Abstract
In recent years, there has been intensification in community discernment of the damaging possessions of fluoride to human health (because of its effects on teeth and bones), as well as effects on the environment. Artificial activities are one of the biggest issues in the world today. It is crucial to develop efficient and reliable solutions to remove excess fluoride from water environments. The fluoride parameter stands out among the others. The goals included describing the framework for monitoring water quality, defining a proposed set of indicators, and informing the public about fluoride content. It is still essential to effectively clean fluoride-contaminated water. Metal–organic framework (MOF) materials are thought to be one of the several attractive adsorption materials for the various technologies used to remove fluoride from water. This article reviews current developments in the synthesis of MOFs and their use in aquatic defluoridation. MOFs are classified as the core metal ions. The mechanism of adsorption and an assessment of potential real-world uses of fluoride removal by various MOFs are explained. The practice of artificial water fluoridation should be reviewed globally as part of efforts to prevent harmful fluoride consumption, and industrial safety regulations should be improved to reduce the unethical release of fluoride compounds into the environment. The practice of artificial water fluoridation should be reviewed globally as part of efforts to prevent harmful fluoride consumption, and industrial safety regulations should be improved in order to reduce the unethical release of fluoride compounds into the environment. Public health strategies to reduce dental caries without relying on systemic fluoride intake.
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Kulwant, M., Patel, D., Shirin, S., Sharma, S.N., Yadav, A.K. (2023). Future Frameworks for Fluoride and Algorithms for Environmental System. In: Yadav, A.K., Shirin, S., Singh, V.P. (eds) Advanced Treatment Technologies for Fluoride Removal in Water. Water Science and Technology Library, vol 125 . Springer, Cham. https://doi.org/10.1007/978-3-031-38845-3_19
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