Geoscience » Play Fairway Analyses Atlases 2010–Present
November 2018 – June 2019
Shortly after the Scotian Shelf and Slope Play Fairway Analysis (PFA) was released in 2011, Shell Canada acquired six exploration parcels in the Shelburne Subbasin and collected approximately 10,850 square kilometers of wide azimuth 3D seismic data.
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.
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.
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
April – November 2018
The study investigates the feasibility of developing a generic, shared-use, multi-function turbine transport deployment and retrieval barge/drydock for use by the Nova Scotia tidal energy sector.
Using Radar to Evaluate Seabird Abundance and Habitat Use at the Fundy Ocean Research Center for Energy Site near Parrsboro, Nova Scotia
April – September 2018
Shore-based seabird surveys conducted at the Fundy Ocean Research Center for Energy (FORCE) in Parrsboro, NS, determine abundance, habitat use and potential risk to seabirds at the site.
March – June 2018
This study investigates two Nova Scotia “dry ports” and their potential in supporting the Bay of Fundy region’s emergent tidal energy industry. The term ‘dry port’ refers to a port where the harbour bottom is mainly exposed at low tide.