The Case Against PFAS Polluters| Beer Yeast To Remove Lead From Water
Water Online
Connecting water and wastewater professionals to technology suppliers across municipal and industrial markets
In The Flow: The Case Against PFAS Polluters (And How Water Suppliers Can Benefit)
For this episode of The Water Online Show: In The Flow, Ken Sansone , senior partner at SL Environmental Law Group, PC , describes how water suppliers can lay claim to a portion of the billions of dollars available — money that can go toward installing treatment systems to comply with the recently finalized rule establishing maximum contaminant levels (MCLs) for PFAS in drinking water.
Repurposed Beer Yeast May Offer A Cost-Effective Way To Remove Lead From Water
Every year, beer breweries generate and discard thousands of tons of surplus yeast. In this article, Anne Trafton from MIT News discusses how researchers from MIT and Georgia Tech have now come up with a way to repurpose yeast to absorb lead from contaminated water.
EPA Delivers $179M From Investing in America Agenda For Innovative Water Reuse And Drought Resilience Projects
U.S. Department of the Interior announced a $179M investment through President Biden’s Investing in America agenda for innovative water reuse projects that strengthen drought resilience across the West, increasing water security and resilience across western communities.
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PFAS Beyond Removal: 7 Often-Overlooked Factors
The most widely applied PFAS removal technologies are granular activated carbon (GAC), ion exchange (IX), and reverse osmosis (RO), although other solutions have been coming to market as well. Beyond cost and performance, plant managers and project engineers should consider the following...
The Water Research Foundation Funds 26 New Research Projects Totaling $5.9M
The Water Research Foundation (WRF) is seeking volunteer participants for 26 new research projects funded through WRF's Research Priority Program. This strategic research program enables WRF to address broadly relevant subscriber issues, challenges, and opportunities with targeted research.
Inexpensive Microplastic Monitoring Through Porous Materials And Machine Learning
Optical analysis and machine learning techniques can now readily detect microplastics in marine and freshwater environments using inexpensive porous metal substrates. Details of the method, developed by researchers at Nagoya University with collaborators at the National Institute for Materials Sciences in Japan and others, are published in the journal Nature Communications.