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Research Paper | Physics | India | Volume 14 Issue 4, April 2025 | Rating: 5.2 / 10
Utilization of Palladium-Doped MoS2 Hybrid Structures for the Micro-Trace Detection of Arsenic (III) Ions
Namita, Naushad Alam, Jamilur R. Ansari
Abstract: Molybdenum disulfide (MoS?), a prominent two-dimensional transition metal dichalcogenide (TMD), is characterized by its remarkable mechanical properties, tunable bandgap, and layered structure, which offers a high surface area conducive for various catalytic and electronic applications. However, its relatively low electrical conductivity and limited active sites hinder its efficacy in electrochemical and catalytic processes. To address these shortcomings, palladium (Pd) nanoparticles (NPs) can be integrated into the MoS? matrix, resulting in a hybrid nanostructure that enhances charge transfer kinetics and catalytic performance. The synthesis of Pd-MoS? hybrid structure typically involves a two-step process: initial production of MoS? nanosheets via hydrothermal or liquid exfoliation methods, followed by the deposition of Pd nanoparticles through chemical reduction techniques. The development and characterization of Pd-MoS? hybrid structure have garnered significant research attention, driven by their superior physicochemical properties and extensive potential applications across catalysis, energy storage, and sensing domains. The synthesized Pd-MoS? hybrid structure exhibits improved electrical conductivity, enhanced catalytic efficiency, and an increased density of surface-active sites. These attributes render it particularly promising for electrocatalytic applications, such as the hydrogen evolution reaction (HER), fuel cells, supercapacitors, biosensors, and environmental remediation efforts. The synergistic interactions between Pd and MoS? nanosheets not only bolster the performance of the composite material but also pave the way for innovative design strategies tailored toward advanced materials with specific functionalities. Future research focused on optimizing synthesis parameters, achieving uniform nanoparticle dispersion, and ensuring long-term stability will be crucial for unlocking the comprehensive potential of the Pd-MoS? hybrid structure in next-generation technologies.
Keywords: Nanocomposites, Electrochemical, Catalytic, hybrid structure, Sensing
Edition: Volume 14 Issue 4, April 2025,
Pages: 776 - 783