1 / 29

Hydrologic trends in the West

Hydrologic trends in the West. Philip Mote Climate Impacts Group University of Washington. Alan Hamlet, Martyn Clark, Dennis Lettenmaier With thanks to Dave Hart, Jon Lea, Greg Johnson, Randy Julander, Scott Pattee. ftp://ftp.atmos.washington.edu/philip/SNOWPAPER/.

Sophia
Download Presentation

Hydrologic trends in the West

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Hydrologic trends in the West Philip Mote Climate Impacts Group University of Washington Alan Hamlet, Martyn Clark, Dennis Lettenmaier With thanks to Dave Hart, Jon Lea, Greg Johnson, Randy Julander, Scott Pattee ftp://ftp.atmos.washington.edu/philip/SNOWPAPER/

  2. The Columbia Basin’s snow in a warming world 20th c. 2020s 2040s April 1 snow water equivalent (mm)

  3. Snake River at Ice Harbor

  4. This talk • Significant hydrologic changes will occur for 2-4°F warming • The Northwest has already seen 1.5°F warming in the 20th century • Have hydrologic changes been observed? • Are they consistent with the warming and the model projections?

  5. decrease increase Data from NRCS, CA DWR, BC SRM 824 snow courses/SNOTEL Trends in April 1 SWE, 1950-2000 Relative to 1950 value 73% – trends Large – trends PNW Some + trends SW

  6. VIC simulation • 1/8° long x 1/8° lat, west of Continental Divide • Daily weather data, 1/1/1915 - 9/30/97 interpolated to VIC grid points from Coop stations • Long-term trends interpolated from USHCN stations

  7. Relative trends 1950-1997

  8. Trends in timing of peak snowpack Figure by Alan Hamlet, UW Change in Date

  9. Western Cordillera trends in Apr SWE/Mar SWE

  10. 1950-1997 relative trends vs DJF temperature Obs VIC

  11. Regional average April 1 SWE Obs o VIC x

  12. Relating SWE to climate data • US Historical Climate Network (USHCN) • Use nearest 5 stations to form reference time series T(t) and P(t) • Correlation between Apr 1 SWE and T or P • Regression: SWE(t)=aTT(t) + aPP(t)+(t) • Components of trend aT<T> and aP<P>

  13. Correlations between Nov-Mar climate and Apr 1 SWE X-direction: precip Y-direction: temp Coldest locations insensitive to temperature Cascades very sensitive

  14. April 1 SWE trends, 1950-2002 aT<T> aP<P>

  15. aP<P> + aT<T>

  16. Changes in SWE vs changes in precip

  17. Trends in timing of spring snowmelt (1948-2000) +20d later –20d earlier Courtesy of Mike Dettinger, Iris Stewart, Dan Cayan

  18. As the West warms, winter flows rise and summer flows drop Figure by Iris Stewart, Scripps Inst. of Oceanog. (UC San Diego)

  19. Conclusions • Observations show substantial declines in western snowpack, corresponding changes in flow • Largely temperature-driven • Cascades, N. Calif most temp-sensitive • Large increases in precipitation have offset warming in some places • Warming trends very likely to continue ftp://ftp.atmos.washington.edu/philip/SNOWPAPER/

  20. April 1 SWE trends, 1930-2002 aP<P> aT<T>

  21. SNOTEL data: cold-season melt events vs Apr 1 SWE

  22. At almost every USHCN station, winters warmed + signs: warming but not statistically significant

  23. Winters wetter in much of the West Drier in some of Northwest (PDO)

  24. Declining snowpack in the Cascades From the VIC simulation

More Related