High purity graphene oxide powder (

High purity graphene oxide powder (GO 99.999%, US Research
Nanomaterials, Inc.) with 6–10 layers was applied as graphene
source. Zn(NO3)20
6H2O powder and Na2S (Sigma Aldrich) flakes
were utilized as zinc and sulfur sources, respectively. In the first
step, pure ZnS NPs were synthesized by the mixing 0.1 mol of
Zn(NO3)20
6H2O solution and 0.15 mol of Na2S solution in a
500 cc beaker with a magnet stirrer at room temperature. It was
observed that, a white precipitation was formed. A solution of
0.1 mol of sodium hydroxide (NaOH) and 0.15 mol of L-cysteine
was separately prepared in another beaker and then during approximately 2 h, this solution was added drop by drop to the big
beaker. After that, the precipitation was washed by distilled water
for several times and it was kept in an oven at 70 °C for 24 h to dry
completely. After cooling the oven, a soft and white powder was
obtained. In the next step, ZnS/GO powder with the different
concentrations of GO was synthesized. All conditions in this step
were the same as the previous conditions. In this step, a GO solution with 14 g/L concentration was prepared and then the different percentages of GO solutions with 5, 10, and 15 wt%/v concentration were added to the zinc nitrate solution. It was observed
that the color of precipitation was changed to dark color.
In order to check the quality of the obtained powders, they
were characterized using several tools. The crystal phase, morphology, and microstructure of the product were characterized
using X-ray powder diffraction (XRD, Philips, X’pert, system using
CuK α radiation), transmission electron microscopy (TEM, Hitachi
H-7100), Fourier transform infrared spectrometry (FTIR, PerkinElmer System 2000 series spectrophotometer (USA) by the KBr
method), and Raman spectroscopy (Model: Almega ThermoNicolet
Dispersive). The optical properties of the materials were studied
using a UV-visible spectroscopy (Perking-Elmer spectrometer).
To fabricate a photovoltaic and photosensor device, a mixture
of 0.01 g powder and 0.3 mL chitosan (as a conducting polymer)
was employed. This mixture was ultrasonicated in an ultrasonic
bath for 8 min and then was dropped on an SiO2 substrate, which
was cleaned under the standard conditions, between two silver
electrodes situated on two sides of a window with an area of
0.25 cm2. The devices were used as UV detector and photovoltaic.
The devices as UV detectors were subsequently used in a DC circuit
connected to an oscilloscope. Photocurrent intensities were measured under a 2 V bias potential. The photoresponse property of
the nanocomposites and NPs was examined by four UV LEDs (P ¼ 4
W- 16 W and λ¼ 395 nm) and chopped light illumination. In order to check the solar cell characteristics, the measurement was
carried out under 100 mW/cm2 (1.5 Air Mass) illumination from a
solar simulator (solar cell simulator IIIS-200þ, Nanosat Co., Iran). A
100-W xenon lamp served as a light source, and the intensity of
the light was calibrated, using a standard silicon solar cell.