Solar and Heliospheric Observatory

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Artist's conception of the Solar and Heliospheric Observatory (SOHO) spacecraft.

Photosphere of the Sun with limb darkening, image taken by the Solar and Heliospheric Observatory satellite, Oct. 29, 2003.

Solar and Heliospheric Observatory

satellite

Also known as: SOHO

Written by David M. Harland

Fact-checked by The Editors of Encyclopaedia Britannica

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Solar and Heliospheric Observatory (SOHO), satellite managed jointly by the European Space Agency (ESA) and the U.S. National Aeronautics and Space Administration (NASA) that is equipped with a battery of novel instruments to study the Sun.

SOHO was launched by NASA on an Atlas rocket on Dec. 2, 1995. In order to provide continuous observations, it was maneuvered to orbit the first Lagrangian point (L1), a point some 1.5 million km (900,000 miles) from Earth toward the Sun where the gravitational attraction of Earth and the Sun combine in such a way that a small body remains approximately at rest relative to both. SOHO’s suite of 11 instruments included three to conduct helioseismological investigations of the structure and dynamics of the solar interior, from the core out to the surface; five to study the means by which the corona is heated; and three to study where and how the solar wind is accelerated away from the Sun. The goal was to start observations near the minimum of the solar cycle in order to monitor the buildup to the next maximum.

In monitoring the corona, SOHO caught a surprisingly large number of comets (one every few weeks) diving into the Sun. More than 2,000 comets have been found in SOHO images, making it the top “discoverer” of comets of all time.

After an incorrect command on June 25, 1998, caused SOHO to spin out of control, the spacecraft was slowly nursed back to life. In December 2000, when the Sun was at its most active, SOHO undertook solar wind studies in coordination with Ulysses, which was then flying high in solar orbit over the Sun’s southern polar region, in order to construct three-dimensional maps.

Among its many achievements, SOHO found that sunspots are shallow and that a hurricane-like structure at their base keeps them stable. Helioseismological data were used to make images of the far side of the Sun. Sunspot activity on the far side of the Sun could also be monitored by observing how the ultraviolet light emitted by the sunspots interacts with nearby hydrogen gas. SOHO also determined that the solar wind flows outward by waves in vibrating magnetic field lines.

David M. Harland

solar wind

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solar wind

astronomy

Written and fact-checked by The Editors of Encyclopaedia Britannica

Last Updated: Mar 10, 2025 • Article History

Related Topics:: aurora; interplanetary medium; solar wind power satellite; reconnection; interplanetary magnetic field

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solar wind, flux of particles, chiefly protons and electrons together with nuclei of heavier elements in smaller numbers, that are accelerated by the high temperatures of the solar corona, or outer region of the Sun, to velocities large enough to allow them to escape from the Sun’s gravitational field. The solar wind is responsible for creating the tail of Earth’s magnetosphere and the tails of comets, both of which face away from the Sun. At a distance of one astronomical unit (AU; the mean distance between Earth and the Sun, about 150 million km [93 million miles]), during a relatively quiet period, the wind contains approximately 1 to 10 protons per cubic centimetre moving outward from the Sun at velocities of 350 to 700 km (about 220 to 440 miles) per second; this creates a positive ion flux of 10⁸ to 10⁹ ions per square centimetre per second, each ion having an energy equal to at least 15 electron volts. During solar flares, the proton velocity, flux, plasma temperature, and associated turbulence increase substantially.

There are two solar winds: a fast, uniform, and steady wind, blowing at 800 km (500 miles) per second, and a slow, gusty, and sporadic wind, with about half the speed of the fast one. The two winds originate at different places on the Sun and accelerate to terminal velocity at different distances from it. The distribution of the two solar wind sources depends on the 11-year solar activity cycle.

When the solar wind encounters Earth’s magnetic field, a shock wave results, the nature of which is not fully understood. As the solar wind spreads out into an increasing volume, its density and pressure become less. Eventually the pressure of the solar wind becomes comparable to that of the interstellar medium. The termination shock, where the solar wind slows because it encounters the interstellar medium, has been measured at about 94 and 84 AU by the Voyager 1 and 2 spacecraft, respectively.

1 July 2002: The Solar and Heliospheric Observatory (SOHO) satellite reveals a massive solar eruption more than 30 times the Earth's diameter. The eruption formed when a loop of a magnetic field over the surface of the Sun trapped hot gas.

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This article was most recently revised and updated by Richard Pallardy.