dc.description.abstract |
Photocatalysis has emerged as one of the most promising technologies and represents a
easy way to utilize the energy of natural sunlight and it can provide viable solutions for
environmental remediation and alternative clean energy supply. In natural photosynthesis,
plants use sunlight to rearrange chemical bonds of H2O to produce O2 and the reduced fuel.
Therefore, the direct conversion of solar energy into chemical energy/fuels using artificial
photosynthesis constitutes an ideal technology for harvesting and storing sunlight energy in
the form of chemical fuels such as H2. The dihydrogen has been considered as the fuel of
future and an environmental friendly alternative to fossil fuels. It is important to note that, the
strong dependence on non-renewable energy resources like fossil fuels has resulted global
warming and air pollution. Therefore it is utmost urgent to develop clean sources of energy
which are pollution free. Thus, development of heterogeneous photocatalysts for efficient
water splitting into H2 and O2 using sunlight constitutes the most promising process for
carbon-neutral, sustainable energy. In this regard, semiconductor nanostructures have
attracted immense attention due to their size-dependent unique optical and photocatalytic
properties. The properties of these nanomaterials depend on their crystallite's size,
morphology and structure. Therefore, controlling the size and morphology is crucial to tailor
the properties of these nanostructures. Particularly, the metal sulfide nanocrystals (NCs) of
CdS, Zn1-xCdxS and MoS2 have gained considerable interest owing to their promising
photocatalytic applications for degradation of toxic organic pollutants and water splitting and
H2 generation. Various inorganic and organic sulfur compounds have been employed as in
situ source of S2- ions for the syntheses of metal sulfide nanocrystals (NCs). However,
literature study revealed that it is quite difficult to obtain nanocrystals with smaller (~2-5 nm)
size without the use of template/capping ligand. Though the use of template
molecules/capping agents assist in the formation of nanostructures with well-defined
morphology, the capping ligand-free NCs offer several advantages over capped-NCs.
Towards development of metal sulfide nanostructures with controlled size, morphology, we
sought to use organosulfur compounds wherein the release of S2-
ions can be controlled by tuning the reaction temperature. In this regard, the present work
investigates the development of facile, one-pot routes for controllable synthesis of metal
sulfide (CdS, ZnS, PbS, CuS, Zn1-xCdxS and MoS2) NCs from new organosulfur compounds,
4,4'-dipyridyl disulphide (DPDS = (C5H4N)2S2) and dibenzyl disulphide (DBDS = (C7H7)2S2)
which acts as temperature controlled in situ source of S2- ions. The synthesized metal sulfide
NCs have been characterized by various techniques and their photocatalytic applications for
degradation toxic organic pollutants (dyes) in water and water splitting into H2 generation has
been investigated. For the first time, we have demonstrated application of Zn1-xCdxS NCs for
visible-light-assisted reduction of niroaromatic pollutants in water by utilizing the hydrogen
generated by water splitting as a source of protons. Further, development of hybrid
nanostructures of MoS2/C3N4 and their visible-light-assisted photocatalytic properties for
water splitting and H2 generation has been also been investigated. |
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