Atmospheric Effects of &gt;30‐keV Energetic Electron Precipitation in the Southern Hemisphere Winter During 2003

Pettit, Joshua; Randall, C. E.; Peck, E. D.; Marsh, Daniel R.; Kamp, Max van de; Fang, Xiaohua; Harvey, V. Lynn; Rodger, Craig J.; Funke, B.

doi:10.1029/2019ja026868

Cited by 29 publications

(58 citation statements)

References 88 publications

(121 reference statements)

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“…Simulations of mesospheric and lower thermospheric (MLT) NOx descent using the Whole Atmosphere Community Climate Model (WACCM, or its extended version WACCMX) have greatly underestimated the amount of NOx. This underestimate has been reported both for the Southern Hemisphere (Pettit et al, 2019) and for the Northern Hemisphere (Randall et al, 2015;Orsolini et al, 2017). A similar deficit was also reported with the Hamburg model of Neutral and Ionized Atmosphere (HAMMONIA) (Meraner et al, 2016) when operated in a free-running mode (i.e.…”

Section: Introductionsupporting

confidence: 79%

2 and 3-dimensional structure of the descent of mesospheric trace constituents after the 2013 SSW elevated stratopause event

Siskind¹,

Harvey²,

Sassi³

et al. 2021

Preprint

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Abstract. We use the Specified Dynamics version of the Whole Atmosphere Community Climate Model Extended (SD-WACCMX) to model the descent of nitric oxide (NO) and other mesospheric tracers in the extended, elevated stratopause phase of the 2013 Sudden Stratospheric Warming (SSW). The dynamics are specified with a high altitude version of the Navy Global Environmental model (NAVGEM-HA). Consistent with our earlier published results, we find that using a high altitude meteorological analysis to nudge WACCMX allows for a realistic simulation of the descent of lower thermospheric nitric oxide down to the lower mesosphere, near 60 km. This is important because these simulations only included auroral electrons, and did not consider additional sources of NO from higher energy particles, for example, medium energy electron precipitation (> 30 keV). This suggests that the so-called energetic particle precipitation indirect effect (EPP-IE) can be accurately simulated, at least in years of low geomagnetic activity, such as 2013, without the need for additional NO production, provided the meteorology is accurately constrained. Despite the general success of WACCMX in simulating mesospheric NO, a detailed comparison of the WACCMX fields with the analyzed NAVGEM-HA H2O and satellite NO and H2O data from the Solar Occultation for Ice Experiment (SOFIE) and the Atmospheric Chemistry Experiment-Fourier Transform Spectrometer (ACE-FTS) reveals significant differences in the latitudinal and longitudinal distributions in the 45–55 km region. This stems from the tendency for WACCMX descent to maximize at sub-polar latitudes and while such sub-polar descent is seen in the NAVGEM-HA analysis, it is more transient than in the WACCMX simulation. These differences are linked to differences in the Transformed Eulerian Mean (TEM) circulation between NAVGEM-HA and WACCMX, most likely arising from small differences in how gravity wave forcing is represented. To attempt to compensate for the differing distributions of model vs. observed NO and to enable us to quantify the total amount of upper atmospheric NO delivered to the stratopause region, we use potential vorticity and equivalent latitude coordinates. Preliminary results suggest both model and observations are generally consistent with NO totals in the range of 0.1–0.25 gigamoles (GM).

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Section: Introductionsupporting

confidence: 79%

2 and 3-dimensional structure of the descent of mesospheric trace constituents after the 2013 SSW elevated stratopause event

Siskind¹,

Harvey²,

Sassi³

et al. 2021

Preprint

Self Cite

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“…Measured flux ratios from the horizontal (90°) and vertical (0°) telescopes have been used to infer efficiency of loss‐cone filling by trapped electron scattering in several studies of radiation belt and atmospheric dynamics (Li et al, 2013; Ni et al, 2014; Nesse Tyssøy et al, 2016; Soria‐Santacruz et al, 2015); others have used data from either telescope orientation alone (Peck et al, 2015; Pham et al, 2017; Pettit et al, 2019; Rodger et al, 2010). Typically, they have relied on nominal detector response characteristics as specified by the electronic and geometrical configurations of the MEPED instrumentation, which provide an energy threshold and angular field of view (FOV) for each of several available data channels, or have combined more accurate energy response functions (Yando et al, 2011) with a nominal FOV angular response.…”

Section: Introductionmentioning

confidence: 99%

POES/MEPED Angular Response Functions and the Precipitating Radiation Belt Electron Flux

Selesnick

Yando³

et al. 2020

JGR Space Physics

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Angular response functions are derived for four electron channels and six proton channels of the SEM-2 MEPED particle telescopes on the POES and MetOp satellites from Geant4 simulations previously used to derive the energy response. They are combined with model electron distributions in energy and pitch angle to show that the vertical 0 • telescope, intended to measure precipitating electrons, instead usually measures trapped or quasi-trapped electrons, except during times of enhanced pitch angle diffusion. A simplified dynamical model of the radiation belt electron distribution near the loss cone, as a function of longitude, energy, and pitch angle, that accounts for pitch angle diffusion, azimuthal drift, and atmospheric backscatter is fit to sample MEPED electron data at L = 4 during times of differing diffusion rates. It is then used to compute precipitating electron flux, as function of energy and longitude, that is lower than would be estimated by assuming that the 0 • telescope always measures precipitating electrons.

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“…Simulations of the atmospheric effects of EPP using the specified dynamics version of the Whole Atmosphere Community Climate Model (WACCM 4) (Marsh et al, 2013) were improved by including MEE ionization (Pettit et al, 2019). WACCM-D (Verronen et al, 2016) and WACCM-SIC (Kovács et al, 2016) allow more detailed representations of D region chemistry to be performed in WACCM simulations.…”

Section: Previous Studiesmentioning

confidence: 99%

Spatial Distributions of Nitric Oxide in the Antarctic Wintertime Middle Atmosphere During Geomagnetic Storms

et al. 2020

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Energetic electron precipitation leads to increased nitric oxide (NO) production in the mesosphere and lower thermosphere. NO distributions in the wintertime, high‐latitude Southern Hemisphere atmosphere during geomagnetic storms are investigated. NO partial columns in the upper mesosphere at altitudes 70–90 km and in the lower thermosphere at 90–110 km have been derived from observations made by the Solar Occultation For Ice Experiment (SOFIE) on board the Aeronomy of Ice in the Mesosphere (AIM) satellite. The SOFIE NO measurements during 17 geomagnetic storms in 2008–2014 have been binned into selected geomagnetic latitude and geographic latitude/longitude ranges. The regions above Antarctica showing the largest instantaneous NO increases coincide with high fluxes of 30–300 keV precipitating electrons from measurements by the second‐generation Space Environment Monitor (SEM‐2) Medium Energy Proton and Electron Detector (MEPED) instrument on the Polar‐orbiting Operational Environmental Satellites (POES). Significant NO increases over the Antarctic Peninsula are likely due to precipitation of >30 keV electrons from the radiation belt slot region. NO transport is estimated using Horizontal Wind Model (HWM14) calculations. In the upper mesosphere strong eastward winds (daily mean zonal wind speed ~20–30 m s−1 at 80 km) during winter transport NO‐enriched air away from source regions 1–3 days following the storms. Mesospheric winds also introduce NO‐poor air into the source regions, quenching initial NO increases. Higher up, in the lower thermosphere, weaker eastward winds (~5–10 m s−1 at 100 km) are less effective at redistributing NO zonally.

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Atmospheric Effects of >30‐keV Energetic Electron Precipitation in the Southern Hemisphere Winter During 2003

Cited by 29 publications

References 88 publications

2 and 3-dimensional structure of the descent of mesospheric trace constituents after the 2013 SSW elevated stratopause event

2 and 3-dimensional structure of the descent of mesospheric trace constituents after the 2013 SSW elevated stratopause event

POES/MEPED Angular Response Functions and the Precipitating Radiation Belt Electron Flux

Spatial Distributions of Nitric Oxide in the Antarctic Wintertime Middle Atmosphere During Geomagnetic Storms

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