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Capturing uncertainty in magnetospheric ultra‐low frequency wave models (2019)

S.N. Bentley, Clare E. J. Watt, I.J. Rae, M.J. Owens, K. Murphy, M. Lockwood, J. K. Sandhu

Wiley

In: Space Weather

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Publication Date: 2019

Description: Abstract We develop and test an empirical model predicting ground‐based observations of ultra‐low frequency (ULF, 1‐20 mHz) wave power across a range of frequencies, latitudes and magnetic local time sectors. This is parameterized by instantaneous solar wind speed vsw, variance in proton number density var(Np) and interplanetary southward magnetic field Bz. A probabilistic model of ULF wave power will allow us to address uncertainty in radial diffusion coefficients and therefore improve diffusion modeling of radial transport in Earth's outer radiation belt. Our model can be used in two ways to reproduce wave power; by sampling from conditional probability distribution functions or by using the mean (expectation) values. We derive a method for testing the quality of the parameterization and test the ability of the model to reproduce ULF wave power time series. Sampling is a better method for reproducing power over an extended time period as it retains the same overall distribution while mean values are better for predicting the power in a time series. The model predicts each hour in a time series better than the assumption that power persists from the preceding hour. Finally, we review other sources of diffusion coefficient uncertainty. Although this wave model is designed principally for the goal of improved radial diffusion coefficients to include in outer radiation belt diffusion based modeling, we anticipate that our model can also be used to investigate the occurrence of ULF waves throughout the magnetosphere and hence the physics of ULF wave generation and propagation.

Print ISSN: 1539-4964

Electronic ISSN: 1542-7390

Topics: Geosciences , Physics

Published by Wiley on behalf of American Geophysical Union (AGU).

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Direct observations of the full Dungey convection cycle in the polar ionosphere for southward interplanetary magnetic field conditions (2015)

Q. –H. Zhang, M. Lockwood, J. C. Foster, S. –R. Zhang, B. –C. Zhang, I. W. McCrea, J. Moen, M. Lester, J. Michael Ruohoniemi

Wiley

In: Journal of Geophysical Research JGR - Space Physics

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Publication Date: 2015-05-17

Description: Tracking the formation and full evolution of polar cap ionization patches in the polar ionosphere, we directly observe the full Dungey convection cycle for southward interplanetary magnetic field (IMF) conditions. This enables us to study how the Dungey cycle influences the patches’ evolution. The patches were initially segmented from the dayside storm enhanced density plume (SED) at the equatorward edge of the cusp, by the expansion and contraction of the polar cap boundary (PCB) due to pulsed dayside magnetopause reconnection, as indicated by in-situ THEMIS observations. Convection led to the patches entering the polar cap and being transported antisunward, whilst being continuously monitored by the globally distributed arrays of GPS receivers and SuperDARN radars. Changes in convection over time resulted in the patches following a range of trajectories, each of which differed somewhat from the classical twin-cell convection streamlines. Pulsed nightside reconnection, occurring as part of the magnetospheric substorm cycle, modulated the exit of the patches from the polar cap, as confirmed by coordinated observations of the magnetometer at Tromsø and EISCAT Tromsø UHF Radar. After exiting the polar cap, the patches broke up into a number of plasma blobs, and returned sunward in the auroral return flow of the dawn and/or dusk convection cell. The full circulation time was about three hours.

Print ISSN: 0148-0227

Topics: Geosciences , Physics

Published by Wiley on behalf of American Geophysical Union (AGU).

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