Add to ORKGHigh precision observations during Solar Cycle 23 using the Wisconsin H‐alpha Mapper (WHAM) Fabry‐Perot quantify a factor of 1.5 ± 0.15 higher Balmer α column emission intensity during near‐solar‐maximum than during solar minimum conditions. An unresolved question is how does the observed solar cycle variation in the hydrogen column emission compare with that calculated from the hydrogen distribution in atmospheric models? We have compared WHAM solar minimum and near‐solar‐maximum column intensity observations with calculations using the thermospheric hydrogen density profile and background thermospheric conditions from the Mass Spectrometer Incoherent Scatter (NRLMSISE‐00) empirical model extended to exospheric altitudes using the analytic...
We will present observations of thermospheric exospheric hydrogen H-alpha emissions taken by the Wis...
Geocoronal hydrogen forms the upper boundary of the Earths HOx chemisty and is a byproduct of methan...
Long term data sets are required to investigate sources of natural variability in the upper atmosphe...
High precision observations during Solar Cycle 23 using the Wisconsin H‐alpha Mapper (WHAM) Fabry‐Pe...
Understanding the influence of the solar cycle variation on the Earth\u27s upper atmosphere is impor...
We have completed analysis of recent Fabry-Perot observations of upper atmospheric hydrogen during s...
Hydrogen is a primary constituent of the geocorona and is a chemical byproduct of species below such...
Ground-based Fabry-Perot observations of the hydrogen Balmer-alpha emission have been used since the...
We will discuss work in progress to better understand solar cyclic and climatic influences on hydrog...
Long term observations of geocoronal hydrogen offer potential to contribute to our understanding of ...
Ground‐based hydrogen Balmer‐α observations from Northern midlatitudes span multiple solar cycles, f...
Observations of thermospheric + exospheric Hα column emissions by the Wisconsin Hα Mapper (WHAM) Fab...
The University of Wisconsin has observed geocoronal hydrogen Balmer-alpha emissions since the late 1...
We will present geocoronal Hα intensity data taken over a four year time span during near solar mini...
We will present observations of thermospheric exospheric hydrogen H-alpha emissions taken by the Wis...
Geocoronal hydrogen forms the upper boundary of the Earths HOx chemisty and is a byproduct of methan...
Long term data sets are required to investigate sources of natural variability in the upper atmosphe...
High precision observations during Solar Cycle 23 using the Wisconsin H‐alpha Mapper (WHAM) Fabry‐Pe...
Understanding the influence of the solar cycle variation on the Earth\u27s upper atmosphere is impor...
We have completed analysis of recent Fabry-Perot observations of upper atmospheric hydrogen during s...
Hydrogen is a primary constituent of the geocorona and is a chemical byproduct of species below such...
Ground-based Fabry-Perot observations of the hydrogen Balmer-alpha emission have been used since the...
We will discuss work in progress to better understand solar cyclic and climatic influences on hydrog...
Long term observations of geocoronal hydrogen offer potential to contribute to our understanding of ...
Ground‐based hydrogen Balmer‐α observations from Northern midlatitudes span multiple solar cycles, f...
Observations of thermospheric + exospheric Hα column emissions by the Wisconsin Hα Mapper (WHAM) Fab...
The University of Wisconsin has observed geocoronal hydrogen Balmer-alpha emissions since the late 1...
We will present geocoronal Hα intensity data taken over a four year time span during near solar mini...
We will present observations of thermospheric exospheric hydrogen H-alpha emissions taken by the Wis...
Geocoronal hydrogen forms the upper boundary of the Earths HOx chemisty and is a byproduct of methan...
Long term data sets are required to investigate sources of natural variability in the upper atmosphe...