Atmospheric and oceanic excitation of the polar motion and length of day

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Atmospheric and oceanic excitation of the polar motion and length of day

EXCITATION OF THE POLAR MOTION AND ROTATION RATE

updated : January 2023 Inverted barameter (IB) Non IB (for NCEP only) Date for graphics: Year MJD Civil date Comparison of observed excitation with : Matter + motion terms Matter term motion term Atmosphere Oceans Continental water Sea level Plots and correlation Graphic dimension: X label : English French
Plot and correlate χ_GEOD and χ_GEOPH	Plot differences χ_GEOD-χ_GEOPH	Plot χ_GEOPH
x components (along Greenwhich) y components (90°E) Excess of length-of-day (z) 2D x/y equatorial components
Apply Vondrak frequency filter Remove parabolic trend (P₀) year Transfer coefficient for P₀: T₀= The Vondrak filter transfer function at another period P is given by : T=1/(1+(P₀/P)⁶ (1-T₀)/T₀) For the case "Select band below" the selected period is transfered with a rate of (100-T₀) Spectral analysis (FFT, complex for 2D signal) Amplitude PSD Moving average over min. frequency max. frequency (in cycle per time unit) x/y Log scale x (along Greenwhich) y (90° E) z (axial) 2D x - i y Geodetic Geophysical Geophysical - Geodetic Produce data file : x/y/z components of the Geodetic (χ_GEOD) and Geophysical excitations (χ_GEOPH) functions (not filtered) x/y/z components χ_GEOD - χ_GEOPH

Chandler period : days Chandler quality factor :	Starting date : year month day Ending date : year month day
Coefficients of the effective angular momentum function (by default: from Gross et al, JGR, 2005): Matter-equatorial Matter-axial Motion-equatorial Motion-axial

This tool allows you to compute the excitation functions of the Earth rotation χ₁, χ₂, χ₃ (according to the "Euler-Liouville" formalism) and to compare them to the geophysical excitation functions, as far as these later ones are available. Comparison is done through visual plot and computation of the correlation coefficients.

The observed excitation functions (χ_x, χ_y, χ_z) are computed from the pole coordinates (x,y) and length of day changes ΔLOD of the IERS C04 series (sampling of 1 day, fluctuations > 6 days) according to the equations : χ_x + i χ_y=(x-i y) + i/σ_c d(x-iy)/dt where σ_c is the Chandler angular frequency : (σ_c = 2π/T ( 1 + i / 2 Q), T Chandler period, Q quality factor) and χ_z=ΔLOD (actually the true adimensionel axial excitation function is ΔLOD / LOD with LOD =86400 s TAI). The equatorial excitation function χ_x + i χ_y is computed according to an algorithm such as the one introduced by Wilson and Vicente (1981,1985,2002) .

Comparison can be done with :

Atmospheric Angular Momentum Functions provided by the Special Bureau for Atmosphere of the IERS (NCEP-NCAR reanalysis time series) (http://files.aer.com/aerweb/AAM) from 1962 to 2016/1/1 (see readme). From 2016/1/1 up to the current week these data are completed by those of the operational NCEP model ( ftp://ftp.cpc.ncep.noaa.gov/long/aam/nmc). In March 2019 we add the operational ECWMF series as computed by GFZ, daily updated and spanning the period 1976-one day back from now

Oceanic Angular Momentum (OAM) functions of the ECCO model : file ECCO_50yr.chi (10 day values from 1962 to 1993 daily interpolated at 0hUTC) + file ECCO_kf080 (daily values from 1993 to last current year, assimilation of altimetric measurements of the sea surface, NCEP/NCAR atmospheric forcing), provided by the Special Bureau for Oceans of IERS (responsible : Richard Gross). In March 2019 we add the operational MPIOP series, as computed by GFZ from MPIOM (Max-Planck-Institute Ocean Model), daily updated and spanning the period 1976-one day back from now

Hydrological Angular Momentum (HAM) functions (since March 2019). HAM series of the LSDM model, as estimated by GFZ, daily updated and spanning the period 1976-one day back from now

Sea Level Angular Momentum (SLAM) functions (since March 2019). SLAM series of the ECMWF-MPIOM-LSDM coupled model, as estimated by GFZ, daily updated and spanning the period 1976-one day back from now

For the observed axial excitation the effect of zonal gravitational tides is removed according to the model recommanded by IERS Conventions 2010.

The atmospheric and oceanic angular momentum functions are filtered and sampled before comparison. By default the pressure term is associated with oceans reacting as "Inverted Barometer" (IB) in front of the pressure variations : this is a realist approximation for variations larger than 10 days (for rough pressure term click the button "Non IB").

Geodetic Excitation functions are derived from C04 pole coordinates using the Wilson (1985) digital filter.

The equatorial excitation function is based upon the knowledge of the Chandler term period T and its quality factor Q. As these parameters are affected by large uncertainties, we let you the possibility to tune them within the allowed bands (426 <T<439 days; 50<Q<200). The excitation function in the Chandler frequency band can be spoiled by bad choice of these parameters. Outside this band the choice of these parameter is not critic.

Since March 2019 the user can fix by himself the coefficients of the effective angular momentum functions.

Thanks to Henryk Dobslaw and Robert Dill for fruitful discussion pertaining to GFZ angular momentum series. Thanks to David Salstein (Atmospheric and Environmental Research, Boston) and Olivier de Viron (Institut de Physique du Globe de Paris) for their respective advices. C. Bizouard