1. PERD CCIES POL: Current & Temperature Changes along the Newfoundland and Scotian Shelf/Slope Focus: Potential occurrence and impacts of climate changes in ocean currents, transports and temperatures in Atlantic offshore oil and gas production and exploration areas

2. Components: ·Observational studies of Labrador Current in key areas ·Regional ocean circulation models ·Implications of climate-change scenarios for regional circulation and impacts Participants: -Loder, Hannah, Dupont, Geshelin, Yashayaev, Wright et al. (BIO, DFO) -Han, Colbourne et al. (NAFC, DFO)

3. Linkages: -Coordination with OEF POL (1.2.1) and industry co-sponsorships for moored measurements -North Atlantic circulation modelling (BIO/Dalhousie) -DFO Atlantic Zonal Monitoring Program (AZMP) -NW Atlantic ocean climate studies (BIO et al.)

4. Current and Temperature Changes along the Newfoundland/Scotian Shelf/Slope PERD Climate Change Impacts on the Energy Sector (CCIES) POL 6.1.1 Coordination with PERD Offshore Environmental Factors POL 1.2.1 Oil and Gas Industry Partnerships in Observational Components

5. Oil & Gas Exploration and Production on the Scotian Shelf and Slope Labrador Current extension along shelf edge Proximity to energetic Gulf Stream

6. Oil & Gas Exploration and Production on the Grand Bank and in Flemish Pass Severe ocean conditions Iceberg alley (Labrador Current) along shelf edge Persistent Labrador Current in deep-water frontier blocks

7. CCGV Hudson at Hibernia

8. Mean Transports in NW Atlantic Shelf/Slope Labrador Current part of a larger-scale coastal current Large diminution in transport in Grand Bank region Past and potential future variations in equatorward extent of Labrador Current

9. Mean Transports in Grand Bank Region Flow bifurcations north of Flemish Pass, at Tail of Bank, and in Laurentian Channel Variability important to downstream regions

10. Freshwater Transports in NW Atlantic Freshwater and ice from subarctic important to shelf/slope and deep- ocean dynamics in North Atlantic Sea ice and icebergs important to transportation and oil and gas activities

11. Observational Program Elements 1  Multi-Year Cross-Slope Arrays of Moorings at Key Sites on AZMP lines on:  Scotian Slope (Halifax line)  Newfoundland Slope (Flemish Pass line)  Current and hydrographic (T, S) time series  PERD OEF: high-frequency and extreme currents  Industry funding from 7 oil companies

12. Moored Array for Current & Hydrographic Observations on Scotian Slope Current-meter moorings to describe variability in cross- slope structure over 2 years Cooperative with PERD OEF and 7 oil companies

13. Variability in Seasonal Along-Slope Flow from 2000-02 Moored Measurements SWward flow at all depths at 1100- and 2000-m sites until winter 2002 NEward flow in upper 500m at all 3 sites in spring-summer 2002 Seasonal + Interannual variability

14. Observational Program Elements 2  Satellite Altimetric Data (1992- )  Broad-scale surface current patterns & anomalies  Integration with other datasets  Potential for currents/transport monitoring ?  Historical Data  Currents: Moorings, Drifters  Hydrographic (1950- ): T, S, Geostrophic  Coastal Sea Level

15. Variability in Surface Currents from Satellite Altimetry (Han) Averaged seasonal changes over 1992-2000 from TOPEX/Poseidon Interannual variations also under investigation

16. Historical Current Stats in Flemish Pass Means and standard deviations shown by season and depth Limited coverage of seasonal variability and deep water Mean (Labrador Current) generally exceeds fluctuations

17. PERD/Industry Current Meter Moorings in Flemish Pass: 2002-04 Sites and Model Summer Currents Site A (400m): Core of Labrador Current Site B (1100m): Deep Jun-Nov 2002: Recovered Nov02 - Jul03: Deployed Jul03 - Spr04: Proposed Support from EnCana, ChevronTexaco & Petro- Canada

18. Seasonal-Mean Currents in 2002 Climatological seasonal currents from model (contours) (Xu) 2002 seasonal currents from moorings: summer, fall

19. Hydrography and Geostrophic Velocity in Flemish Pass: June 2002

20. Geostrophic Velocity + Bottom Velocity from Climatological Model: June 2002

21. Seasonal Surface Currents from Altimetry Seasonal surface current anomalies from TOPEX/Poseidon (1992-2000), added to LA POP model mean flow Persistent features of Labrador and North Atlantic Currents

22. Surface Current Variability from Altimetry Time variability of currents at cross-over point of TOPEX / POSEIDON tracks Plans to compare with geostrophic and moored measurements, and models

23. Regional Ocean Circulation Modelling  Evaluations of 1985-1998 Simulation from Los Alamos Ocean General Circulation Model (POP) (Smith et al.)  Realistic wind stress but restoration to T, S climatology at boundaries  High spatial (0.1 o ) resolution: quasi-realistic Gulf Stream and eddies  Volume, T and S budgets for Slope Water region  Comparisons of temporal variability with observations

24. Regional Ocean Circulation Modelling 2  Evaluations of Hindcast Simulations with Dalhousie/BIO OGCM (modified POP) (planned with Wright et al.)  Realistic surface forcing and improved interior relaxation from climatology  Intermediate spatial (0.3 o ) resolution but plans to reduce  Focus on variability in Labrador Current extension and Slope Water

25. Regional Ocean Circulation Modelling 3 Variability and Sensitivity Studies with Regional Model for Newfoundland Shelf (FEM) (planned with Han)  Input from larger-scale model for response to extreme wind forcing in 1990s

26. Implications of Climate-Change Scenarios  Implications for current, transport, hydrographic (and ice) variability on Newfoundland and Scotian Shelf/Slope  Labrador Current and Gulf Stream influences  Impacts on shelf-edge production facilities  Impacts on deeper-water (slope) developments  To Date  Literature review  Description and understanding of observed variability  Information transfers to industry

27. Implications of Climate-Change Scenarios  Refined strategy for 03/04  Focus on identification of: forcing-response relations from climate variability studies and potential impacts of climate-change scenarios  Defer regional model simulations for climate change until improved larger-scale models  Prepare report on recent and potential oceanic changes relevant to climate-change impacts assessment for Atlantic oil and gas production areas

28. Summary Points  Moored measurement arrays, plus hydrographic sections and altimetry, providing improved estimates of Labrador Current variability (seasonal, interannual ?) at key sites  Mounting observational support for seasonality and interannual variability in Labrador Current extension beyond Grand Bank, but poorly understood  Improved capability for describing interaction of Labrador Current and Gulf Stream, but remains poorly understood

29. Summary Points 2  Importance of variable atmospheric forcing, ice, freshwater and ocean dynamics  Reliable predictive model for seasonal and interannual variability of Labrador Current not yet available  Assessment of implications of climate change for Atlantic offshore can draw on knowledge of past variability while predictive capability being improved