Your search keyword '"Francis Vitt"' showing total 2 results

1. Development and Validation of the Whole Atmosphere Community Climate Model With Thermosphere and Ionosphere Extension (WACCM‐X 2.0)

Author

Daniel R. Marsh, Astrid Maute, Joseph McInerney, Francis Vitt, Liying Qian, Charles G. Bardeen, Wenbin Wang, B. Foster, Hanli Liu, Stanley C. Solomon, Peter H. Lauritzen, Raymond G. Roble, Arthur D. Richmond, Nicholas Pedatella, Gang Lu, and Jing Liu

Subjects

010504 meteorology & atmospheric sciences, space weather, ionosphere, Space weather, Atmospheric sciences, 01 natural sciences, Physics::Geophysics, Atmosphere, lcsh:Oceanography, 0103 physical sciences, Environmental Chemistry, lcsh:GC1-1581, 010303 astronomy & astrophysics, lcsh:Physical geography, Physics::Atmospheric and Oceanic Physics, 0105 earth and related environmental sciences, thermosphere, Global and Planetary Change, Atmospheric tide, Solar maximum, whole atmosphere, Local time, Physics::Space Physics, General Earth and Planetary Sciences, community model, Climate model, Astrophysics::Earth and Planetary Astrophysics, Ionosphere, Thermosphere, lcsh:GB3-5030

Abstract

Key developments have been made to the NCAR Whole Atmosphere Community Climate Model with thermosphere and ionosphere extension (WACCM‐X). Among them, the most important are the self‐consistent solution of global electrodynamics, and transport of O+ in the F‐region. Other ionosphere developments include time‐dependent solution of electron/ion temperatures, metastable O+ chemistry, and high‐cadence solar EUV capability. Additional developments of the thermospheric components are improvements to the momentum and energy equation solvers to account for variable mean molecular mass and specific heat, a new divergence damping scheme, and cooling by O(3P) fine structure. Simulations using this new version of WACCM‐X (2.0) have been carried out for solar maximum and minimum conditions. Thermospheric composition, density, and temperatures are in general agreement with measurements and empirical models, including the equatorial mass density anomaly and the midnight density maximum. The amplitudes and seasonal variations of atmospheric tides in the mesosphere and lower thermosphere are in good agreement with observations. Although global mean thermospheric densities are comparable with observations of the annual variation, they lack a clear semiannual variation. In the ionosphere, the low‐latitude E × B drifts agree well with observations in their magnitudes, local time dependence, seasonal, and solar activity variations. The prereversal enhancement in the equatorial region, which is associated with ionospheric irregularities, displays patterns of longitudinal and seasonal variation that are similar to observations. Ionospheric density from the model simulations reproduces the equatorial ionosphere anomaly structures and is in general agreement with observations. The model simulations also capture important ionospheric features during storms.

Published

2018

2. Temporal Variability of Atomic Hydrogen From the Mesopause to the Upper Thermosphere

Author

Daniel R. Marsh, Martin G. Mlynczak, Stan Solomon, Linda A. Hunt, Liying Qian, Anne K. Smith, Joseph McInerney, Francis Vitt, Alan G. Burns, and Hanli Liu

Subjects

Solar minimum, 010504 meteorology & atmospheric sciences, 010502 geochemistry & geophysics, Atmospheric sciences, Solar maximum, 01 natural sciences, Mesosphere, Solar cycle, Atmosphere, Geophysics, Space and Planetary Science, Mesopause, Environmental science, Ionosphere, Thermosphere, 0105 earth and related environmental sciences

Abstract

We investigate atomic hydrogen (H) variability from the mesopause to the upper thermosphere, on time scales of solar cycle, seasonal, and diurnal, using measurements made by the Sounding of the Atmosphere using Broadband Emission Radiometry (SABER) instrument on the Thermosphere Ionosphere Mesosphere Energetics Dynamics satellite, and simulations by the National Center for Atmospheric Research Whole Atmosphere Community Climate Model‐eXtended (WACCM‐X). In the mesopause region (85 to 95 km), the seasonal and solar cycle variations of H simulated by WACCM‐X are consistent with those from SABER observations: H density is higher in summer than in winter, and slightly higher at solar minimum than at solar maximum. However, mesopause region H density from the Mass‐Spectrometer‐Incoherent‐Scatter (National Research Laboratory Mass‐Spectrometer‐Incoherent‐Scatter 00 (NRLMSISE‐00)) empirical model has reversed seasonal variation compared to WACCM‐X and SABER. From the mesopause to the upper thermosphere, H density simulated by WACCM‐X switches its solar cycle variation twice, and seasonal dependence once, and these changes of solar cycle and seasonal variability occur in the lower thermosphere (~95 to 130 km), whereas H from NRLMSISE‐00 does not change solar cycle and seasonal dependence from the mesopause through the thermosphere. In the upper thermosphere (above 150 km), H density simulated by WACCM‐X is higher at solar minimum than at solar maximum, higher in winter than in summer, and also higher during nighttime than daytime. The amplitudes of these variations are on the order of factors of ~10, ~2, and ~2, respectively. This is consistent with NRLMSISE‐00.

Published

2018