Litcius/Paper detail

NRLMSIS 2.1: An Empirical Model of Nitric Oxide Incorporated Into MSIS

J. T. Emmert, McArthur Jones, D. E. Siskind, D. P. Drob, J. M. Picone, M. H. Stevens, S. M. Bailey, Stefan Bender, P. F. Bernath, B. Funke, Mark E. Hervig, Kristell Pérot

2022Journal of Geophysical Research Space Physics94 citationsDOIOpen Access PDF

Abstract

Abstract We have developed an empirical model of nitric oxide (NO) number density at altitudes from ∼73 km to the exobase, as a function of altitude, latitude, day of year, solar zenith angle, solar activity, and geomagnetic activity. The model is part of the NRLMSIS® 2.1 empirical model of atmospheric temperature and species densities; this upgrade to NRLMSIS 2.0 consists solely of the addition of NO. MSIS 2.1 assimilates observations from six space‐based instruments: UARS/HALOE, SNOE, Envisat/MIPAS, ACE/FTS, Odin/SMR, and AIM/SOFIE. We additionally evaluated the new model against independent extant NO data sets. In this paper, we describe the formulation and fitting of the model, examine biases between the data sets and model and among the data sets, compare with another empirical NO model (NOEM), and discuss scientific aspects of our analysis.

Topics & Concepts

ZenithSolar zenith angleExtant taxonAtmospheric sciencesEmpirical modellingAltitude (triangle)Environmental scienceMeteorologyEarth's magnetic fieldAtmospheric modelsLatitudeAtmosphere (unit)MathematicsPhysicsGeodesyComputer scienceGeologySimulationGeometryMagnetic fieldQuantum mechanicsBiologyEvolutionary biologyAtmospheric Ozone and ClimateIonosphere and magnetosphere dynamicsAtmospheric and Environmental Gas Dynamics