 | This article has multiple issues. Please helpimprove it or discuss these issues on thetalk page.(Learn how and when to remove these messages) (Learn how and when to remove this message)
|
.gif)
Insolar physics, asolar particle event (SPE), also known as asolar energetic particle event orsolar radiation storm,[a][1] is asolar phenomenon which occurs when particles emitted by theSun, mostlyprotons, become accelerated either in the Sun'satmosphere during asolar flare or ininterplanetary space by acoronal mass ejectionshock. Other nuclei such ashelium andHZE ions may also be accelerated during the event. These particles can penetrate the Earth's magnetic field and cause partialionization of theionosphere. Energetic protons are a significant radiation hazard tospacecraft andastronauts.
SPEs occur whencharged particles in the Sun's atmosphere are accelerated to extremely high velocities. These charged particles, referred to assolar energetic particles, can escape into interplanetary space where they follow theinterplanetary magnetic field.
When solar energetic particles interact with theEarth's magnetosphere, they are guided by the Earth's magnetic field towards the North and South poles where they can penetrate into the upper atmosphere.[2]
The physical mechanism behind the acceleration of solar energetic particles leading up to SPEs is currently debated. However, SPEs can generally be divided into two classesbased on their acceleration mechanisms.[citation needed]
Gradual SPEs are thought to involve the acceleration of particles byshocks driven bycoronal mass ejections in the uppercorona. They are associated withtype II radio bursts and are characterized by elemental abundances, charge states, and temperatures similar to that of the ambient corona. These events produce the highest particle intensities near Earth.
Impulsive SPEs are thought to involve the acceleration of particles mostly by processes associated withmagnetic reconnection and wave-particle interactions at the locations ofsolar flares. They are associated with short-duration flare emissions at low altitudes andtype III radio bursts. They are less intense near Earth than gradual events.An additional hybrid class has been identified which involves characteristics of both gradual and impulsive events.[3][4]
Protons accelerated during an SPE normally have insufficient energy to penetrate the Earth's magnetic field. However, during unusually strong flares, protons can be accelerated to sufficient energies to reach the Earth's magnetosphere and ionosphere around theNorth Pole andSouth Pole.
Energetic protons that are guided into the polar regions collide with atmospheric constituents and release their energy through the process of ionization. The majority of the energy is deposited in the extreme lower region (D-region) of theionosphere (around 50–80 km in altitude). This area is particularly important toionospheric radio communications because this is the area where most of the absorption of radio signal energy occurs. The enhanced ionization produced by incoming energetic protons increases the absorption levels in the lower ionosphere and can have the effect of completely blocking all ionospheric radio communications through the polar regions. Such events are known as polar cap absorption events. These events commence and last as long as the energy of incoming protons at approximately greater than 10MeV (million electron volts) exceeds roughly 10 pfu (particle flux units or particles sr−1 cm−2 s−1) atgeosynchronous satellite altitudes.
Polar cap absorption events and the associated HF radio blackout pose unique problems to commercial and military aviation. Routes that transitpolar regions, especially above about 82-degrees north latitude, can only rely on HF radio communications. Hence, if polar cap absorption events are ongoing or forecast, commercial airlines are required to redirect their routes such that HF communications remain viable.[5][6]
Extremely intense SPEs capable of producing energetic protons with energies in excess of 200 MeV can increase neutron count rates at ground levels through secondary radiation effects. These rare events are known asground level enhancements (or GLEs).[7] Presently, 73 GLE events are known.[8]The strongest known GLE event was detected on 23-Feb-1956.[9]Some events produce large amounts of HZE ions, although their contribution to the total radiation is small compared to the level of protons.[10]
Solar particle events are thought to be responsible forMiyake events, observed sharp enhancements of the concentration ofcertain isotopes found in tree rings. These events, discovered by physicist Fusa Miyake, have enabled the dating of a number of past SPEs to specific years.
High altitude commercial transpolar aircraft flights have measured increases in radiation during these events. In 2019, the International Civil Aviation Organization introduced the Space Weather Centres that publish space weather advisories pertinent to international air navigation, describing the effects of space weather on aviation and possible mitigation actions.[11] Aircraft flights away from the polar regions are far less likely to see an impact from SPEs.
Significant proton radiation exposure can be experienced by astronauts who are outside of the protective shield of the Earth's magnetosphere, such as an astronaut in-transit to, or located on, the Moon. However, the effects can be minimized if the astronauts are in alow Earth orbit and remain confined to the most heavily shielded regions of their spacecraft. Proton radiation levels in low Earth orbit increase with orbital inclination. Therefore, the closer a spacecraft approaches the polar regions, the greater the exposure to energetic proton radiation will be.
Energetic protons from SPEs can electrically charge spacecraft to levels that can damage electronic components. They can also cause electronic components to behave erratically. For example,solid state memory on spacecraft can be altered, which may cause data or software contamination and result in unexpected (phantom) spacecraft commands being executed. Energetic proton storms also destroy the efficiency of thesolar panels that are designed to collect and convert sunlight to electricity. During years of exposure to energetic proton activity from the Sun, spacecraft can lose a substantial amount of electrical power that may require important instruments to be turned off.
When energetic protons strike the sensitive optical electronics in spacecraft (such as star trackers and other cameras) flashes occur in the images being captured. The effect can be so pronounced that during extreme events, it is not possible to obtain quality images of the Sun or stars. This can cause spacecraft to lose their orientation, which is critical if ground controllers are to maintain control.
Major SPEs can be associated with geomagnetic storms that can cause widespread disruption toelectrical grids. However, proton events themselves are not responsible for producing anomalies in power grids, nor are they responsible for producing geomagnetic storms. Power grids are only sensitive to fluctuations in the Earth's magnetic field.
{{cite book}}:ISBN / Date incompatibility (help)