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IGCP 565: Hydrogeodesy: The development from 2008 to 2012 . Hans-Peter Plag Nevada Bureau of Mines and Geology and Seismological Laboratory, University of Nevada, Reno, NV, USA, hpplag@unr.edu. Motivation for the IGCP 565 Project:
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IGCP 565: Hydrogeodesy: The development from 2008 to 2012 Hans-Peter Plag Nevada Bureau of Mines and Geology and Seismological Laboratory, University of Nevada, Reno, NV, USA, hpplag@unr.edu.
Motivation for the IGCP 565 Project: - one billion people are currently without sufficient access to clean drinking water; (- Millennium Development Goal for Water will not be reached in Africa;) - according to the 2nd UN Water Assessment Report, this deficit is a result of governance problems and poorly informed decision-making; - demand for water resources is rising due to increased water usage for potable consumption, energy production, irrigation for agriculture purposes, industrial and urban uses, while climate change is locally to regionally impacting water resources through increased frequencies and magnitudes of droughts and floods; - a better understanding of the water cycle on regional to global scales is critical for managing water resources in a sustainable manner; - geodetic techniques capture signals from water moving through the water cycle;
Developing the Global Geodetic Observing System into a Monitoring System for the Global Water CycleObjectives Origin and Intent: • Initiated as an outreach from geodesy to hydrology; • Intended as a framework for the dialogue between hydrology and geodesy. Goals: • Explore and develop components of the geodetic infrastructure most relevant for the monitoring of the water cycle • Make observations and products available for assimilation in predictive models of the global water cycle. • Develop products and algorithms that will allow regional water management to fully utilize the potential of the geodetic techniques for monitoring the regional terrestrial hydrosphere.
Developing the Global Geodetic Observing System into a Monitoring System for the Global Water CycleIGCP 565 Workshops Workshop 1: December 11, 2008, San Francisco: Science of geodetic monitoring of the hydrological cycle Workshop 2: September 30-October 2, 2009, Graz, Austria: Toward a Roadmap for Future Satellite Gravity Missions Workshop 2b: December 12-13, San Francisco, USA: From Satellite Gravity Observations to Products Workshop 3: October 11-13, 2010, Reno, USA: Separating Hydrological and Tectonic Signals in Geodetic Observations Workshop 4: November 21-22, 2011, Johannesburg, South Africa: Integration of geodetic observations and products in models of the hydrological cycle Workshop 5: October 29-30, 2012, Johannesburg, South Africa: Improving regional water management in Africa on the basis of geodetic water cycle monitoring
Workshop 1: December 11, 2008, San Francisco: Science of geodetic monitoring of the hydrological cycle Co-located with GRACE Science Team Meeting: - demonstrated the important contribution of GRACE; - emphasized the need for a GRACE follow-on mission. Workshop Conclusions and Recommendations: - Main gaps in the hydrological budget are (deep) groundwater and evaporation; - Seasonal predictions are an important problem in water management, emphasizing the need for models with predictive capability. - Assimilation of geodetic observations into hydrological models is preferred approach to utilize geodetic observations. - Hybrid approach of local implementation and global observations and models is considered necessary. - Geodetic observations are valuable on all scales. - The best way to get the products to the users is to demonstrate to operational agencies what can be done with geodesy. - It was agreed that the IGCP 565 Project would focus on regional applications in Africa.
Workshop 2: September 30-October 2, 2009, Graz, Austria: Toward a Roadmap for Future Satellite Gravity Mission Feb. 2009: U.S. Decadal Survey “Symposium:” - confirmed importance of a GRACE follow-on mission; Workshop Conclusions and Recommendations: - produced a roadmap towards future gravity satellite missions. - emphasized the importance of these missions for addressing major challenges in our understanding and quantitative knowledge of the water cycle and for the monitoring of the water cycle as it changes under global warming. - This roadmap was later distributed to decision makers and may well have contributed to decisions in the USA and Germany to implement a GRACE follow-on mission much earlier than originally planned.
Workshop 2b: December 12-13, San Francisco, USA: From Satellite Gravity Observations to Products Workshop 2 Road Map and Declaration distributed at the Plenary of the Group on Earth Observations (GEO), November 2009, Washington, D.C. Review of the first two years of the IGCP 565 Project: - Workshops illustrated the potential of the geodetic observations for hydrological applications; - Underlined the importance of continued satellite gravity missions; - Identified lack of well validated and quality controlled geodetic products easily applied by hydrologists Challenges: - providing a platform for a better communication of hydrological and geodetic communities, - better integration of the project into the frame of other relevant programs, such as GEO, IGWCO, GEWEX, and UNESCO/IHP. - Progress towards applicable products for those who can put them to best use.
Workshop 3: October 11-13, 2010, Reno, USA: Separating Hydrological and Tectonic Signals in Geodetic Observations Objective: Make progress towards improved applicability of geodetic observations for hydrological and global change studies Workshop Conclusions and Recommendations: - Geodetic observations require integrated analysis and modeling - The two primary recommendations of the 3rd workshop are: (1) Capacity building with application of geodetic products that water resource decision makers are able to readily access and easily use, and (2) development of a demonstration project in California that merges geodetic information with hydrologic modeling via assimilation and leads to realistic technology transfer to African nations through a similar project in the Nile Basin. - Many other conclusions and recommendations
Workshop 4: November 21-22, 2011, Johannesburg, South Africa: Integration of geodetic observations and products in models of the hydrological cycle Workshop Goals: • progress towards low-latency hydrogeodetic products for regional water management applications; • Develop projects to improve information on water resources particularly in Africa; and to support their sustainable management; • entrain new users of hydrogeodetic applications, techniques, and training for improved water resource decision-making in Africa.
Workshop 4: November 21-22, 2011, Johannesburg, South Africa: Integration of geodetic observations and products in models of the hydrological cycle Workshop Conclusions and Recommendations: • Africa is a "hot spot" in terms of water issues impacting all socioeconomic sectors, health, and food security; • Research on effects of climate variability on key reservoirs is limited; • There is a lack of long enough observed time series for fundamental variables; • Hydrogeodesy represents a new and fundamental approach for monitoring changes in land water storage; • Predictive terrestrial water storage models for Africa require full integration of geodetic observations; • Limited data access, challenges in use of products, and the absence of a workbench hampers application of hydrogeodesy to regional water management; • Synergies between the many water-related activities are not fully exploited.
Workshop 5: October 29-30, 2012, Johannesburg, South Africa: Improving regional water management in Africa on the basis of geodetic water cycle monitoring Workshop Goals: • Review the challenges for water security in Africa; • Identify the role of hydrogeodesy in addressing these challenges; • Explore synergies between the various programs addressing water security; • Foster linkages between research and water management.
Hydrogeodesy Progress 2003: GRACE; unprecedented observations of the regional to global water cycle Since 2003: progress in joint analysis of gravity, geometry and rotation observations Since 2004: InSAR demonstrates potential for monitoring groundwater variations Since 2005: Soil molisture and snow depth from GPS multipath Since 2005: Satellite altimetry for rivers and lakes improving 2009: GRACE-based discoveries: Groundwater depletion in Northern India; melting of ice sheets 2010: Progress towards community products, but no joint products available 2011: GPS time series available with low latency for order 10,000 stations. 2012: Portal for GPS-derived water cycle products
River Basin Hydrology Status Hydrogeodesy enables closure of monthly water balance at for large river basins Run-off and evapotranspiration are still very uncertain This leads to uncertainties in groundwater storage
Science Issues Observations: River run-off and evapotranspiration Modeling: The development of an integrated dynamic model for the prediction of geodetic signals due to daily to interannual surface mass changes. Analysis: Inversion algorithms for combined geodetic observations for surface mass changes. Water Management support: Development of products relevant for regional water management. Predictions: Assimilation of the observations in integrated predictive models of the hydrological cycle.