In recent years metal chalcogenides

In recent years metal chalcogenides like ZnS, CdS, CuS and MoS2 have been studied because of
great interest due to their unusual physical and excellent chemical properties [1-2]. Now-a-days,
synthesis and characterization of semiconducting metal chalcogenides have drawn more and more
attention. Among these metal chalcogenides, copper sulfide (CuS) nanostructures is an important ptype
semiconducting material due to its unique electrical, optical, physical, chemical properties [3-
4].
CuS possesses metal-like electrical conductivity and good chemical sensing capabilities.
Recently, nanocrystalline copper sulfide has been used for manufacturing ion selective electrodes,
hydrogen sulphide sensors, photoelectric transformers and superconductors [5-8]. Therefore, much
research on CuS physicochemical properties and its method of growth has been going on among the
researchers. It is widely used in many applications like thin films, solar cells, nanometer scale
switches, optical filter, superionic conductor, catalysis, sensors, solar radiation absorber, electronic
and optoelectronic applications, environmental applications like photocatalytic applications for dye
degradation, water purification and waste water treatment [9-14]. CuS grows with different
morphologies like nanoflowers, urchin-like structures, nanotubes [15], nano flowers [16], nanorods
[17], nanoflakes [18], nanodisks, nanospheres[19], nanocubes and nanocrystals [20]. Some
nanoparticles were already synthesized by high energy milling in the laboratory mills and very good
results were achieved. In fact, many methodologies have been explored which include solventless
and solution thermolysis, hydrothermal method, solvothermal method, microwave method, chemical
conversion, sonochemical method, chemical vapour deposition, polyol method, wet chemical
method, etc., [21-25] for the synthesis of CuS nanomaterials. It is noted that various surfactants or
templates are usually used in the reaction systems, and they all play critical roles in the
morphological control of CuS nanomaterials. However, the use of surfactants or templates will
inevitably increase the reaction complexity, cause impurity in the products, and is disadvantageous.
Thus, the development of a facile, effective, and surfactant-free approach for the controlled
Journal of Nano Research Vols. 18-19 (2012) pp 43-51
Online available since 2012/Jul/26 at www.scientific.net
© (2012) Trans Tech Publications, Switzerland
doi:10.4028/www.scientific.net/JNanoR.18-19.43
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synthesis of CuS nanomaterials is highly desirable. Among all these methods, hydrothermal route is
very effective and a simple method used for the preparation of CuS nanomaterials without any
complex reactants [26,27].
In this paper, a simple method has been adopted to grow CuS nanomaterials with different
hierarchical structures without the need of any surfactant by a hydrothermal route. In this regard,
copper chloride as a Cu-precursor, thiourea and sodium thiosulphate as S-sources has been utilized
for the preparation of CuS nanostructures. An investigation has also been done on the effect of
reaction time on the morphology of the products. A detailed mechanism on the growth at different
experimental parameters has been discussed.
2.