Home
Norah Kaggwa Kwagala's picture

Norah Kaggwa Kwagala

Researcher
Academic article
  • Show author(s) (2021). The Micro-Macro Coupling of Mass-Loading in Symmetric Magnetic Reconnection With Cold Ions. Geophysical Research Letters.
  • Show author(s) (2021). On the Presence and Thermalization of Cold Ions in the Exhaust of Antiparallel Symmetric Reconnection. Frontiers in Astronomy and Space Sciences.
  • Show author(s) (2021). Magnetospheric Multiscale Observations of an Expanding Oxygen Wave in Magnetic Reconnection . Geophysical Research Letters. 10 pages.
  • Show author(s) (2021). Magnetic Reconnection in a Sheared Magnetic Flux Tube: Slippage Versus Tearing. Journal of Geophysical Research (JGR): Space Physics.
  • Show author(s) (2021). Comparing Three Approaches to the Inducing Source Setting for the Ground Electromagnetic Field Modeling due to Space Weather Events. Space Weather.
  • Show author(s) (2020). Validating the Space Weather Modeling Framework (SWMF) for applications in northern Europe: Ground magnetic perturbation validation. Journal of Space Weather and Space Climate. 13 pages.
  • Show author(s) (2020). On the Impact of a Streaming Oxygen Population on Collisionless Magnetic Reconnection. Geophysical Research Letters.
  • Show author(s) (2020). Interaction of Cold Streaming Protons with the Reconnection Process. Journal of Geophysical Research (JGR): Space Physics. 11 pages.
  • Show author(s) (2020). Collisionless Magnetic Reconnection in an Asymmetric Oxygen Density Configuration. Geophysical Research Letters.
  • Show author(s) (2020). A new Look at the Electron Diffusion Region in Asymmetric Magnetic Reconnection. Journal of Geophysical Research (JGR): Space Physics. 16 pages.
  • Show author(s) (2018). Seasonal and solar cycle variations of thermally excited 630.0 nm emissions in the polar ionosphere. Journal of Geophysical Research (JGR): Space Physics. 7029-7039.
  • Show author(s) (2017). How often do thermally excited 630.0 nm emissions occur in the Polar Ionosphere? Journal of Geophysical Research (JGR): Space Physics. 698-710.
  • Show author(s) (2016). On the contribution of thermal excitation to the total 630.0 nm emissions in the northern cusp ionosphere. Journal of Geophysical Research (JGR): Space Physics. 1234-1245.
Academic lecture
  • Show author(s) (2021). Acceleration and thermalization of cold ions within the reconnection exhaust.
  • Show author(s) (2020). What can limit the effectiveness of magnetic reconnection?
  • Show author(s) (2020). On the Micro-Macro Coupling of Mass-Loading in Magnetic Reconnection with Cold Ions.
  • Show author(s) (2020). On the Micro-Macro Coupling of Mass-Loading in Magnetic Reconnection with Cold Ions.
  • Show author(s) (2020). How does a cold proton population influence the reconnection process on different scales?
  • Show author(s) (2020). Electron and ion dynamics during closure of Hall current systems.
  • Show author(s) (2020). Cold proton-reconnection interaction.
  • Show author(s) (2019). Validating the Space Weather Modeling Framework (SWMF) for applications in northern Europe: Ground magnetic perturbation validation .
  • Show author(s) (2019). Thermally excited 630.0 nm emissions in the polar ionosphere.
Masters thesis
  • Show author(s) (2015). Dayside 630.0 nm emissions due to thermally excited O(1D) in the cusp region ionosphere over Longyearbyen, Svalbard.
Doctoral dissertation
  • Show author(s) (2018). Thermally excited 630.0 nm emissions in the polar ionosphere.
Poster
  • Show author(s) (2020). Quantitative Investigation of the Effect on Ground Magnetic Perturbations of IMF Bx .
  • Show author(s) (2019). Validating the Space Weather Modeling Framework (SWMF) for applications in northern Europe: Ground magnetic perturbation validation .
  • Show author(s) (2017). Thermally Excited 630.0 nm Emissions in the Polar Ionosphere.
  • Show author(s) (2016). Occurrence and Characteristics of Thermally Excited 630.0 nm Emissions in the Polar Ionosphere.

More information in national current research information system (CRIStin)