Structure and origins of the Weddell Sea Anomaly from tidal and planetary wave signatures in FORMOSAT‐3/COSMIC observations and GAIA GCM simulations

Chang, Loren C.; Liu, Huixin; Miyoshi, Y.; Chen, Chia-Hung; Chang, Fu‐Min; Lin, Charles; Liu, Jann Yenq; Sun, Yihe

doi:10.1002/2014ja020752

Cited by 33 publications

(52 citation statements)

References 27 publications

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“…They attributed the eastward propagation of these features as being the result of the dominant diurnal standing (D0 tide) and the eastward wavenumber 1 (DE1 tide), both of which appear to have eastward phase velocities when viewed in local time. Additionally, Chang et al (2015) suggested that the WSA not only can be reconstructed as the result of superposition between the D0 tide and DE1 tide but also westward wavenumber 2 (DW2 tide) and stationary planetary wave 1 (SPW1 tide) components in TECs, producing the characteristic midnight WSA peak. The D0, DE1, DW2, and SPW1 components were found to be an interannually recurring feature of the southern midto high-latitude ionosphere during the summer, manifesting as enhancements in electron density around 300-km altitude of the summer mid to high magnetic latitudes.…”

Section: Resultsmentioning

confidence: 99%

“…This mechanism was confirmed using in situ CHAMP and GRACE observations by Chao and Luhr (2014), who reported that the diurnal eastward propagation of WSA-like features is caused by the D0 tide in the Southern Hemisphere and DE1 in the Northern Hemisphere. Recently, the tidal decomposition has been applied to TEC and/or electron density derived from inversion of TEC using radio occultation technique of FORMOSAT3/COS-MIC (F3/C), to quantify the components dominating local time and spatial variation in the WSA region (Chang et al 2015). Liu et al (2014) and Chang et al (2012) showed that the eastward drift of the three-dimensional F3/C electron density with HWM93 field-aligned winds agree with the eastward movements of the WSA.…”

Section: Introductionmentioning

confidence: 99%

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Three-dimensional electron density along the WSA and MSNA latitudes probed by FORMOSAT-3/COSMIC

et al. 2015

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In this paper, we employ electron density profiles derived by the GPS radio occultation experiment aboard the FORMOSAT-3/COSMIC (F3/C) satellites to examine the electron density on geographic latitudes of 40°to 80°in the Southern hemisphere and 30°to 60°in the Northern hemisphere at various global fixed local times from February 2009 to January 2010. The results reveal that an eastward shift of a single-peak plasma density feature occurs along the Weddell Sea Anomaly (WSA) latitudes, while a double-peak plasma density feature appears along the northern Mid-latitude Summer Nighttime Anomaly (MSNA) latitudes. A cross-comparison between three-dimensional F3/C electron density and HWM93 simulation confirms that the magnetic meridional effect and vertical effect caused by neutral winds exhibit the eastward shifts. Furthermore, we find that the eastward shift of the peaks when viewed as a function of local time suggests that they could be interpreted as being comprised of different tidal components with distinct zonal phase velocities in local time.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Three-dimensional electron density along the WSA and MSNA latitudes probed by FORMOSAT-3/COSMIC

et al. 2015

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“…(Heroux and Higgins 1977;Heroux and Hinteregger 1978;Heelis et al 1980;Dickinson et al 1984;Emery et al 2008;Wu et al 2012). With respect to the mid-latitudes, several recent model and observational studies showed that for manifesting the mid-latitude summer night anomaly, tidal components such as DE1 and DW2 in combination with SPW1 are predominant in the Northern Hemisphere, whereas D0 in combination with SPW1 are the major components in the Southern Hemisphere (Chen et al 2013;Jones et al 2013;Xiong and Lühr 2014;Chang et al 2015). However, origins of these non-migrating tides, especially the quantitative contribution from the lower atmosphere, are not completely understood.…”

Section: Introductionmentioning

confidence: 99%

Longitudinal structure in electron density at mid-latitudes: upward-propagating tidal effects

Wang

Zhang

2017

Earth Planets Space

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This work studies the upward-propagating migrating and non-migrating tidal effects from the lower atmosphere on the longitudinal variation of electron density ( Ne) in both the E and F regions at mid-latitudes during the 2002 March equinox. A total of 12 runs are conducted using the Thermosphere Ionosphere Electrodynamic General Circulation model for theoretical investigation. The Ne at altitudes above 200 km is affected by upward-propagating tides, with maximum values attained around 300 km. Migrating tides result in reduced longitudinal differences in the Ne over North America and in the Southern Hemisphere, while non-migrating tides induce a wave-4 pattern in both hemispheres. The non-migrating effect is weaker than the migrating effect after penetrating into the F region. The neutral composition (i.e., ratio of atom oxygen to molecular nitrogen) is dominant in regulating the Ne in both the migrating (accounting for approximately 64%) and non-migrating (about 60%) tidal penetration processes. TheNe caused by the tidal meridional wind (accounting for approximately 70%) is stronger than the tidal zonal wind (about 30%) under both the migrating and non-migrating tidal conditions, except in the Southern Hemisphere under migrating tidal input. This work contributes to our understanding of the mechanisms for the longitudinal modulation of the Ne at mid-latitudes.

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“…Chang et al . [] reported that the features of the WSA can be reconstructed as the result of superposition between the D0, eastward wave number 1, DW2, and SPW1 components in F3/C TECs, producing the characteristic midnight WSA peak. According to these studies, we investigate the cause of the southern MSNA/WSA feature by using the IPE model with the magnetic apex coordinates and the better specified thermospheric field‐aligned neutral winds inferred from the global F3/C h m F 2 observations by using the wind bias correction scheme.…”

Section: Introductionmentioning

confidence: 99%

Field‐aligned neutral wind bias correction scheme for global ionospheric modeling at midlatitudes by assimilating FORMOSAT‐3/COSMIC h_mF₂ data under geomagnetically quiet conditions

et al. 2015

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This study demonstrates the usage of a data assimilation procedure, which ingests the FORMOSAT-3/COSMIC (F3/C) h m F 2 observations to correct the model wind biases to enhance the capability of the new global Ionosphere Plasmasphere Electrodynamics (IPE) model under geomagnetically quiet conditions. The IPE model is built upon the field line interhemispheric plasma model with a realistic geomagnetic field model and empirical model drivers. The h m F 2 observed by the F3/C radio occultation technique is utilized to adjust global thermospheric field-aligned neutral winds (i.e., a component of the thermospheric neutral wind parallel to the magnetic field) at midlatitudes according to a linear relationship between time differentials of the field-aligned wind and h m F 2 . The adjusted winds are further applied to drive the IPE model. The comparison of the modeled electron density with the observations of F3/C and ground-based GPS receivers at the 2012 March equinox suggests that the modeled electron density can be significantly improved in the midlatitude regions of the Southern Hemisphere, if the wind correction scheme is applied. Moreover, the F3/C observation, the IPE model, and the wind bias correction scheme are applied to study the 2012 Southern Hemisphere Midlatitude Summer Nighttime Anomaly (southern MSNA)/Weddell Sea Anomaly (WSA) event at December solstice for examining the role of the neutral winds in controlling the longitudinal variation of the southern MSNA/WSA behavior. With the help of the wind bias correction scheme, the IPE model better tracks the F3/C-observed eastward movement of the southern MSNA/WSA feature. The apparent eastward movement of the southern MSNA/WSA features in the local time coordinate is primarily caused by the longitudinal variation in the declination angle of the geomagnetic field that controls the field-aligned projection of both geographic meridional and zonal components of the neutral wind. Both the IPE simulations and the F3/C observations show the significant longitudinal variation in the speed of the eastward movement of the southern MSNA/WSA.

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Structure and origins of the Weddell Sea Anomaly from tidal and planetary wave signatures in FORMOSAT‐3/COSMIC observations and GAIA GCM simulations

Cited by 33 publications

References 27 publications

Three-dimensional electron density along the WSA and MSNA latitudes probed by FORMOSAT-3/COSMIC

Three-dimensional electron density along the WSA and MSNA latitudes probed by FORMOSAT-3/COSMIC

Longitudinal structure in electron density at mid-latitudes: upward-propagating tidal effects

Field‐aligned neutral wind bias correction scheme for global ionospheric modeling at midlatitudes by assimilating FORMOSAT‐3/COSMIC h_mF₂ data under geomagnetically quiet conditions

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Structure and origins of the Weddell Sea Anomaly from tidal and planetary wave signatures in FORMOSAT‐3/COSMIC observations and GAIA GCM simulations

Cited by 33 publications

References 27 publications

Three-dimensional electron density along the WSA and MSNA latitudes probed by FORMOSAT-3/COSMIC

Three-dimensional electron density along the WSA and MSNA latitudes probed by FORMOSAT-3/COSMIC

Longitudinal structure in electron density at mid-latitudes: upward-propagating tidal effects

Field‐aligned neutral wind bias correction scheme for global ionospheric modeling at midlatitudes by assimilating FORMOSAT‐3/COSMIC hmF2 data under geomagnetically quiet conditions

Contact Info

Product

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Field‐aligned neutral wind bias correction scheme for global ionospheric modeling at midlatitudes by assimilating FORMOSAT‐3/COSMIC h_mF₂ data under geomagnetically quiet conditions