CNT-based composites can exhibit exceptional physical, chemical, and mechanical properties, and their tiny addition enhances activity significantly. These captured the eyes of food industrial sector due to its promising characteristics. Biosensing, gas sensing, antimicrobial properties, antibody immobilization, are key factor here. CNTs of various diameters, lengths, and functionalization processes were utilized to show antibacterial effect. By this effect these can be used in food packaging. By sensing ethylene, CNTs can be used in food ripening. As CNTs in pure water improves heat transmission, these can be used in controlled pasteurization which is needed for food safety. CNTs can sense cholesterol, vitamin B6 and others food ingredients. So, these can be utilized in improvement of food quality. The germination of seedlings can be helped along by CNT, which is a positive impact in food quality. The application of CNTbased nanomaterials in food industry is the focus of our research.
TiO2 nanoparticles (NPs) are very necessary for the uses that they have in a variety of fields. Several different industries are now showing a significant amount of interest in distinct types of TiO2 NPs, as well as their production, characterization, and significant applications. TiO2 NPs will benefit greatly from the development of improved synthetic pathways and better characterization techniques as a result of their quick translation into industries, the fabrication of a large number of valuable goods, and their implications for the expansion of the economy. In this study, we will discuss the many methodologies for the synthesis of TiO2 nanomaterials, the advancements that have been made in characterization methods, as well as the various unique industrial and other important application domains.
The ZIF and the plethora of nanocomposites of varying types of it are capable to the protection of the natural environment. By utilizing several processes known as adsorption, photocatalysis, oxidation, antibacterial activity, ZIF can be utilized in fuel purification, removal of heavy metal from water, managing nuclear waste, desulfarizations, adsorption of different toxic gases, and dye degradation. For these, ZIFs become important in the case of cleaning environment. By using adsorption, these have the capacity to separate gases from environment that are toxic. By oxidation, ZIF can do oxidative desulfarizations, which make ZIF efficient in cleaning environment by removing sulfur. ZIF can degrade dyes through photocatalysis which is useful in industrial water purification. As ZIFs are hydrophobic, removing halogens and rhodamine B from water is possible by utilizing ZIFs. The use of ZIF-based nanomaterials in clean environment purposes is the principal focus of our research.
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