The Center for Astrophysics | Harvard & Smithsonian
The Center for Astrophysics | Harvard & Smithsonian
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Solar & Heliospheric Physics

The Sun is the best laboratory we have for studying stars and how they influence the planets orbiting them. Space- and ground-based observatories monitor day-to-day fluctuations in the Sun’s light, atmosphere, and magnetic field. In addition, we have roughly four centuries of historical sunspot data, tracing the history of magnetic activity on the Sun. These observations provide essential information about the physical processes on the Sun, which reveal its history and future. In addition, they reveal the ways the Sun influences Earth and other Solar System bodies, as well as giving us insight into the behavior of other stars throughout the cosmos.

Our Work

Center for Astrophysics | Harvard & Smithsonian scientists work in many areas of solar and heliospheric physics:

3 Million°
Approximate temperature, in Kelvin, of the sun’s corona, nearly 500 times that of the sun’s surface

The Mysterious Star We Know Best

The Sun is only 150 million kilometers (93 million miles) away from Earth, which is a tiny distance in cosmic terms. That relative closeness lets us observe the Sun to a level of precision we can’t achieve for any other star.

The field of solar and heliospheric physics enfolds the processes that make the Sun shine, produce its magnetic field, shape its atmosphere, and send particles across the Solar System, which is called the solar wind. Solar physics involves understanding the internal processes of the Sun, which produce its magnetic field, and the dynamics of its atmosphere. The range of influence for the solar wind is called the heliosphere, which extends far past the orbit of Pluto.

  • While we can’t see inside the Sun directly, solar physicists can still infer what’s going on using the sound waves traveling through the interior. These waves produce variations on the Sun’s surface, much like earthquakes. Helioseismology is the study of these waves and what they tell us about the Sun’s interior. [ link to “stellar structure” page ]

  • The Sun generates a powerful magnetic field, which in turn accelerates electrically charged particles — electrons and ions — in its atmosphere to high speeds. The magnetic field’s intensity cycles over a period of eleven years. That produces fluctuating numbers of sunspots, which are dark places on the Sun where the field is particularly intense. At periods of higher activity, the Sun produces more of the outbursts known as coronal mass ejections, which can disrupt communications and power grids on Earth. For that reason, solar physicists study the magnetic cycle to try to predict these events.

  • Perhaps the biggest mystery about the Sun is the temperature of its atmosphere. While the surface is around 5500º C (9900º F), the solar atmosphere rises to millions of degrees for reasons we don’t fully understand. The outermost layer of the atmosphere, the Sun’s corona, is one of the Solar System’s most extreme environments, with high temperatures stripping electrons from atoms and magnetic fields whipping particles to high speeds.

  • The hot atmosphere is too dynamic for the Sun’s gravity to hold in entirely. As a result, the Sun is always shedding charged particles — mostly electrons and protons — which constitute the solar wind. Those particles flow into the Solar System, where they interact with the magnetic fields of planets like Earth, creating auroras. The solar wind also pummels comets, producing their characteristic tails, and bombards asteroids, shifting their orbits and rotation rates. The range of influence of the solar wind extends far beyond the orbit of Pluto, and defines the heliosphere.

 

artistic depiction of the Parker Solar Probe

This artistic depiction of NASA's Parker Solar Probe shows the spacecraft on its approach to the Sun. The probe passes through the outermost layers of the solar atmosphere, collecting particles and taking measurements to understand solar weather.

Credit: NASA
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AIR-Spec/ASPIRE

The Sun generates a powerful magnetic field, which drives the solar storms that occasionally batter the worlds of the Solar System. However, the magnetic fields in the solar corona are very hard to observe, despite their importance in creating space weather. For that reason, scientists at the Center for Astrophysics | Harvard & Smithsonian developed the Airborne Infrared Spectrometer (AIR-Spec), an instrument carried aboard an airplane to measure the properties and effects of the coronal magnetic field during solar eclipses, where the corona is most plainly visible. AIR-Spec was inaugurated during the 2017 total solar eclipse visible across the United States; an improved version will fly during the 2019 eclipse visible from South America and the southern Pacific Ocean.

Visit the AIR-Spec Website
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Deep Space Climate Observatory (DSCOVR)

Understanding climate change requires an understanding of Earth as a planet. The Deep Space Climate Observatory (DSCOVR) is a joint NASA-NOAA space observatory with two tasks: real-time tracking of conditions on Earth, and monitoring the solar wind — electrically charged particles streaming from the Sun. DSCOVR’s vantage point is a stable orbit between Earth and the Sun, allowing it to give us as much as an hour’s warning before solar storms hit, in addition to regularly-updated full-Earth images. Center for Astrophysics | Harvard & Smithsonian researchers collaborated on one of DSCOVR’s solar-wind instruments.

Visit the DSCOVR Website
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High Resolution Coronal Imager (Hi-C)

Why the Sun’s corona — the wispy outermost atmosphere — is so much hotter than its surface stands as a big mystery in solar science. NASA’s High-Resolution Coronal Imager (Hi-C) is an ultraviolet telescope designed to help solve the mystery, and understand the processes by which the Sun sends violent storms of particles into the Solar System. Since most of the light from the Sun’s atmosphere is blocked by air molecules on Earth, Hi-C is carried on a short-flight rocket into Earth’s upper atmosphere. Since 2012, Hi-C has flown three times, providing the highest resolution images of the corona and revealing new details in the Sun’s atmosphere. Hi-C is jointly operated by NASA's Marshall Space Flight Center (MSFC) and the Center for Astrophysics | Harvard & Smithsonian, with contributions from other researchers around the world.

Visit the Hi-C Website
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Hinode

The Sun is the closest star to Earth, and the single most important influence on the worlds of the Solar System in terms of the light and particles it emits. Studying the Sun, in other words, helps us understand the habitability of Earth, but also other stars elsewhere in the universe. One important solar observatory is the Japanese Aerospace Exploration Agency’s Hinode spacecraft, which carries three powerful instruments to study the Sun in X-rays, visible light, and ultraviolet light. Center for Astrophysics | Harvard & Smithsonian engineers collaborated in the development of the X-ray Telescope for the spacecraft. Hinode has been observing the Sun continuously since its launch in 2006, providing important day-by-day information about our host star’s activity.

Visit the Hinode/XRT Website
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Interface Region Imaging Spectrograph (IRIS)

The Sun’s surface is incandescently hot, but its outer atmosphere — the corona — is far hotter, for reasons astronomers don’t fully understand. NASA’s Interface Region Imaging Spectrograph (IRIS) is an orbiting observatory designed to study the mysterious transitional part of the Sun’s lower atmosphere, where the heating of the material flowing into the corona takes place. Understanding the heating process may help predict solar storms as well. Scientists and engineers from the Center for Astrophysics | Harvard & Smithsonian contributed to the telescope for IRIS. In addition, CfA researchers participate in telescope operations, and provide scientific support and analysis for the observatory’s work.

Visit the IRIS Website
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Parker Solar Probe

What is driving the solar wind? Some particles in the Sun’s atmosphere gain enough speed to escape the Sun’s gravitational pull and bombard the worlds of the Solar System, but the processes behind the phenomenon are still mysterious. To solve that mystery, NASA’s Parker Solar Probe spacecraft was built to fly through the Sun’s atmosphere, performing the first up-close solar measurements in history. Scientists and engineers at the Center for Astrophysics | Harvard & Smithsonian built the Solar Probe Cup (SPC) instrument for the spacecraft. SPC is part of the Solar Wind Electrons Alphas and Protons (SWEAP) instrument suite used to sample particles directly from the Sun’s atmosphere for analysis.

Visit the Parker Solar Probe SWEAP Website
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Solar and Heliospheric Observer (SOHO)

The Sun is the only star we can study in detail, providing us with the opportunity to observe stellar internal structure, magnetic fields, and atmosphere. Solar and Heliospheric Observer (SOHO), a space observatory jointly operated by NASA and the European Space Agency (ESA), has been one of the best sources for that knowledge. Originally designed to operate for two years, SOHO has provided daily data on the Sun for more than twenty years, making it one of the longest running space observatories. During that time, SOHO has monitored the Sun’s atmosphere, surface, and seismology, using a wide range of scientific instruments. Scientists and engineers at the Center for Astrophysics | Harvard & Smithsonian developed the instrument SOHO uses to measure the ultraviolet spectrum of the Sun.

Visit the SOHO/UVCS Website
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Solar Dynamics Observatory (SDO)

The Sun is both life-giving and dangerous. Variations in the Sun’s light and wind have profound effects on Earth, while solar storms can wreak havoc on power and communications systems. NASA’s Solar Dynamics Observatory (SDO) is a spacecraft dedicated to studying these potentially dangerous variations, and the magnetic fields that drive them. Engineers at the Center for Astrophysics | Harvard & Smithsonian contributed to the design and construction of the four Atmospheric Imaging Array (AIA) telescopes. AIA is one of the three major experiments carried by SDO.

Visit the SDO Website
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The Coronal Spectrographic Imager in the EUV (COSIE)

Space weather is a matter of concern for all of us: storms from the Sun can disrupt global communications and electrical power grids. However, we still don’t understand exactly how these storms are formed, much less how to predict them. To complement existing solar observations, the Coronal Spectrographic Imager in the EUV (COSIE) is a proposed telescope for use on the International Space Station, designed to view the Sun in extreme ultraviolet (EUV) light. If the project is selected, COSIE would provide a thousand times improvement in EUV observations of the Sun’s atmosphere over existing telescopes, providing a better means of spotting and predicting solar storms. COSIE is a proposal by researchers at the Center for Astrophysics | Harvard & Smithsonian, who are also developing the technology to make the instrument possible.
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Transition Region and Coronal Explorer (TRACE)

The Transition Region and Coronal Explorer (TRACE) was a space-based solar observatory which operated from 1998 through 2010. TRACE primarily observed in ultraviolet light to map the small-scale structure of the eruptions of gas on the Sun’s surface known as coronal loops, as well as the “transition region” where the Sun’s atmosphere increases in temperature dramatically. The telescope was a joint project of the Center for Astrophysics | Harvard & Smithsonian, NASA, and Lockheed Martin. The long duration of the mission enabled TRACE to be the second space-based solar observatory to monitor an entire sunspot cycle, which provided valuable information on how the Sun’s magnetic field affects its atmosphere.
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Wind Spacecraft

NASA’s Wind Spacecraft has observed the Sun ever since its launch in 1994, making it one of the most successful and longest-running space observatories. Orbiting at a special location between Earth and the Sun, Wind measures the properties of the electrically-charged particles known as the solar wind. Scientists from the Center for Astrophysics | Harvard & Smithsonian currently operate one of Wind’s instruments, which collects ions from the solar wind. Data from the spacecraft have been used in over 4,500 journal articles, doctoral dissertations, and other scientific publications. Wind was built to last: it has enough fuel to keep operating for another 50 years.

Visit the Wind Spacecraft Website
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