Variation in the refractive index with wavelength for Sn3Sb2S6 thin films as-deposited and annealed at different temperatures

Fig. 8 Plots of (n 2 - 1)-1 versus (hν) 2 for Sn3Sb2S6 thin films as-deposited and annealed at different temperatures

Table 2 Estimated values of the optical parameters of Sn3Sb2S6 thin films annealed at different temperatures

T (°C)	E_g(eV)	E_o(eV)	E_d(eV)	ε_∞		M_-1	M_-3
As-deposited	1.92	3.00	10.00	4.86	0.72	3.33	0.37
100	1.86	3.99	14.28	4.85	0.19	3.57	0.22
150	1.84	3.83	16.66	5.76	1.75	4.34	0.29
200	1.80	2.27	12.50	5.88	1.16	4.54	0.60
250	1.74	2.22	11.11	6.37	1.00	5.00	1.01
300	1.71	3.16	16.66	7.29	2.23	5.27	0.52

Fig. 9 Plots of ε r versus λ 2 for Sn3Sb2S6 thin films as-deposited and annealed at different temperatures

Fig. 10 Variation in the resistivity with the annealing temperatures for the Sn3Sb2S6 thin films annealed at 200 °C a, 250 °C b, 300 °C c

Fig. 11 Plots of ln σ versus 103T103T for the Sn3Sb2S6 thin films annealed at 200 °C a, 250 °C b, 300 °C c

Table 3 Estimated values of the activation energies of Sn3Sb2S6 thin films annealed at different temperatures

T (°C)	ΔE₁ (eV)	ΔE₂ (eV)
200	0.28	0.02
250	0.34	0.01
300	0.34	0.01

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Optical Constant and Electrical Resistivity of Annealed Sn₃Sb₂S₆ Thin Films

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