A. D. Aylward scite author profile

Abstract. We present the ground signatures of dynamic substorm features with particular emphasis on the event interpretation capabilities provided by the IMAGE magnetometer network. This array covers the high latitudes from the sub-auroral to the cusp/cleft region. An isolated substorm on 11 Oct. 1993 during the late evening hours exhibited many of well-known features such as the Harang discontinuity, westward travelling surge and poleward leap, but also discrete auroral forms, known as auroral streamers, appeared propagating westward along the centre of the electrojet. Besides the magnetic ®eld measurements, there were auroral observations and plasma¯ow and conductivity measurements obtained by EISCAT. The data of all three sets of instruments are consistent with the notion of upward ®eld-aligned currents associated with the moving auroral patches. A detailed analysis of the electrodynamic parameters in the ionosphere, however, reveals that they do not agree with the expectations resulting from commonly used simplifying approximations. For example, the westward moving auroral streamers which are associated with ®eld-aligned current ®laments, are not collocated with the centres of equivalent current vortices. Furthermore, there is a clear discrepancy between the measured plasma¯ow direction and the obtained equivalent current direction. All this suggests that steep conductivity gradients are associated with the transient auroral forms. Also self-induction eects in the ionosphere may play a role for the orientation of the plasma¯ows. This study stresses the importance of multi-instrument observation for a reliable interpretation of dynamic auroral processes.

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Annual and semiannual variations in the ionospheric F2-layer: II. Physical discussion

Rishbeth

Müller‐Wodarg

Zou

et al. 2000

Ann Geophysicae

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Abstract. The companion paper by Zou et al. shows that the annual and semiannual variations in the peak F2-layer electron density (NmF2) at midlatitudes can be reproduced by a coupled thermosphere-ionosphere computational model (CTIP), without recourse to external in¯uences such as the solar wind, or waves and tides originating in the lower atmosphere. The present work discusses the physics in greater detail. It shows that noon NmF2 is closely related to the ambient atomic/molecular concentration ratio, and suggests that the variations of NmF2 with geographic and magnetic longitude are largely due to the geometry of the auroral ovals. It also concludes that electric ®elds play no important part in the dynamics of the midlatitude thermosphere. Our modelling leads to the following picture of the global three-dimensional thermospheric circulation which, as envisaged by Duncan, is the key to explaining the F2-layer variations. At solstice, the almost continuous solar input at high summer latitudes drives a prevailing summer-to-winter wind, with upwelling at low latitudes and throughout most of the summer hemisphere, and a zone of downwelling in the winter hemisphere, just equatorward of the auroral oval. These motions a ect thermospheric composition more than do the alternating day/night (up-and-down) motions at equinox. As a result, the thermosphere as a whole is more molecular at solstice than at equinox. Taken in conjunction with the well-known relation of F2-layer electron density to the atomic/molecular ratio in the neutral air, this explains the F2-layer semiannual e ect in NmF2 that prevails at low and middle latitudes. At higher midlatitudes, the seasonal behaviour depends on the geographic latitude of the winter downwelling zone, though the e ect of the composition changes is modi®ed by the large solar zenith angle at midwinter. The zenith angle e ect is especially important in longitudes far from the magnetic poles. Here, the downwelling occurs at high geographic latitudes, where the zenith angle e ect becomes overwhelming and causes a midwinter depression of electron density, despite the enhanced atomic/ molecular ratio. This leads to a semiannual variation of NmF2. A di erent situation exists in winter at longitudes near the magnetic poles, where the downwelling occurs at relatively low geographic latitudes so that solar radiation is strong enough to produce large values of NmF2. This circulation-driven mechanism provides a reasonably complete explanation of the observed pattern of F2 layer annual and semiannual quiet-day variations.

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An Investigation of the CME of 3 November 2011 and Its Associated Widespread Solar Energetic Particle Event

Prise¹,

Harra²,

Matthews³

et al. 2013

Sol Phys

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Westward moving dynamic substorm features observed with the IMAGE magnetometer network and other ground-based instruments

et al. 1998

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Models of Solar Wind Structures and Their Interaction with the Earth’s Space Environment

et al. 2009

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The discipline of "Space Weather" is built on the scientific foundation of solarterrestrial physics but with a strong orientation toward applied research. Models describing the solar-terrestrial environment are therefore at the heart of this discipline, for both physical understanding of the processes involved and establishing predictive capabilities of the consequences of these processes. Depending on the requirements, purely physical models, semi-empirical or empirical models are considered to be the most appropriate. This review focuses on the interaction of solar wind disturbances with geospace. We J. Watermann ( ) Le Studium and LPC2E/CNRS, 234 J. Watermann et al.cover interplanetary space, the Earth's magnetosphere (with the exception of radiation belt physics), the ionosphere (with the exception of radio science), the neutral atmosphere and the ground (via electromagnetic induction fields). Space weather relevant state-of-the-art physical and semi-empirical models of the various regions are reviewed. They include models for interplanetary space, its quiet state and the evolution of recurrent and transient solar perturbations (corotating interaction regions, coronal mass ejections, their interplanetary remnants, and solar energetic particle fluxes). Models of coupled large-scale solar windmagnetosphere-ionosphere processes (global magnetohydrodynamic descriptions) and of inner magnetosphere processes (ring current dynamics) are discussed. Achievements in modeling the coupling between magnetospheric processes and the neutral and ionized upper and middle atmospheres are described. Finally we mention efforts to compile comprehensive and flexible models from selections of existing modules applicable to particular regions and conditions in interplanetary space and geospace.

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A. D. Aylward

Westward moving dynamic substorm features observed with the IMAGE magnetometer network and other ground-based instruments

Annual and semiannual variations in the ionospheric F2-layer: II. Physical discussion

An Investigation of the CME of 3 November 2011 and Its Associated Widespread Solar Energetic Particle Event

Westward moving dynamic substorm features observed with the IMAGE magnetometer network and other ground-based instruments

Models of Solar Wind Structures and Their Interaction with the Earth’s Space Environment

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