It is known that semiconducting nan

It is known that semiconducting nanostructure is one of the
best candidates to fabricate photodetector and photovoltaic devices [1–5]. In fact, the military and industrial applications of
photodetector and solar cell devices are highly important. However, the efficiency and responsibility of these nanostructures for
these industrial applications are the most important issue that
should be taken into account. In fact, when these nanostructures
are illuminated by a photon with energy greater than the band gap
energy of the nanostructures, an electro-hole pair is created. Such
pairs can play as photocatalyst that remove pollutions, or photocurrent, and be used in a circle and generate an electrical current.
To increase the photoresponse speed of a semiconductor, some
important factors such as the size, electron-hole pair life time, and
increasing of photon absorption should be considered. The decreasing of the nanomaterials size causes an increase in surface
area and then more reaction with the environment. In addition,
interaction between photons and smaller particles is higher than
the bigger particles [6,7]. Therefore, presenting a method that
reduces the nanomaterials size can increase the solar-cell
efficiency and photoresponse speed. Furthermore, preparing an
environment, which can increase electron-hole pair life time and
photon absorption, is extremely important to improve solar-cell
efficiency and photoresponse speed. Graphene as a unique twodimensional (2D) structure can affect electron-hole pair life time
[8,9]. Furthermore, graphene with a zero band gap structure is a
high conductive material that can increase the photocurrent intensity of a photodetector device. Therefore, in order to join a
suitable semiconductor with a wide band gap, which can cover all
sunlight spectra, graphene could lead to obtaining a nanocomposite that can be active as a solar-cell material with high efficiency
and UV detector. Among different semiconductors, zinc sulfide
(ZnS) is one of the best semiconductors for this mission due to its
several unique properties. ZnS is an n-type semiconductor with
hexagonal structure and direct band gap energy (3.68 ev) at room
temperature. It is an eco-friendly, non-toxic, and non-hazardous
material. Moreover, ZnS has several applications in industry such
as electrical and optical conductivity, electrochemical sensors,
manufacturing solar cells, diodes, transistors, and photocatalytic
[10]. Therefore, ZnS/graphene nanocomposite is one of the best
candidates to obtain a photovoltaic material that works with a
high efficiency [11 ,12] and UV photodetector [13–16].
With regard to the above-mentioned reasons, in this work ZnS/
graphene nanocomposites were synthesized by a cost-effective
and simple co-precipitation method. L-cysteine amino acid was
employed as a green surfactant. In fact, due to the friendly
behavior of amino acid with environment, this method would be a
green chemistry method. In this study, the effects of the different
concentrations of graphene on the physical properties, solar-cell
effi ciency, and photodetector applications of the nanocomposites
were investigated.