Cloud Seeding in the Walker River Basin Arlen Huggins Desert Research Institute

1. Cloud Seeding in the Walker River BasinArlen HugginsDesert Research Institute • Scientific basis for wintertime cloud seeding • Determining the potential for increased snowfall • Seeding methods and materials • Detecting the impact of cloud seeding • Current activities in the Walker Basin • Future directions

2. Cloud Seeding: A Brief History • Cold Box Experiments: 1940’s • Operational Projects: 1950’s to present • Research Projects • Field Studies (1960’s - 1990’s) • Statistical Experiments (1960’s and 1970’s) • Proof of Concept Experiments (1980’s-1990’s) • New Evaluation Techniques (1980’s - ?)

3. Current Wintertime Seeding Projects

4. Concepts for Cold Cloud Seeding • Winter clouds contain some water that has not been converted to ice crystals and snow • Amount of supercooled liquid determines seeding potential • Ice forming particles (nuclei) required to produce ice • Natural ice “nuclei” are less numerous at warmer temperatures • Artificial seeding either adds more ice nuclei or reduces the temperature so ice can form • Seeded ice crystals grow and fall as snow

5. Sizes of Cloud Water and Ice Particles 1 mm

6. The Potential for Cloud Seeding • Storm Frequency and Duration • The Amount of Supercooled Liquid Water in a Storm • Targeting Considerations

7. Seasonal Precipitation

8. Supercooled Liquid WaterRemotely Sensed Microwave Radiometer Measures Cloud Liquid Depth and Water Vapor Depth

9. Supercooled Liquid Water: Integrated Effect

10. Conceptual Model for Cloud Seeding Seeding Generator

11. Modeling to Evaluate Generator LocationsSeeding Simulation: Time = 1700 2/14/94

12. Modeling: Plume after 30 minutes

13. Modeling: Plume after 1.5 hours

14. Modeling: Plume after 7 hours

15. Aircraft Cloud Seeding AgI Flares in Aircraft Flare Rack AgI Solution Burners Nighttime Flare Test Dry Ice from an Aircraft Hopper

16. Ground-based Cloud Seeding DRI Remotely-controlled cloud seeding generators. Left: Mobile Unit Above: Semi-permanent Unit

17. Generator Ice Crystal Production

18. Detecting the Effects of Cloud Seeding1. Statistical Methods California 1969: AgI Seeding 0.1 mm/h Colorado 1971: AgI Seeding 0.1-0.7 mm/h Montana 1986: AgI Seeding 0.3 mm/h

19. Detecting the Effects of Cloud Seeding2. Direct Observation Washington 1975: AgI/CO2 0.15 - 0.9 mm/h Nevada 1987: CO2 0.1 - 0.6 mm/h Montana 1988: AgI 0.05 - 0.2 mm/h Colorado 1988: AgI 0.1 mm/h California 1988: AgI/CO2 0.3 - 1.0 mm/h Utah 1994: AgI 0.5 - 1.5 mm/h 0.25 mm/h = 0.01 in/hr Over 35 sq. miles: Seeding effect = 18.7 acre-feet/hour For 8 storm hours = 149.6 acre-feet For 20 storms = 2992 acre-feet

20. Seeding Effects: Detection Methods Aircraft or Vehicle-mounted Particle Probes

21. Seeding Effects: Detection Methods Short-wavelength Radar Snow profiling for chemical analysis

22. Seeding Effects: Some Results Seeded Period A 1-hour AgI Seeding Experiment in Utah

23. Seeding Effects: The Aerosol Plume

24. Seeding Effects: A Radar Plume

25. Seeding Effects: Precipitation Data

26. Walker Basin Seeding Program 6 ground-based generators for 2001-02 8-9 generators by 2002-03 Aircraft Seeding over Sierra Nevada

27. Future Directions • Detailed Sub-basin Evaluation of Seeding Opportunities and Impacts • SLW climatology from radiometer data • Snow Core and Chemical Analysis of Snowpack • Modeling Study to Evaluate Future Ground Generator Locations • Emphasis on targeting high SLW regions • Generator network expansion • Observation/Modeling Study to Evaluate Runoff Impacts