Solar activity dependence of ion upflow in the polar ionosphere observed with the European Incoherent Scatter (EISCAT) Tromsø UHF radar

Ogawa, Y.; Buchert, S. C.; Sakurai, Akio; Nozawa, Satonori; Fujii, Ryoichi

doi:10.1029/2009ja014766

Cited by 29 publications

(46 citation statements)

References 39 publications

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“…Therefore, the polar wind is typically dominated by hydrogen, and the bulk auroral ion upflow dominated by oxygen. In both cases, the observed ion velocity is on average larger and the ion flux lower at solar minimum than at solar maximum (Abe et al 2004;Ogawa et al 2010).…”

Section: Topside Ionospheric Ion Upflow and Accelerationmentioning

confidence: 85%

CASSIOPE Enhanced Polar Outflow Probe (e-POP) Mission Overview

Yau

James

2015

Space Sci Rev

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The Enhanced Polar Outflow Probe (e-POP) on the polar-orbiting CASSIOPE small satellite (325 × 1500 km, 80°inclination) is a suite of 8 plasma instruments, including imaging plasma and neutral particle sensors, magnetometers, dual-frequency Global Positioning System (GPS) receivers, charge coupled-device (CCD) cameras, a radio wave receiver and a beacon transmitter. The scientific objective of e-POP is to make observations of mesoscale and microscale plasma processes in the topside high-latitude ionosphere at the highest-possible resolution, specifically to study the microscale characteristics of plasma outflow and related acceleration processes, the occurrence morphology of neutral escape, and the effects of auroral currents on plasma outflow and those of plasma microstructures on radio propagation: the strategy is to use the large data storage and high-speed telemetry downlink capacity of a companion, experimental communications payload on board CAS-SIOPE to support the high-resolution observations of particle distributions, waves and magnetic fields to 10-ms time scale (∼ 100 m spatial scale) and the imaging of the aurora on 100-ms time scale, as well as imaging studies of the ionosphere in conjunction with groundbased transmitters and ground receiving stations on comparable (10-100 ms) time scales.

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Section: Topside Ionospheric Ion Upflow and Accelerationmentioning

confidence: 85%

CASSIOPE Enhanced Polar Outflow Probe (e-POP) Mission Overview

Yau

James

2015

Space Sci Rev

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“…The effect of ion frictional heating is expected to increase with K P and to be stronger on the dusk side and in the winter: this explains the higher occurrence frequency on the dusk side at EISCAT's latitude, and the increase in occurrence frequency with geomagnetic activity at both ESR and EISCAT. The effect of soft electron precipitation is expected to be stronger during disturbed times, particularly in the dusk quadrant, and to play a more dominant role on the dayside where the precipitating electrons tend to be softer: this explains the higher Ogawa et al (2010) dayside occurrence frequency at ESR compared with EISCAT at both quiet and disturbed times, and the higher frequency on the dawn side during disturbed times. It also suggests that soft electron-driven electron heating may be more efficient than convection-driven ion heating in driving ion upflow.…”

Section: High Latitude Ionospheric Plasmamentioning

confidence: 90%

“…The apparent movement of the dayside ion upflow region may be understood in terms of the influence of solar wind velocity and density and the IMF B Y and B Z on the shape, size and location of the upflow region, since the location of the dayside cusp is known to move equatorward with decreasing IMF B Z or increasing solar wind dynamic pressure. Ogawa et al (2010) found the average starting altitude of ion up-flow to track the measured electron density peak and to be typically 100-150 km higher than the latter. The distribution of starting altitude is quite different at low and high solar flux, respectively.…”

Section: High Latitude Ionospheric Plasmamentioning

confidence: 99%

The Earth: Plasma Sources, Losses, and Transport Processes

et al. 2015

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This paper reviews the state of knowledge concerning the source of magnetospheric plasma at Earth. Source of plasma, its acceleration and transport throughout the system, its consequences on system dynamics, and its loss are all discussed. Both observational and modeling advances since the last time this subject was covered in detail (Hultqvist et al., Magnetospheric Plasma Sources and Losses, 1999) are addressed.

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“…conditions correspond to solar minimum, and the higher upflow speeds are typical for periods of low Sun activity [Ogawa et al, 2010]. It is interesting that despite the high electron temperature, the ion temperature barely changes (see Figure 4e).…”

Section: Low-energy Precipitationmentioning

confidence: 93%

Simulation of O⁺ upflows created by electron precipitation and Alfvén waves in the ionosphere

Sydorenko

Rankin

2013

JGR Space Physics

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[1] A two-dimensional model of magnetosphere-ionosphere coupling is presented. It includes Alfvén wave dynamics, ion motion along the geomagnetic field, chemical reactions between ions and neutrals, collisions between different species, and a parametric model of electron precipitation. Representative simulations are presented, along with a discussion of the physical mechanisms that are important in forming oxygen ion field-aligned plasma flows. In particular, it is demonstrated that ion upwelling is strongly affected by the ponderomotive force of standing Alfvén waves in the ionospheric Alfvén resonator, and by enhanced electric fields that are produced when electrons are heated by soft electron precipitation. It is verified that the simulations are in qualitative agreement with available theoretical predictions. In the resonator, in addition to the ponderomotive force, a contribution to the upflow comes from centrifugal acceleration. Heating by the current of standing waves increases parallel electric fields and ion pressure gradients only at low altitudes where they are easily balanced by friction with neutrals. This prevents development of fast field-aligned ion flows in the E-layer and lower F-layer.

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Solar activity dependence of ion upflow in the polar ionosphere observed with the European Incoherent Scatter (EISCAT) Tromsø UHF radar

Cited by 29 publications

References 39 publications

CASSIOPE Enhanced Polar Outflow Probe (e-POP) Mission Overview

CASSIOPE Enhanced Polar Outflow Probe (e-POP) Mission Overview

The Earth: Plasma Sources, Losses, and Transport Processes

Simulation of O⁺ upflows created by electron precipitation and Alfvén waves in the ionosphere

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Solar activity dependence of ion upflow in the polar ionosphere observed with the European Incoherent Scatter (EISCAT) Tromsø UHF radar

Cited by 29 publications

References 39 publications

CASSIOPE Enhanced Polar Outflow Probe (e-POP) Mission Overview

CASSIOPE Enhanced Polar Outflow Probe (e-POP) Mission Overview

The Earth: Plasma Sources, Losses, and Transport Processes

Simulation of O+ upflows created by electron precipitation and Alfvén waves in the ionosphere

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Product

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Simulation of O⁺ upflows created by electron precipitation and Alfvén waves in the ionosphere