Western Washington University Western CEDAR Salish Sea Ecosystem Conference 2014 Salish Sea Ecosystem Conference (Seattle, Wash.) Apr 30th, 1:30 PM - 3:00 PM Future climate impacts on Puget Sound oceanography: the North Pacific and hydrological context Neil Banas University of Washington, neil@ocean.washington.edu Follow this and additional works at: https://cedar.wwu.edu/ssec Part of the Terrestrial and Aquatic Ecology Commons Banas, Neil, "Future climate impacts on Puget Sound oceanography: the North Pacific and hydrological context" (2014). Salish Sea Ecosystem Conference. 47. https://cedar.wwu.edu/ssec/2014ssec/day1/47 This Event is brought to you for free and open access by the Conferences and Events at Western CEDAR. It has been accepted for inclusion in Salish Sea Ecosystem Conference by an authorized administrator of Western CEDAR. For more information, please contact westerncedar@wwu.edu.
What do we know about how the Salish Sea fits into a changing earth system? Atmospheric, hydrological, and oceanic pathways Neil Banas Joint Institute for the Study of the Atmosphere and Ocean (JISAO) Univ of Washington many thanks to Parker MacCready Barbara Hickey Samantha Siedlecki Kristen Davis and the rest of the UW Coastal Modeling Group Manu Di Lorenzo Curtis Deutsch Salish Sea Ecosystem Conference April 2014
Direct atmospheric effects River inputs Ocean inputs
Global warming causes local warming (Banas and Salathé) Warmer surface temperatures are likely to widen the seasonal window of opportunity for Alexandrium HABs by 1-2 months: see talk by Stephanie Moore, Fri at 11:45, session S-9A
Wind mixing and cloudiness also affect the timing of phytoplankton blooms Model hindcast of spring bloom date in the Strait of Georgia (Allen and Wolfe, Prog. Oceanogr., 2013): climate-linked trend toward increased variance We need to learn more about how extreme weather events are changing, not just seasonal averages
Direct atmospheric effects River inputs Ocean inputs
Single largest contributor of freshwater 48.8 Winter Nooksack BELLINGHAM BAY Late summer SAMISH BAY 48.4 Fraser Skagit Fraser Skagit 48 47.6 47.2 HOOD CANAL Skokomish Deschutes Nisqually SOUTH SOUND M A I N B A S I N Puyallup Snohomish Skokomish Fraser Any given corner of Puget Sound is influenced by climate and hydrology in quite distant watersheds (Note: river-borne fecal coliform and DIN loads are are much more localized, because of decay/utilization rates.) (Banas et al., Estuaries and Coasts, in revision) 123 122.6 122.2 123 122.6 122.2
The most significant climate-linked trend in riverflow (both observed and predicted) is a shift in timing 15000 Columbia Columbia present Fraser present Columbia 2040s Fraser 2040s Columbia: Elsner et al., 2010 Naturalized flow (m3/s) 10000 5000 2040s projection: higher winter flows... Fraser: Shrestha, Schnorbus, and Werner (PCIC, UVic) Puget Sound: Cuo et al. 2011... and lower summer flows Fraser 0 0 50 100 150 200 250 300 350 Yearday See Snover et al. 2013 (UW Climate Impacts Group)
Summary so far We understand the physics of pathways linking the Salish Sea to global climate via atmospheric and hydrological pathways pretty well. The biggest uncertainty is ecological dynamics. We should pay particular attention to phenology: timing of mixing and stratification timing of spring phytoplankton blooms interaction with zooplankton and fish life histories
Direct atmospheric effects River inputs Ocean inputs
Poleward Undercurrent (the deep sourcewater for the Salish Sea and coastal zone) Wind-, river-, and tide-driven circulation all pull water from the Poleward Undercurrent into the Strait of Juan de Fuca: the source of 80 95% of the Salish Sea s nutrients (Mackas and Harrison 1997, Hickey and Banas 2008, Mohamedali et al. 2011) open ocean surface-layer wind-driven upwelling slope W A S H I N G T O N shelf estuarine exchange flow Strait of Juan de Fuca (the typical summer condition, BC to Baja) land
What is the source of our sourcewater? Modeled particle tracks leading to 200 500 m water depth on the mid-washington coast, 2002 09 tracks leading to 200 500 m depth in <1000 m of water, 47 47.5 N, 2002 2009 origin of water found at 200 500 m, 47 47.5N, monthly averages 1 north offshore south 0.8 0.6 0.4 0.2 0 2002 2003 2004 2005 2006 2007 2008 2009 2010
Climate-driven variations in the southern (equatorial) source Thermocline N deficit high O2 low NO3 Anoxic low O2 / high NO3 Southern CA Oxygen anomaly (C. Deutsch, UW: see Deutsch et al., Science, 2011)
Sourcewater chemistry anomalies from the subarctic N Pacific 12 years prior 6 years prior 0 years prior Salinity-based proxy for oxygen anomalies in a multi-decadal hindcast model (E. Di Lorenzo et al., Georgia Tech)
Summary part 2 Circulation trends in the subarctic Pacific, biogeochemical trends in the tropical Pacific, and a variety of processes in the local upwelling zone are all likely to be important determinants of Salish Sea sourcewater chemistry. Uncertainty in these trends is large except for ocean acidification. Some of the uncertainty will be unresolvable until/unless global projections come into agreement. Some of it is simply a matter of research effort and cross-scale coordination.