Environmental risk assessment (ERA) is a process used to evaluate the potential risks posed by nanotechnology to the environment. The process involves identifying, assessing, and mitigating the risks associated with the use and of nanotechnology. ERA typically involves assessing the toxicity, fate and transport, and persistence of nanomaterials in the environment. It also involves determining the potential impacts of nanomaterials on the environment, ecosystems, and public health. ERA is important in the of new nanotechnologies, as it allows developers to understand the potential environmental impacts of their products and ensure that they are safe for both the environment and human health. It also helps to identify potential risks and develop strategies to mitigate them. There are several components of ERA including risk identification, risk assessment, and risk management. Risk identification is the first step in ERA and involves identifying the potential risks of nanomaterials to the environment. This includes identifying the type of nanomaterials and their properties, the potential for exposure, and the associated health and environmental risks. Risk assessment is the second step in ERA and involves assessing the potential risks associated with nanomaterials.
Thomas J Webster
Hebei University of Technology, United States
Hossein Hosseinkhani
Innovation Center for Advanced Technology, Matrix, Inc., United States
Hai Feng Ji
Drexel University, United States
Paulo Cesar De Morais
Catholic University of Brasilia, Brazil
Azzedine Bensalem
Long Island University, United States
Robert Buenker
Wuppertal University, Germany
Rafal Kozubski
Jagiellonian University in Krakow, Poland
Sylwia Wcislik
Kielce University of Technology, Poland
Raman Singh
Monash University-Clayton Campus, Australia
Michael I Tribelsky
Moscow State University, Russian FederationSubmit your abstract Today
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