Thin films deposited from chalcogenide glasses have several potential applications in optical communications, opto-electronic applications, and solar cells [1]. Chalcogenide glasses are based mainly on chalcogen elements Sulfur, Selenium, and Tellurium and are formed by bonding to network forming elements of comparable electronegativity, such as In, Sn, Si, Ge, Ga and Cd [2–5]. On the other hand, infrared glasses are mainly based on covalently bonded elements of comparable values of electronegativity. In this regard, chalcogenide glasses are covalently bonded, possess a weak inter-atomic bonding, and they look more like polymers. They show much interest in diverse areas of applications because of their transparency in the near- and mid- IR spectral regions, high refractive index, and excellent non-linear behavior [6,7]. Due to these structural characteristics, chalcogenide glasses are ideal for infrared and nonlinear optics, bio-sensors, and waveguide applications [7,8]. Chalcogenide glasses have shown fast response to optical non-linearity over conventional silicon-based glasses [9]. On the other hand, synthesis process and the glass compositional ratios can strongly govern the desired properties of the obtained chalcogenide based thin films [10]. Selenium and tellurium based glasses are having notable glass-forming ability and good integration with other elements with comparable electronegativity [4,11]. In this regard, ternary glass systems make it possible for more atoms to incorporate into the glass matrix resulting in improved properties. Se–Te system is most studied due to its functionality as glass host matrix and its elevated glass forming ability. However, physical properties of these glasses were reported to be improved by dopant elements [12,13]. Incorporating metallic elements to the Se–Te glass matrix resulted in high thermal stability of the system [14,15]. Additionally, metallic dopants were reported to improve chalcogenide glass characteristics such as optical, electrical, and mechanical properties [5]. Indium doping was reported to expand the glass forming region and increase the disorder in the system which leads to wider areas of applications [7,16]. On the other hand, chalcogenide glasses were reported to possess elevated values of the nonlinear optical parameters [17]. It was also reported that materials with elevated optical nonlinearity have potential applications in photonics, optoelectronics, and optical sensing applications [18].

In the present study, the effect of partial replacement of tellurium by indium on structural, physical, and optical properties of Se–Te–In chalcogenide thin films is studied. Linear and non-linear optical parameters are calculated and discussed in terms of glass composition.

Three chalcogenide glass’ matrices containing different concentrations (in wt.%) of Se, Te, and In elements were prepared, from high purity chemicals (99.999%), using the melt quench technique. The following chemical formula describes the ratio of each constituent in the ternary glass system: 80 wt.% Se⋅20−x wt.%Te⋅x wt.% In, where, x=0, 5, and 10wt.%. Where suitable amount of raw elements (calculated according to atomic weight and constituent ratio) were introduced and sealed in evacuated silica tubes (at pressure of ∼10−5Torr) in order to avoid sample oxidation. Samples were then heated at 800±5°C in horizontal furnace for up to 15h. Prior to heating, tubes were treated in an ultrasonic cleaner and cleaned several times using detergent and double distilled water, and a final washing with ethyl alcohol. Continuous rocking of the tubes during heating was necessary in order to maintain homogeneity and uniformity of the melts. Finally, the molten materials were quenched into iced water to avoid any sort of crystallization.

The obtained bulk glass’ samples were ground into powder using hydraulic pressing under vacuum, in order to be used to prepare thin films. A suitable amount of the powdered material was positioned into a Molybdenum Boat and evaporated on a silica glass (SG) substrate under high vacuum of ∼2×10−5Torr using a standard Edwards A306 Auto coating unit with conventional rotary and turbo molecular pumps. Prior to use, SG substrates were cleaned several times before being mounted in the rotating substrate work holder, with adjusted rotating speed that allows the production of highly homogeneous films.

Differential scanning calorimetry was employed to perform thermal analysis of the studied bulk samples, using a DSC6220 calorimeter from EXSTAR SII with accuracy of 0.1K. Samples were scanned at different heating rates, using a 3mg sample amount, in the temperature range from 300 to 580K. Before each heating cycle, calorimeter was calibrated using the well-known melting enthalpy of indium. Amorphous nature of thin film samples was confirmed via XRD using Shimadzu XRD-7000 diffractometer, with a Cu Kα radiation of λ=1.5406Å, at scan rate of 2°/min, in the 2θ range from 10° to 90°. Optical analysis was performed using an Evolution 600 UV-Vis spectrophotometer from Thermo scientific USA, in the spectrum range from 190 to 1100nm.

In this work, three chalcogenide glasses of the composition Se80Te(20−x)Inx, where x=0, 5, 10, were synthesized via fast quenching of their melts. Bulk samples were studied by differential scanning calorimetry in order to check for their internal nature. Results showed that bulk samples possess only small endothermic peak for each sample, that identifies the glass transition temperature Tg, followed by an exothermic peak that defines the amorphous-crystalline phase transition Tp. Values for Tg and Tp were decreased when increasing the amount of In. These results confirmed the amorphous nature of the bulk samples. On the other hand, powdered bulk samples were thermally evaporated to prepare three planner thin films of the glass composition. XRD analysis confirmed the amorphous nature of the studied thin films. Optical absorbance and transmittance were recorded and used to calculate absorption coefficient, refractive index, and band gap. Indium incorporation to the glass matrix contributed to elevating refractive index and showed wide transmission window in the visible and near IR regions. Nonlinear optical parameters were calculated using values of refractive index and discussed in terms of the glass composition. Results of nonlinear refractive index, first and third order optical susceptibilities nominate the studied thin films for applications in IR waveguides and optical sensors.