Environmental technology

ALGECO (Cost-effective algae technology to promote circular economy development of Norwegian wastewater treatment plants) provides a scientific blueprint for a new paradigm of bioeconomy for Norwegian wastewater treatment plants (WWTPs). We aim to transform municipal treated wastewater from waste into algae-based products by developing and implementing innovative, cost-effective and viable algae technologies.

There is a need for more accessible and comprehensive knowledge on industrial symbiosis. Through bilateral cooperation between Romanian and Norwegian actors, the CATALYST project will provide relevant and reliable information on symbiotic opportunities, case studies, and best practices for facilitators, companies and industrial symbiosis stakeholders identified through the project.

In the CORNELIA project, NIVA together with its two industrial partners tests and verifies innovative technical solutions for targeted removal of antimicrobial resistance from wastewater at hospitals (at the source) and at wastewater treatment plants (before discharge to the environment).

The goal of the DUWA project is to treat wastewater discharges from hospitals to minimize the spreading of antimicrobial resistance (AMR) to the environment and to reduce the emission of micropollutants. NIVA assists the start-up company Sustaintech AS in the development and verification of ozonation to remove antibiotic resistant bacteria (ARB) and antibiotic resistance genes (ARG) in wastewater decentrally at a Norwegian hospital.

The Arctic environment is facing evident changes such as temperature increase and consequent rapid decline in the sea ice. These conditions will favour the development of industrial activities, e.g., oil & gas exploration and aquaculture. We need to assess the potential environmental risks from the anticipated industrial development in the Arctic, and to do that, we need to develop robust methods and approaches that characterise the pollution pathway from the emission to the environment to the display of adverse outcomes in the biota.

Antimicrobial resistance (AMR) is one of the greatest health challenges of our time with serious economic consequences for society globally. The goal of HOTMTAS is to design, implement and assess modular advanced solutions for effective and decentralized wastewater treatment at selected point sources of AMR emergence, such as hospitals and nursing homes.

Hydrosun aims to develop knowledge enabling efficient design and operation of hydro-FPV HyPPs.

This Horizon EU project will identify and develop innovative tools to monitor, map and describe marine organisms, from microbes to mammals and coastal vegetation, across different habitat types in European coastal and marine waters. OBAMA-NEXT will support sustainable marine conservation strategies and policies. Existing and emerging technologies are studied, including satellites, drones, ROVs, drop-video, acoustics, eDNA, and Citizen Sciences.

PAIRWISE aims to advance knowledge of antimicrobial resistance (AMR) as a pollution in aquatic environments, wildlife, and livestock. PAIRWISE focuses on dispersal and dynamics of antibiotic resistant bacteria, antibiotic resistance genes and antibiotics in aquatic environments affected by wastewater treatment plants (WWTP).