Research Portal
Displaying 11 – 16 of 16 results
Geoscience » Source Rock & Depositional Environment
Attenuation of Petroleum Generation Characteristics by the Sulfurization of Organic Matter in Westphaflan Carboniferous Lacustrine Source Rocks (A Geochemical Study of Potential Marine Incursions)
October 2017 – May 2019
This project creates geochemical diagnostic tools that can be applied to potential source rocks of differing ages in the Maritimes Basin. These tools help build a more accurate interpretation of the evolution of the basin.
Remote Acoustic Measurements of Turbulence in High-Flow Tidal Channels during High Wave Conditions
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).
Turbine Wake Characterization
November 2017 – March 2019
Turbine wake characterization is a key endeavour to the development of in-stream tidal turbine arrays. In a sense, a turbine’s footprint includes its wake, wherein flow speeds are less and turbulence is elevated compared to the ambient surroundings. It is thus desired to not just delineate wake
Assessment of Hydrodynamic Impacts throughout the Bay of Fundy and Gulf of Maine due to Tidal Energy Extraction by Tidal Lagoons
January 2010 – December 2011
The researchers extended existing hydrodynamic models of tidal flows in the Bay of Fundy to simulate the presence and operation of a tidal lagoon project located in the Minas Basin.
Assessment of the Potential of Tidal Power from Minas Passage and Minas Basin
October 2009 – September 2011
This project estimated the power potential of the tides and tidal currents in the Minas Basin and Minas Channel regions of the Bay of Fundy.
Near Field Effects of Tidal Power Extraction on Extreme Events and Coastline Integrity in the Bay of Fundy
January 2010 – March 2011
Researchers quantified the near-field effects of power extraction on the resulting effects of extreme storm events and coastline integrity by implementing a spectral wave model to numerically simulate wave transformation for tidal current conditions with and without turbines.