Energy conversion through mass loading of escaping ionospheric ions for different Kp values

Yamauchi, M.; Slapak, Rikard

doi:10.5194/angeo-36-1-2018

Cited by 8 publications

(17 citation statements)

References 63 publications

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“…The first CME, which arrived late 6 September, had northward IMF with 600‐km/s velocity, whereas the second that arrived late 7 September had southward IMF with 800‐km/s velocity. These features are most likely the causes of higher‐scaled O + outflow because both velocity and IMF are expected to influence O + outflow (Lennartsson et al, ; Yamauchi & Slapak, ). Lennartsson et al () showed that negative IMF B z has a higher influence on the total O + outflow by approximately a factor 3.…”

Section: Discussionmentioning

confidence: 99%

“…However, Nilsson et al () showed that O + is less accelerated during BBFs than the dominating protons. Finally, high O + escape into the inflow solar wind plasma leads to a high mass loading rate and high extraction rate of the solar wind kinetic energy to the ionosphere in a limited and small region at high latitudes (Yamauchi & Slapak, ). Therefore, we expect ground‐induced currents at much higher latitudes than normal.…”

Section: Discussionmentioning

confidence: 99%

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O⁺Escape During the Extreme Space Weather Event of 4–10 September 2017

et al. 2018

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We have investigated the consequences of extreme space weather on ion outflow from the polar ionosphere by analyzing the solar storm that occurred early September 2017, causing a severe geomagnetic storm. Several X‐flares and coronal mass ejections were observed between 4 and 10 September. The first shock—likely associated with a coronal mass ejection—hit the Earth late on 6 September, produced a storm sudden commencement, and began the initial phase of the storm. It was followed by a second shock, approximately 24 hr later, that initiated the main phase and simultaneously the Dst index dropped to Dst = −142 nT and Kp index reached Kp = 8. Using COmposition DIstribution Function data on board Cluster satellite 4, we estimated the ionospheric O+ outflow before and after the second shock. We found an enhancement in the polar cap by a factor of 3 for an unusually high ionospheric O+ outflow (mapped to an ionospheric reference altitude) of 1013 m−2 s−1. We suggest that this high ionospheric O+ outflow is due to a preheating of the ionosphere by the multiple X‐flares. Finally, we briefly discuss the space weather consequences on the magnetosphere as a whole and the enhanced O+ outflow in connection with enhanced satellite drag.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

O⁺Escape During the Extreme Space Weather Event of 4–10 September 2017

et al. 2018

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“…These low-latitude instruments (around 19 ∘ N geographic latitude, and 29 ∘ N geomagnetic latitude) record data in a region where the space weather effects have not been studied sufficiently due to the lack of the historical records (Denardini et al, 2016). Recently, De la Luz et al (2018) registered, for the first time, global space weather effects over Mexico (ionospheric and geomagnetic disturbances, variations in cosmic rays fluxes, and radio communication's interferences) for two particular events: 22 June 2015 and 29 September 2015. It is noteworthy that during this interval of a few days of high solar activity in September 2017, the Mexican region was affected also by other natural hazards.…”

Section: Introductionmentioning

confidence: 99%

Space Weather Events, Hurricanes, and Earthquakes in Mexico in September 2017

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In the interval of 4–10 September 2017, the Sun presented multiple solar flares from active region AR 2673. There were also coronal mass ejections that interacted with the Earth's magnetosphere. This solar activity produced several space weather events. These events were observed with ground‐based instruments of the Mexican Space Weather Service. The Mexican Array RadioTelescope detected highly perturbed solar transits associated with Type I radio emissions from active regions. The Compact Astronomical Low‐frequency, Low‐cost Instrument for Spectroscopy in Transportable Observatories‐Mexican Array RadioTelescope station detected several radio bursts including a Type III associated with the X8.2 flare on 10 September. The magnetometer detected variations reaching a regional K index of 8.3 during the geomagnetic storm. The ionosphere over Mexico was disturbed by different space weather phenomena with the dominant effects of the geomagnetic storm. We used total electron content data to study latitudinal and longitudinal ionospheric effects in this interval. The cosmic rays monitor detected a Forbush decrease associated also with the geomagnetic storm. This low‐latitude instrumental network in Mexico allowed estimating the regional response to space weather events. Coincidentally with the space weather events referred above, there were also two other types of natural hazards affecting the country at that moment, the hurricane Katia category 2 in the Gulf of Mexico, and two major earthquakes (7 and 19 September 2018). The conjunction of these natural phenomena were close to creating a worst‐case scenario in terms of civil protection reaction.

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“…Ion escape during space weather events has additional importance because Schillings et al () found that the escaping O + flux for Kp > 7 can be higher than the predicted values from the exponential Kp dependence for Kp ≤ 7. The results suggest that (1) past ion loss from the ionosphere could have been larger than the above estimate (Yamauchi & Slapak, ) and (2) the energy extraction and relevant space weather hazards in the polar region can be even larger than predicted by any existing model using our knowledge for ordinary conditions of Kp < 7. Indeed, there is no guarantee that the response of the high‐latitude ionosphere to extreme solar and interplanetary space weather conditions stays within the expected range from ordinary active conditions through UV ionization, particle precipitations, and electromagnetic energy input represented by, for example, Akasofu's coupling function (Akasofu, ; Newell et al, , ).…”

Section: Introductionmentioning

confidence: 53%

“…Such a nonlinear dependence on Kp also exponentially enhances energy extraction from the solar wind to the cusp current system through the mass‐loading effect of the escaping ions, i.e., inelastic mixing of escaping ions and incoming solar wind ions (Yamauchi & Slapak, , ), enhancing the risk of space weather hazards in that local region. Thus, the ionosphere plays two important roles in ion escape, one energizing the ionospheric ions through various energization mechanisms (e.g., André & Yau, ) such as Joule heating (Brekke & Rino, ) and the other extracting energy from the solar wind through the mass‐loading effect of the escaping ions.…”

Section: Introductionmentioning

confidence: 99%

Ionospheric Response Observed by EISCAT During the 6–8 September 2017 Space Weather Event: Overview

et al. 2018

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We present ionospheric plasma conditions observed by the EISCAT radars in Tromsø and on Svalbard, covering 68°–81° geomagnetic latitude, during 6–8 September 2017. This is a period when X2.2 and X9.3 X‐ray flares occurred, two interplanetary coronal mass ejections (ICMEs) arrived at the Earth accompanied by enhancements of MeV‐range energetic particle flux in both the solar wind (SEP event) and inner magnetosphere, and an AL < −2,000 substorm took place. (1) Both X flares caused enhancement of ionospheric electron density for about 10 min. The X9.3 flare also increased temperatures of both electrons and ions over 69°–75° geomagnetic latitude until the X‐ray flux decreased below the level of X‐class flares. However, the temperature was not enhanced after the previous X2.2 flare in the prenoon sector. (2) At around 75° geomagnetic latitude, the prenoon ion upflow flux slightly increased the day after the X9.3 flare, which is also after the first ICME and a SEP event, while no outstanding enhancement was found at the time of these X flares. (3) The upflow velocity sometimes decreased when the interplanetary magnetic field (IMF) turned southward. (4) Before the first ICME arrival after the SEP event under weak IMF with Bz ~0 nT, a substorm‐like expansion of the auroral arc signature took place without local geomagnetic signature near local midnight, while no notable change was observed after the ICME arrival. (5) AL reached <−2,000 nT only after the arrival of the second ICME with strongly southward IMF. Causality connections between the solar/solar wind event and the ionospheric responses remain unclear.

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Energy conversion through mass loading of escaping ionospheric ions for different Kp values

Cited by 8 publications

References 63 publications

O⁺Escape During the Extreme Space Weather Event of 4–10 September 2017

O⁺Escape During the Extreme Space Weather Event of 4–10 September 2017

Space Weather Events, Hurricanes, and Earthquakes in Mexico in September 2017

Ionospheric Response Observed by EISCAT During the 6–8 September 2017 Space Weather Event: Overview

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Energy conversion through mass loading of escaping ionospheric ions for different Kp values

Cited by 8 publications

References 63 publications

O+Escape During the Extreme Space Weather Event of 4–10 September 2017

O+Escape During the Extreme Space Weather Event of 4–10 September 2017

Space Weather Events, Hurricanes, and Earthquakes in Mexico in September 2017

Ionospheric Response Observed by EISCAT During the 6–8 September 2017 Space Weather Event: Overview

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Product

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O⁺Escape During the Extreme Space Weather Event of 4–10 September 2017

O⁺Escape During the Extreme Space Weather Event of 4–10 September 2017