June 2018 – October 2019
In the past few years, the Nova Scotia tidal community has augmented its marine operational capacity, but some unknowns and risks still exist and the cost associated with such operations are high.
July 2018 – July 2019
This project has two primary objectives - to characterize the flow and turbulence in the Aquatron facility pool tank using turbulence sensors calibrated against a traceable standard; and to test technologies for investigating the horizontal variability of turbulence in real-world tidal channels.
July 2018 – May 2019
There’s not yet a standardized, optimal way of extracting power from tidal currents. That’s why many tidal industry technologies are currently being tested around the world.
April 2018 – April 2019
Many of the high-flow tidal channels targeted for worldwide in-stream hydro-electric development are impacted by surface gravity waves incident from a large exterior basin (e.g. the Bay of Fundy/Gulf of Maine/North Atlantic).
Optimized Combinations of Tidal, Wind and Solar Electricity Generation with Energy Storage to Meet Nova Scotia’s Electrical Demand
August 2018 – March 2019
Wind, solar and tidal-generated electricity each have different, but potentially complimentary, cyclic times.
October 2018 – March 2019
The research goal was to enhance understanding on sensor performance and sensor-to-sensor interactions to inform environmental effects monitoring (EEM) protocol for future tidal turbine deployments.
Innovative Solutions for De-risking Species Detections in Tidal Energy Environmental Effects Monitoring Programs
April 2018 – March 2019
With collaboration from Genome Atlantic, this research project is using a new environmental DNA technology to rapidly identify and determine abundance of different fish species in high-flow marine conditions. Experiments were conducted at Dalhousie University’s Aquatron facility. N