Thermospheric Composition O/N Response to an Altered Meridional Mean Circulation During Sudden Stratospheric Warmings Observed by GOLD

Oberheide, J.; Pedatella, Nicholas; Gan, Quan; Kumari, Komal; Burns, A. G.; Eastes, R.

doi:10.1029/2019gl086313

Cited by 54 publications

(100 citation statements)

References 36 publications

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“…This enhanced poleward (and downward-not shown) flow driven at least in part by increased SW2 amplitudes between ∼115 and 150 km acts to adiabatically heat the lower thermosphere, especially at middle-to-high northern latitudes (see Figure 10). Further, this enhanced poleward (and downward) flow shown in Figure 8 coupled with enhanced equatorward (and upward) flow shown in Figure 6 between ∼90 and 110 km is consistent with previous modeling studies of enhanced lower atmospheric wave forcing on the meridional residual circulation (e.g., Miyoshi et al, 2015;Oberheide et al, 2020;Pedatella et al, 2016;Yamazaki & Richmond, 2013).…”

Section: Migrating Semidiurnal Tidesupporting

confidence: 91%

“…Ultimately, increased eastward small‐scale GWs dissipation/breaking during the January 2013 SSW/MC event appears to be the primary driver of light species depletions, with increased SW2 activity playing a modest role in the TIME‐GCM. With the recent launch of the Global‐scale Observations of the Limb and Disk (GOLD) mission studies using SABER H and GOLD O/N 2 (e.g., Oberheide et al, 2020) can be used to trace the effects of SSWs and MCs both vertically and horizontally within the atmosphere. These data provide the first opportunity to examine coupling from the high‐latitude stratosphere to the tropical thermosphere. Light species variability associated with SSW/MC may potentially affect the plasma population of the topside ionosphere and plasmasphere.…”

Section: Discussionmentioning

confidence: 99%

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Coupling From the Middle Atmosphere to the Exobase: Dynamical Disturbance Effects on Light Chemical Species

et al. 2020

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This paper characterizes the impacts of sudden stratospheric warmings (SSWs) and mesospheric coolings (MCs) on the light species distribution (i.e., helium [He], and atomic hydrogen [H]) of the thermosphere using a combined data-modeling approach. Performing a set of numerical experiments with a general circulation model whose middle atmospheric dynamical and thermodynamical fields were constrained using a numerical weather prediction system, we simulate the effects of SSWs and MCs on light chemical species, and via comparisons with two data sets taken from the mesosphere and thermosphere, we quantify the associated variability in light species abundances and mass density. Large depletions in the observed and modeled polar H abundance in the mesosphere and lower thermosphere (MLT) occur with MC onset, as opposed to SSW onset. Depletions in all light thermospheric species at high northern latitudes extend up to the exobase in our model simulations during the January 2013 SSW/MC period, with the largest depletions simulated for the lightest species. Further, our modeling work substantiates the paradigm of increased mixing in the MLT driven by a meridional residual circulation during SSWs resulting from enhanced small-scale gravity wave and migrating semidiurnal tidal forcing; the former being the primary driver and the latter of secondary but notable importance in our model simulations. SSW/MC induced light species variability then gets projected upward into the thermosphere through molecular diffusion. Modeled light species variability during the January 2013 SSW/MC event suggests SSW/MC signatures could be present in the topside ionosphere and plasmasphere. Plain Language Summary Sudden stratospheric warmings (SSWs) and mesospheric coolings (MCs) are episodic polar middle atmospheric (∼12-80 km or ∼7-50 miles altitude) dynamical weather events driven by increased wave forcing from the troposphere. These events are known to have global effects on the meteorology of the upper atmosphere (i.e., the thermosphere and ionosphere). Observational and modeling evidence presented in this study demonstrate that SSWs and MCs in the middle atmosphere act to drive changes in the chemical composition of the upper atmosphere through an intricate series of processes, set in motion by SSW/MC enhancements in lower and middle atmospheric wave forcing. Our results show that SSW/MC driven changes in particularly light species like hydrogen extend well into the transition region between Earth's atmosphere and outer space. This implies that middle atmospheric weather may have an impact on the plasma populations several Earth radii above Earth's surface (∼10,000 miles or more away).

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Section: Migrating Semidiurnal Tidesupporting

confidence: 91%

Section: Discussionmentioning

confidence: 99%

Coupling From the Middle Atmosphere to the Exobase: Dynamical Disturbance Effects on Light Chemical Species

et al. 2020

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“…This implies that the brightness depletion after day 25 (21 December 2018) may also be associated with the SSW. Pedatella et al (2016) suggested that an enhanced migrating semidiurnal tide (SW2) during SSW events is able to induce a global‐scale upward circulation and thereby a reduction of zonal mean O/N 2 ratio and electron densities (Liu & Roble, 2002; Oberheide et al, 2020; Shepherd et al, 1999). In addition, the intraseasonal variability (e.g., Sassi et al, 2019; Vergados et al, 2018) in the lower atmosphere could be responsible for the observed 60‐day oscillation in brightness as well.…”

Section: Resultsmentioning

confidence: 99%

New Observations of Large‐Scale Waves Coupling With the Ionosphere Made by the GOLD Mission: Quasi‐16‐Day Wave Signatures in the F‐Region OI 135.6‐nm Nightglow During Sudden Stratospheric Warmings

et al. 2020

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The recently launched Global-scale Observations of the Limb and Disk (GOLD) Mission observed prominent quasi-16-day oscillations (Q16DOs) in the OI 135.6-nm nightglow from the equatorial ionization anomaly (EIA) region during 26 November 2018 to 25 January 2019. Meanwhile, the enhanced and concurrent quasi-16-day wave (Q16DW) activity was observed in the middle atmosphere by the Sounding of the Atmosphere using Broadband Emission Radiometry (SABER) instrument. This implies that the F-region ionosphere couples with the lower atmosphere through large-scale waves. A noteworthy phenomenon was that the Q16DOs displayed an asymmetric behavior between the northern and southern EIA crests. This asymmetry indicates that the ionospheric Q16DOs might be driven by the Q16DW-modulated tides, which not only modulated the E-region dynamo winds but also modulated the F-region field-aligned neutral winds via vertical penetration, producing the oscillations in plasmas densities.Plain Language Summary Driving of the short-term variability in the ionosphere is a crucial scientific question of space physics, which connects the thermosphere and ionosphere to the solar and magnetospheric forcing, as well as terrestrial atmosphere weather. It is also the most challenge part of space weather forecast. Traveling planetary waves (PWs), including the eastward propagating Kelvin waves and westward propagating Rossby waves, are responsible for a large amount of day-to-day variability in ionospheric parameters. Our study showed an evidence of the Rossby waves coupling with the nighttime F-region ionosphere observed by GOLD. More importantly, the observations suggested a physical pathway accounting for the PW coupling in the atmosphere-ionosphere system; that is, PW-modulated tides penetrate into the F-region ionosphere and produce the field-aligned motion of the plasmas, leading to the oscillations in electron density at the PW periods.

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“…The second temporal scale is associated with ionospheric oscillations with planetary wave time scales and observed as 2‐, 5‐ to 6‐, or 10‐ to 16‐day quasi‐periodic variations in peak electron density, peak height of the F region, and locations of the equatorial ionization anomaly (EIA) (Mo et al, 2014; Patra et al, 2014). The third temporal scale can last for 10–20 days or longer and is expressed as decreases in zonal and diurnal mean electron density and mean ionospheric peak height (Pancheva & Mukhtarov, 2011), decrease in thermospheric density (Liu et al, 2011; Yamazaki et al, 2015), and decrease in thermospheric O/N 2 ratio (Oberheide et al, 2020). These observational studies have stimulated considerable advances in understanding the physical mechanisms that link the state of the stratosphere to low‐latitude ionospheric variability.…”

Section: Introductionmentioning

confidence: 99%

“…These observational studies have stimulated considerable advances in understanding the physical mechanisms that link the state of the stratosphere to low‐latitude ionospheric variability. Three generally accepted mechanisms include (1) changes in the migrating and non‐migrating solar and lunar tides (Forbes & Zhang, 2012; Jin et al, 2012; Liu et al, 2010; Pedatella & Forbes, 2010), (2) increases in stratospheric tropical ozone during SSWs that lead to an enhancement in the migrating tide (Goncharenko et al, 2012; Limpasuvan et al, 2016; Siddiqui et al, 2019), and (3) reductions in the thermospheric O/N 2 ratio due to tidal dissipation (Oberheide et al, 2020; Yamazaki & Richmond, 2013). Superposition of these and other mechanisms that are still yet to be discovered creates highly variable conditions in the quiet‐time ionosphere‐thermosphere system that can be observed in multiple upper atmospheric parameters.…”

Section: Introductionmentioning

confidence: 99%

Longitudinally Dependent Low‐Latitude Ionospheric Disturbances Linked to the Antarctic Sudden Stratospheric Warming of September 2019

et al. 2020

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The strongest Southern Hemisphere minor sudden stratospheric warming (SSW) in the last 40 years occurred in September 2019 and resulted in unprecedented weakening of the stratospheric polar vortex. Ionospheric total electron content (TEC) observations are used to provide an overview of statistically significant anomalies in the low‐latitude ionosphere during this event. Quasi‐semidiurnal perturbations of TEC are observed in response to the SSW, similar to those seen during Northern Hemisphere SSWs. Analysis indicates the existence of quasi‐periodic oscillations in TEC in the crests of the equatorial ionization anomaly, with strong 5‐ to 6‐day and 2‐ to 3‐day periodicities. Ionospheric anomalies from the combined effects of multiple mechanisms exceed a factor of 2, comparable to the strongest anomalies associated with Northern Hemisphere SSWs. These results also indicate a remarkable longitudinal variation in the character and magnitude of variations that could be related to a modulation of the non‐migrating diurnal tide.

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Thermospheric Composition O/N Response to an Altered Meridional Mean Circulation During Sudden Stratospheric Warmings Observed by GOLD

Cited by 54 publications

References 36 publications

Coupling From the Middle Atmosphere to the Exobase: Dynamical Disturbance Effects on Light Chemical Species

Coupling From the Middle Atmosphere to the Exobase: Dynamical Disturbance Effects on Light Chemical Species

New Observations of Large‐Scale Waves Coupling With the Ionosphere Made by the GOLD Mission: Quasi‐16‐Day Wave Signatures in the F‐Region OI 135.6‐nm Nightglow During Sudden Stratospheric Warmings

Longitudinally Dependent Low‐Latitude Ionospheric Disturbances Linked to the Antarctic Sudden Stratospheric Warming of September 2019

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