Solar wind: Difference between revisions
No edit summary |
No edit summary |
||
Line 12: | Line 12: | ||
===With Magnetospheres=== | ===With Magnetospheres=== | ||
The most relevant interaction to us on Earth is the interaction of the solar wind with magnetospheres. A magnetosphere is the region of space surrounding an object where the dominant magnetic field is the field produced by that object. The Earth produces a magnetosphere with a field similar to a bar magnet. Through a complex interaction, the solar wind "carries" some of the Sun's magnetic field with it. When it arrives at Earth, both the energy of the particles and magnetic field bombard the magnetic field of the Earth, and change its shape. The particles of the solar wind are deflected by the magnetic field of the Earth due to the Lorentz force. The magnetic field of the Earth also traps some of the particles in orbits called 'radiation belts.' Satellites with orbits through these regions must have additional shielding against radiation. Some particles of the solar wind still leak into the magnetosphere, especially when solar storms or mass coronal ejections increase the speed or quantity of the solar wind. When they do, different phenomena related to electricity and magnetism occur. One of such phenomena is the 'Aurora borealis,' or the Northern Lights. This bright display is caused when charged particles enter the atmosphere at certain regions and ionize other atoms. Another result of increased solar activity is geomagnetic storms. Geomagnetic storms refer to the ability of strong solar winds to cause changes in the Earth's magnetic field. At a basic level, the cause of the 'storm' is the changing magnetic field of the Earth, which creates additional electromagnetic forces. These forces are strong enough to disrupt GPS signals, create measurable forces on satellites, and induce currents in power grids, causing damage. | The most relevant interaction to us on Earth is the interaction of the solar wind with magnetospheres. A magnetosphere is the region of space surrounding an object where the dominant magnetic field is the field produced by that object. The Earth produces a magnetosphere with a field similar to a bar magnet. Through a complex interaction, the solar wind "carries" some of the Sun's magnetic field with it. When it arrives at Earth, both the energy of the particles and magnetic field bombard the magnetic field of the Earth, and change its shape. [[File:SunEarth3_2.gif|thumb|400px|An artist's depiction of the Earth's magnetosphere]] The particles of the solar wind are deflected by the magnetic field of the Earth due to the Lorentz force. The magnetic field of the Earth also traps some of the particles in orbits called 'radiation belts.' Satellites with orbits through these regions must have additional shielding against radiation. Some particles of the solar wind still leak into the magnetosphere, especially when solar storms or mass coronal ejections increase the speed or quantity of the solar wind. When they do, different phenomena related to electricity and magnetism occur. One of such phenomena is the 'Aurora borealis,' or the Northern Lights. This bright display is caused when charged particles enter the atmosphere at certain regions and ionize other atoms. Another result of increased solar activity is geomagnetic storms. Geomagnetic storms refer to the ability of strong solar winds to cause changes in the Earth's magnetic field. At a basic level, the cause of the 'storm' is the changing magnetic field of the Earth, which creates additional electromagnetic forces. These forces are strong enough to disrupt GPS signals, create measurable forces on satellites, and induce currents in power grids, causing damage. | ||
Revision as of 20:03, 4 December 2015
--Cradford6 (talk) 18:58, 4 December 2015 (EST)Caelan Radford
The solar wind is a phenomena created by charged particles ejected by the Sun. It is mainly consisted of particles including electrons, protons, and alpha particles (helium nuclei). The constant stream of particles can reach speeds up to millions of miles per hour and make up the make up the medium of the solar system. The solar wind radiates outward from the sun until a radius where the force exerted by the solar wind equals the force exerted by the interstellar medium. This radius is the heliopause, the outer edge of the Solar System.
Cause
Solar wind is created by complex electromagnetic forces in the atmosphere of the Sun. The outer region of the Sun's atmosphere, the corona, is the source of the solar wind. The source of the force propelling the solar wind is a modern mystery; the thermal energy of the corona is not large enough to account for the speed of the particles (even though the corona is around a million degrees Celsius). It is hypothesized that the force must be a powerful magnetic force, but the source and mechanism of the force is not well understood.
Interactions
With Magnetospheres
The most relevant interaction to us on Earth is the interaction of the solar wind with magnetospheres. A magnetosphere is the region of space surrounding an object where the dominant magnetic field is the field produced by that object. The Earth produces a magnetosphere with a field similar to a bar magnet. Through a complex interaction, the solar wind "carries" some of the Sun's magnetic field with it. When it arrives at Earth, both the energy of the particles and magnetic field bombard the magnetic field of the Earth, and change its shape.
The particles of the solar wind are deflected by the magnetic field of the Earth due to the Lorentz force. The magnetic field of the Earth also traps some of the particles in orbits called 'radiation belts.' Satellites with orbits through these regions must have additional shielding against radiation. Some particles of the solar wind still leak into the magnetosphere, especially when solar storms or mass coronal ejections increase the speed or quantity of the solar wind. When they do, different phenomena related to electricity and magnetism occur. One of such phenomena is the 'Aurora borealis,' or the Northern Lights. This bright display is caused when charged particles enter the atmosphere at certain regions and ionize other atoms. Another result of increased solar activity is geomagnetic storms. Geomagnetic storms refer to the ability of strong solar winds to cause changes in the Earth's magnetic field. At a basic level, the cause of the 'storm' is the changing magnetic field of the Earth, which creates additional electromagnetic forces. These forces are strong enough to disrupt GPS signals, create measurable forces on satellites, and induce currents in power grids, causing damage.
Other Objects
If an object in the Solar System is not protected by a strong magnetic field, it is bombarded by the solar wind. This force is the cause of the visible tails on comets. The solar wind is bombarding the comet and transferring energy to small particles, which creates a tail on the comet that always points away from the sun. Other larger objects are affected as well. Mars, for example, has a relatively weak magnetosphere due to an apparent lack of a liquid core. Because of this, the solar wind bombards Mars and transfers energy to atoms in its atmosphere, driving them into space. NASA's Mars Atmosphere and Volatile Evolution mission has shown Mars loses more mass from its atmosphere during solar storms, suggesting the solar wind had a large role in changing the atmosphere of Mars to what it is today. Manmade objects are subject to the solar wind as well. Satellites must be able to withstand the radiation. There have also been many proposed designs for spacecraft with 'sails' which take advantage of the energy of solar wind either using electric or magnetic fields to capture the particles and 'steal' their energy.
Examples
Be sure to show all steps in your solution and include diagrams whenever possible
Simple
Middling
Difficult
Connectedness
- How is this topic connected to something that you are interested in?
- How is it connected to your major?
- Is there an interesting industrial application?
History
Put this idea in historical context. Give the reader the Who, What, When, Where, and Why.
See also
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?
Further reading
Books, Articles or other print media on this topic
External links
References
This section contains the the references you used while writing this page