Estimating ocean tide model uncertainties for electromagnetic inversion studies

Saynisch, Jan; Irrgang, Christopher; Thomas, Maik

doi:10.5194/angeo-2018-27

Cited by 3 publications

(4 citation statements)

References 6 publications

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“…Signatures of ocean tidal dynamics are omnipresent in oceanographic and geodetic observations taken either on the ground or from space. This includes periodic variations in ocean currents registered by moored instruments or acoustic tomography (Dushaw et al., 1997; Luyten & Stommel, 1991; Ray, 2001) as well as by induced secondary magnetic fields (Maus & Kuvshinov, 2004; Saynisch et al., 2018), sea surface height changes measured from tide gauges and satellite altimetry (Doodson, 1928; Schrama & Ray, 1994), and global bottom pressure variations from pelagic pressure recorders and gravimetric satellite missions (Wiese et al., 2016). More recently, even tiny variations in sea surface temperature (Hsu et al., 2020) and tropical precipitation observations (Kohyama & Wallace, 2016) were related to ocean tidal dynamics.…”

Section: Introductionmentioning

confidence: 99%

High‐Resolution Numerical Modeling of Barotropic Global Ocean Tides for Satellite Gravimetry

2021

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Signatures of ocean tidal dynamics are omnipresent in oceanographic and geodetic observations taken either on the ground or from space. This includes periodic variations in ocean currents registered by moored instruments or acoustic tomography (Dushaw et al., 1997;Luyten & Stommel, 1991;Ray, 2001) as well as by induced secondary magnetic fields (Maus & Kuvshinov, 2004;Saynisch et al., 2018), sea surface height changes measured from tide gauges and satellite altimetry (Doodson, 1928;Schrama & Ray, 1994), and global bottom pressure variations from pelagic pressure recorders and gravimetric satellite missions (Wiese et al., 2016). More recently, even tiny variations in sea surface temperature (Hsu et al., 2020) and tropical precipitation observations (Kohyama & Wallace, 2016) were related to ocean tidal dynamics.Separating tidal and transient signals in satellite records is not trivial due to the complicated spatiotemporal sampling of observations taken from satellites in non-geostationary orbits. The repeat orbit of the TOPEX/Poseidon (T/P) satellite altimetry mission (Fu & Cazenave, 2000) has been carefully selected in a way that aliases the major ocean tidal constituents into periods that are well distinct from naturally occurring periodicities, thereby providing tidal charts based on observations that cover the open ocean in a regular spatial pattern (Shum et al., 1997

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Section: Introductionmentioning

confidence: 99%

High‐Resolution Numerical Modeling of Barotropic Global Ocean Tides for Satellite Gravimetry

2021

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“…While, e.g., Saynisch et al (2018) compared forward models for the M2 tidal magnetic field based on different tidal models, we aim at illustrating the effect of the involved trial functions on the possible extraction of the tidal 15 magnetic field from satellite data in the first place. The indicated residuals for the synthetic examples show that the use of the presented adapted physics based trial functions could have a detectable effect for the extraction of such signals in satellite data.…”

Section: Discussionmentioning

confidence: 99%

On the Approximation of Spatial Structures of Global Tidal Magnetic Field Models

Telschow¹,

Gerhards²,

Rother³

2018

Preprint

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Abstract. The extraction of the magnetic signal induced by the oceanic M2 tide is typically based solely on the temporal periodicity of the signal. Here, we propose a system of tailored trial functions that additionally takes the spatial constraint into account that the sources of the signal are localized within the oceans. This construction requires knowledge of the underlying conductivity model but not of the inducing tidal current velocity. Approximations of existing tidal magnetic field models with these trial functions and comparisons with approximations based on other localized and non-localized trial functions are 5 illustrated.

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“…Especially since the launch of the Swarm satellite magnetometers (Friis‐Christensen et al, ), the number of EMOTS‐related studies is ever growing. Alone in the last few years, many papers studying or using EMOTS were published (Grayver & Olsen, ; Guzavina et al, , ; Petereit et al, , ; Šachl et al, ; Schnepf et al, ; Saynisch et al, ; Velimsky et al, ). EMOTS are used to infer information about the Earth's lithosphere and mantle (Guzavina et al, ; Grayver et al, ; Kuvshinov et al, ; Schnepf et al, ).…”

Section: Introductionmentioning

confidence: 99%

“…Likewise, EMOTS are proposed to infer information about the oceans (Irrgang et al, ; Petereit et al, ; Saynisch et al, , ). In addition, EMOTS influence on other EM observations, and EMOTS errors are important topics (Guzavina et al, ; Saynisch et al, ; Schnepf et al, , ). Most of the mentioned studies focus only on the amplitudes of EMOTS and their sensitivities.…”

Section: Introductionmentioning

confidence: 99%

Phase Changes of Electromagnetic Oceanic Tidal Signals

et al. 2020

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Over the last years, the number of studies that investigate or utilize the electromagnetic (EM) signals generated by ocean tides is steadily growing. However, the majority of these studies focuses on the amplitudes of EM tidal signals. This study investigates the phases of EM tidal signals and their changes. Twenty-six years of monthly observation-based datasets of tidal velocities, geomagnetic field, and oceanic conductivity are fed into an EM induction solver to generate varying EM tidal signals. The sensitivities of the resulting EM signals are analyzed by forbidding or allowing the input datasets to vary in time. We report on the phase's sensitivities with respect to changes in the EM properties, that is, secular variation of the geomagnetic field and changes in oceanic conductivity. Distinct temporal behavior and distinct geographic pattern for the two sensitivities can be reported. In general, apart from global phase shifts of 3-5 degrees, concentrated areas with phase shifts of up to 45 degrees occur all over the globe, over the oceans, for example, Arctic and Atlantic Ocean, as well as on coastal land regions, for example, Southwest Greenland and Japan. Very locally, phase shifts of 90 degree or higher occur.

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Estimating ocean tide model uncertainties for electromagnetic inversion studies

Cited by 3 publications

References 6 publications

High‐Resolution Numerical Modeling of Barotropic Global Ocean Tides for Satellite Gravimetry

High‐Resolution Numerical Modeling of Barotropic Global Ocean Tides for Satellite Gravimetry

On the Approximation of Spatial Structures of Global Tidal Magnetic Field Models

Phase Changes of Electromagnetic Oceanic Tidal Signals

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