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While the built environmental and water cycle have benefited from significant intellectual and technological advances
over the past half century, urban water phenomena remain fundamentally complex across scales that range from the
watershed to the molecular level. Additionally, concepts such as a first-flush or measurements such as TSS still perpetuate
yet are the basis for regulation. Regulations whether based on concentration, load or ?first-flush? continue to remind us that
there continues to be a significant gap in knowledge between ?Best Management Practices? (BMPs) design, monitoring and
modeling and a more fundamental unit operations and processes (UOPs) approach. Many current water cycle approaches
within our cities are not sustainable economically and their treatment performance is non-stationary; declining with time and
volume treated as well as from lack of management. Concerns over accretion and dispersion of toxics, nutrients and particulate
matter within the human habitat are significant and represent a potential chronic health concern not only for the natural
ecology but also for humans. Success with respect to a sustainable water cycle requires the integrated knowledge of unsteady
and variable hydraulics, sediment transport, hydrologic, physical, chemical and thermal properties of loadings, combined with
a fundamental foundation that includes UOP principles as well as physical and numerical models. This synthesis is critical
whether the objective is hydrologic restoration, water chemistry control, water reuse, or often, a combination of these. Validated
numerical tools such as continuous simulation (SWMM) and computational fluid dynamics (CFD) models have been more
than capable of resolving urban water issues. At the same time, more precise application of monitoring and sampling subject to
unsteady conditions, for example, granulometric analysis (in terms of particle size distributions and densities, instead of indices
such as TSS) and chemical partitioning with speciation has allowed physical and numerical models to predict management
behavior and misbehavior subject to such complex interactions. This presentation summarizes a series of selected vignettes
on urban infrastructure, rainfall-runoff interactions, urban water and methods developed over the last decade to manage the
activities within our human habitat
Biography
John J Sansalone?s research is coupling computational models of unit operations and processes with monitoring of physical models for water treatment systems,
urban infrastructure and the impacted environment subject to unsteady chemical/hydrologic/physical and climate phenomena. He has over 120 peer-reviewed
journal publications, 11 patents and over 200 conference and seminar presentations and graduated 24 PhDs. He is a Professor at the University of Florida, a
member of the PhD Faculty at the University of Bari and a Visiting Professor at a number of universities in Italy.
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