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W4387530743 abstract "A strong method for developing innovative materials with numerous capabilities results from the formation of hybrid nanomaterials, in which two or more dissimilar materials are combined to form a hybrid nanomaterial. Hybrid semiconductor nanomaterialsHybrid Semiconductor Nanomaterials are gaining popularity because of their wide range of applications in environmentalEnvironmental Applications cleanup, sensingSensing applications, optoelectronicEnergy devices, energyEnergy applications storage, drug delivery, and photocatalysis. The synthesis methods play an important role in tuning the properties of hybrid nanomaterials. Physical, chemical, and mechanical processes are well-known methods for the preparation of nanomaterials. To fabricate hybrid semiconductor nanomaterialsHybrid Semiconductor Nanomaterials, different materials such as metal oxidesMetal Oxides, organic molecules, and inorganic nanostructures are mixed together. Different methods, such as hydrothermal, solvothermal, sol–gel, photoreductionPhotoreduction, microplasma–liquid interaction, and ball milling, can be used to fabricate hybrid semiconductor nanomaterialsHybrid Semiconductor Nanomaterials. This chapter discusses the pros and cons of each method of making nanomaterials and the importance of controlling their size and shape. It also reviews the potential applications of hybrid semiconductor nanomaterials and the challenges associated with their synthesis and characterization." @default.
W4387530743 created "2023-10-12" @default.
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W4387530743 date "2023-01-01" @default.
W4387530743 modified "2023-10-12" @default.
W4387530743 title "Synthesis of Multifunctional Hybrid Semiconductor Nanomaterials" @default.
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W4387530743 doi "https://doi.org/10.1007/978-3-031-39481-2_2" @default.
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