1. McMurdo Dry Valley streams: Ecosystems Waiting for Water MCMLTER: PI-Lyons, Co-PI’s- Doran, Fountain, McKnight, Moorhead, Priscu,Virginia,Wall

4. McMurdo Dry Valleys, Antarctica Polar desert: Dry (<10 cm precip. Annually) Cold (average air temp. = -20 o C) –Meltwater streams flow for 6 to 14 weeks –Streamflow is typically 0.01 to 5 cfs, stream water temperature is typically 0.1 to 14 o C –Hyporheic zone is a key hydrologic feature –Habitat for benthic algae mats –Source and control of solute input to the lakes

5. Glacial meltwater streams:climatic connection between the glaciers and the lakes

6. Monitoring of streamflow and stream ecosystems Network of 19 stream gauges in Taylor and Wright Valleys-continuous (15 min) Collaboration between NSF and USGS Network of 18 transects to document ecological response to changing flow

7. USGS hydrologist gauging Onyx River

8. Creek Canada Glacier Commonwealth Glacier Crescent Glacier Howard Glacier Green Delta Stream Harnish Stream Von Guerard Stream Aiken Creek Huey Canada Creek Stream St r e a m S e a l L o s t McKnight Creek C r e s c e n t S t r e a m N 2 km Relict Channel

9. MCMLTER gauging stations Challenge-range of flows and unstable substrate Parshall flumes with weirs in cutoff wall- compound rating Natural channel controls Located at outlets to lake Temporary sites near glaciers

10. Parshall flume used to obtain accurate discharge at low flow

11. Maintenance of gauges to maintain record Green Creek gauge moved due to lake level rise Santa Fe gauge pummeled by 100 cfs (cubic feet/sec)

12. Fryxell basin: streamflow greater during 89-92 than during 93-present

13. Wright Valley: Onyx River flow has also been lower since 93

14. Bonney basin: high streamflow from Taylor Glacier since 1993

15. Santa Fe Creek on 12/21/00: 35 cfs

16. Filamentous cyanobacteria (blue- green algae): orange algal mats

17. Black algal mats at stream edge: intermittent flow

19. Orange algal mats in Von Guerard Stream: 10-14 species in each sample

20. Black algal mats in Von Guerard Stream: 1-2 species in each sample

21. Streams with stable habitat had few changes

22. Some streams with poor habitat had more abundant mats

23. Hyporheic zone: under and adjacent to stream with active exchange of water Permafrost  Active Layer

24. In dry valley streams the “hyporheic zone” is observed as a wetted zone adjacent to stream

25. Dry valley streams flow through porous alluvium with high rates of “hyporheic exchange”.

27. In cold summers, glacial meltwater soaks in and sublimates in fall and winter.

28. Stream scale experiments to quantify biogeochemical processes Short term experimental perturbations to quantify nutrient uptake and hydrology Long term experiment studying ecological response to geomorphological evolution of stream networks Experiments reviewed through environmental assessment process

29. Experimental enrichment with nitrate and phosphate: 1.5 hrs

30. Sampling Green Creek during experiment

31. Stream algal mats win! Added nutrients are taken up and do not reach the lake.

32. In cold summers, streams retain water and nutrients, lakes fend for themselves.

33. Stream channel that had been inactive was “reactivated” by directing water to channel with low sandbag wall

35. Algal mats in reactivated relict channel are most productive mats is Taylor Valley

36. Photosynthesis measured as rate of oxygen production by mat samples

37. Higher nutrients in relict channel water enhances growth

38. An axiom of ecology is: “Where there is water, there is life.” In Dry Valleys: “Where there has been and will be water, there is life.” Dry valley stream ecosystems can withstand cold, desiccation annually and for longer periods, as long as decades or centuries.

39. The Stream Team gratefully acknowledges logistical support provided by PHI, ASA and Raytheon, and field assistance from other MCMLTER investigators