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Environmental Geodesy

Environmental Geodesy. Lecture 11 (April 4, 2011): Loading - Predicting loading signals - Atmospheric loading - Ocean tidal loading - Non-tidal ocean loading - Hydrological loading - Cryospheric loading - Summary. Predicting Loading Signals. Precision of observations versus

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Environmental Geodesy

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  1. Environmental Geodesy Lecture 11 (April 4, 2011): Loading - Predicting loading signals - Atmospheric loading - Ocean tidal loading - Non-tidal ocean loading - Hydrological loading - Cryospheric loading - Summary

  2. Predicting Loading Signals Precision of observations versus Precision of model predictions • Observations: • For example: • 3-D surface displacements or deformation from geodetic measurements; • gravity changes from absolute and superconducting gravimeters; • gravity variations from satellite missions. Time scales from less than 1 hour up to decades • Model predictions: • Based on: • theory (continuum mechanics); • Earth model; • surface loads.

  3. Predicting Loading Signals Surface LoadingModel predictionsBased on: - theory (continuum mechanics) - Earth model - surface loads

  4. Predicting Loading Signals Model predictions: Mostly used: Green's function approach (boundary value problem) Basic assumption concerning the load: thin mass distribution • Widely used earth model: • spherically symmetric, non-rotating, elastic, isotrop (SNREI) • elastic parameters: Preliminary Reference Earth Model (PREM) Advantage of SNREI: Green's function depends only on angular distance between load and observer. Problems: • boundary undulations (e.g., surface topography, core-mantel boundary); • lateral heterogeneities (density, bulk modulus, shear modulus); • global ocean; • elastic (up to what time scale?).

  5. Predicting Loading Signals Depending on the Earth model, we get the following classes of Green's functions:

  6. Predicting Loading Signals Green's Functions for SNREI Earth Models: Computation of Love Numbers for Spherically symmetric, non rotating, elastic, isotrop models (SNREI): - PREM or ? - PREM: surface layer: 3 km ocean - PREM: frequency-dependent shear modulus: elastic module? - PREM: parameterization of depth- dependency

  7. Predicting Loading Signals Plag et al. (1998) proposed to use surface loading to constrain Earth models Blewitt et al., (2005) proposed to use surface loading to constrain surface mass redistribution (in particular hydrological mass). Depends on sensitivity to Earth model, mass, and theoretical approximations. We will look at: - Earth model; - loads

  8. Predicting Loading Signals Earth models: lateral heterogeneities Now at: http://igppweb.ucsd.edu/~gabi/crust2.html

  9. Predicting Loading Signals Earth models: lateral heterogeneities http://igppweb.ucsd.edu/~gabi/sediment.html

  10. Predicting Loading Signals Earth models: lateral heterogeneities http://igppweb.ucsd.edu/~gabi/rem.dir/rem.home.html: Towards a 3D Reference Earth Model Five high-resolution mantel models available: - Masters et al. (SIO) - Dziewonski et al. (HRV) - Romanowicz et al. (Berkeley) - Grand (UT Austin) - Ritsema et al (Caltech)

  11. Predicting Loading Signals Earth models: lateral heterogeneities

  12. Predicting Loading Signals Earth models: lateral heterogeneities

  13. Predicting Loading Signals Earth models: lateral heterogeneities Status: - SNREI most likely not sufficient; - 3-D Earth modes are developing, transition from PREM (SNREI) to REM (3-D) seems feasible; - But: still considerable difference between existing 3-D models. Not discussed: - anisotropy; - non-hydrostatic pre-stress; - thin-load assumption.

  14. Surface loads Relevant surface loads: - atmospheric loading; - ocean loading (tidal and non-tidal); - continental water storage (lakes, rivers, soil moisture, groundwater, reservoirs); - land-based ice masses (glaciers, ice caps, and ice sheets); - man-made mass relocation (mining, etc.) Data sets: - atmosphere: global surface pressure, 6 hours; ocean response? - tidal ocean: ocean tide models; - non-tidal ocean: circulation models (e.g., 6 hours), satellite altimetry (e.g., 10 days); - continental water storage: observations and models - ice: global data bases

  15. Atmospheric loading ECMWF-NCEP Difference between model orography and surface topography ETOPO5 versus NCEPResolution: 2.5 x 2.5 degrees ETOPO5 NCEP ref. surf. ECMWF ref. surf. NCEP ETOPO5-NCEP

  16. Atmospheric loading Steps to compute atmospheric loading signal: - pressure field at topography: geopotential heights - anomaly: reference pressure field - convolution with Green's function SLP PAN REP UP SUP

  17. Atmospheric loading ECMWF-NCEP Difference between air pressure data sets Reference surfaces for air pressureECMWF: Pressure at sea surfaceNCEP: Pressure at model orography(?) heightComparison: at topographic heightResolution: 2.5 x 2.5 degrees ECMWF ref. surf. NCEP ref. surf.

  18. Atmospheric loading Daily Weekly Range of Pressure anomaly Mean mbar Std Maximum

  19. Atmospheric loading Decadal variability of Surface Pressure 1980-1989 1960-1969 1990-1999 1970-1979 Differences between Decadal Mean and Long-term Mean Range: -4 to 4 mbar Left: Mean 1958 - 2002

  20. Atmospheric loading Atmospheric loading Range:-12 to 12 mmTime:2000.0 to 2004.o

  21. Ocean Tidal Loading Atmospheric loading - Load depends on frequency - Standard approach: - use a (low) number of tidal constituents; GIPSY: M2, S2, N2, K2, K1, O1, P1, Q1, MF, MM, SSA. - compute station-dependent loading coefficients for each constituent - available at http://froste.oso.chalmers.se/loading// - Problems: - many different ocean tide models; still considerable inter-model differences; - Incomplete representation of harmonic potential; - In some areas, shallow-water constituents not considered.

  22. Ocean Tidal Loading Atmospheric loading (m) Le Provost Schwiderski Radial Displacement for M2 Tide in the Icelandic Sea

  23. Non-Tidal Ocean Loading Atmospheric loading - Load (mass distribution and ocean bottom pressure) needs to be modeled; - Standard approach: - use ocean circulation model output; IERS products: * Global OAM mass and motion terms (c20010701) * Global OAM mass and motion terms (ECCO_50yr) * Global OAM mass and motion terms (ECCO_kf049f) * Global OAM mass and motion terms (Johnson 2001) * Global OAM mass and motion terms (Ponte 1998) * Measurements of ocean bottom pressure (GLOUP) * Model for ocean bottom pressure (ECCO) * Model for oceanic center-of-mass (c20010701) * Model for oceanic center-of-mass (Dong MICOM 1997) * Model for oceanic center-of-mass (Dong MOM 1997) * Model for oceanic center-of-mass (ECCO_50yr) * Model for oceanic center-of-mass (ECCO_kf049f) - Problems: - many different models; still considerable inter-model differences; - mass conservation (due to Bousinesque approximation) - large latency.

  24. Hydrological Loading Atmospheric loading - Load is a result of complex processes with different spatial and temporal scales; - Standard approach: - use output of land water storage models; IERS Geophysical Fluids: * Continental water flux data (monthly) * Continental water storage data (monthly) * Hydrological Excitations of EOP Variations (daily) * List of Global Major Artificial Reservoirs * Water Storage Change from Grace (monthly) * Water Storage Data from CPC (monthly) * Water Storage Data from ECMWF (daily) * Water Storage Data from GLDAS (daily) * Water Storage Data from NCEP/NCAR (daily) - Problems: - large inter-model differences; - data with large latencies;

  25. Hydrological Loading Atmospheric loading JPL MASCON, secular trends 2003-2007, Watkins, 2008

  26. Cryospheric Loading Atmospheric loading - Load history is important because of large changes in the past: postglacial rebound and response to current changes - Standard approach: - separate post-glacial and current changes; - post-glacial: geophysical models; - current changes: mass balance from satellite altimetry, GRACE, in situ observations, models; - Problems: - PGR models are uncertain due to rheology, lateral heterogeneities, rotational effects, ice history - errors in PGR map into errors in current mass changes; - conversion of ice surface elevation changes into mass changes.

  27. Cryospheric Loading Atmospheric loading - Accelerated ice melt is a problem for the reference frame

  28. Cryospheric Loading Atmospheric loading Post-glacial rebound; example sea level changes Method: Extrapolation of predicted present-day signal in sea level; Mean of many predictions Example: 14 different predictions Signal: -10 to 5 mm/yr Uncertainty from standard deviation: Max. ± 1.2 mm/yr, relative: ~15% Mean of 14 models STD

  29. Cryospheric Loading Atmospheric loading

  30. Summary Many studies aiming at validation of predictions of surface loading signals in space-geodetic observations. General conclusion: some improvement of the RMS at some sites, but also considerable disagreement between model predictions and observations. Potential sources of disagreement: - lateral heterogeneities in the Earth model not taken into account; - errors in GPS estimates of tropospheric delay, i.e., loading signal partly absorbed by estimated delays; - errors/uncertainties in surface loads/pressure: - for air pressure, deviations of the ocean response to atmospheric forcing from Inverted Barometer (IB); - air pressure at high latitudes; - non-tidal ocean loading: mass conservation of ocean models; - land water storage: soil moisture and groundwater changes; - ice loads: separation of signals from past and current mass changes. - annual signals in time series of station heights due to other processes than loading.

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