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Towards a Community Workbench for Hydrogeodesy

Towards a Community Workbench for Hydrogeodesy. Hans-Peter Plag Nevada Bureau of Mines and Geology and Seismological Laboratory, University of Nevada, Reno, NV, USA, hpplag@unr.edu. Towards a Community Workbench for Hydrogeodesy. - How and What are we Observing?

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Towards a Community Workbench for Hydrogeodesy

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  1. Towards a Community Workbench for Hydrogeodesy Hans-Peter Plag Nevada Bureau of Mines and Geology and Seismological Laboratory, University of Nevada, Reno, NV, USA, hpplag@unr.edu.

  2. Towards a Community Workbench for Hydrogeodesy - How and What are we Observing? - Case Study: Sierra Nevada Uplift - What Others do - Towards a Workbench for Geodesy

  3. How and What are we Observing? Geodetic observation techniques capture signals of many processes overlapping in spatial and temporal scales. Modified from Ilk et al. (2005).

  4. How and What are we Observing? Time-variability in the “three pillars of geodesy” is observed with a portfolio of geodetic techniques: - point-geodetic methods, - surface imaging techniques for land, ice and ocean surfaces, - emerging reflectometry, - in situ and space-borne gravity sensors. All techniques capture signals of the same, unique Earth system but have different sensitivities in terms of spatial and temporal scales. Many physical processes in the Earth system impact geodetic observations on wide and overlapping ranges of spatial and temporal scales. In many studies, focus is on one process, with all other processes being “noise” that needs to be removed.

  5. How and What are we Observing? THE “CURSE” OF INCREASING ACCURACY: EVERYTHING MATTERS The (rapidly improving) accuracy of the geodetic observations increasingly requires an interdisciplinary integrated Earth system approach to the analysis of the observations. The fundamental link between the different observations – the Earth system producing the signals - is not yet widely explored in geodesy. Even within one of the pillars, focus is often on one aspect of the Earth system (a tectonic process, atmospheric loading, ocean loading, hydrological loading, ...) Challenge to small research groups: - integrated use of multiple geodetic techniques - wide range of expertise in system modeling

  6. Are we as a community exploiting the full potential of the rich, accurate, comprehensive, and complementary geodetic observations in the three pillars?

  7. CASE STUDY: SIERRA NEVADA UPLIFT

  8. CASE STUDY: SIERRA NEVADA UPLIFT Hammond et al, 2012: Present-day uplift of Sierra Nevada: 1 to 2 mm/yr Potential causes for the uplift: • tectonic uplift: 3 km over 3 to 60 Million years; • postglacial rebound due the last ice age (far-field): order 1 mm/yr but with large spatial scales; • postglacial rebound after increased glaciation during the Little Ice Age: order of 0.3 mm/yr; with North to South increase; • elastic response to present-day changes in land water storage: order of 1 mm/yr if large groundwater changes; • elastic response to changes in atmospheric and ocean loading.

  9. CASE STUDY: SIERRA NEVADA UPLIFT Hammond et al, 2012: Present-day uplift of Sierra Nevada: 1 to 2 mm/yr Modeling the contributions to the observed uplift requires: • tectonic model, including crustal structure and visco-elastic properties; • postglacial rebound models, far-field contributions; • ice history for the last 500 years; • visco-elastic model for recent ice load changes (transient rheology); • land water storage changes over the observation period; • elastic model to predict the loading signals; • atmosphere and ocean loading predictions;

  10. Results of joint analyses, joint inversions, and model studies indicate that there is a considerable potential of geodetic observations to constrain Earth system models.

  11. WHAT OTHERS DO

  12. WHAT OTHERS DO The solid Earth in Earth System models: Many “Earth system models”: the solid Earth serves as a rigid lower boundary. Challenge to integrate a dynamic solid Earth into these models. Alternative approach based on physical Earth system models?

  13. Should we create a community modeling framework that would facilitate the joint analysis and interpretation of geodetic observations?

  14. TOWARDS A WORKBENCH FOR GEODESY A comprehensive geodesy workbench would: • serve the broad geodetic community • support the integration of the three pillars of geodesy. The workbench could be developed following the example of other community-based modeling frameworks: • Community Surface Dynamics Modeling System (CSDMS), • Global Earthquake Model (GEM), • emerging community ice model systems (Lipscomb et al., 2009).

  15. TOWARDS A WORKBENCH FOR GEODESY

  16. TOWARDS A WORKBENCH FOR GEODESY A comprehensive geodesy workbench would: • serve the broad geodetic community • support the integration of the three pillars of geodesy. The workbench could be developed following the example of other community-based modeling frameworks: • Community Surface Dynamics Modeling System (CSDMS), • Global Earthquake Model (GEM), • emerging community ice model systems (Lipscomb et al., 2009). Workbench would constitute a cyber infrastructure: • globally available with global participation • building the tools, ensuring appropriate standardization and interoperability.

  17. TOWARDS A WORKBENCH FOR GEODESY Components and Benefits of a community-built, web-based (virtual) workbench for geodesy include: Components: • data archive(s) for observations in the three pillars; • data analysis tools (software); • data analysis results (time series, grids, ...); • integrated modeling software; • model predictions. Benefits: • standardization, interoperability, data assimilation; • joint analyses in an interdisciplinary context; • support local and regional studies, access to expertise; • framework for community products; • global availability (capacity building); • significant impact on education.

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