Solar physics is the branch of astrophysics that specializes in the study of the Sun. It deals with detailed measurements that are possible only for our closest star. It intersects with many disciplines of pure physics, astrophysics, and computer science, including fluid dynamics, plasma physics including magnetohydrodynamics, seismology, particle physics, atomic physics, nuclear physics, stellar evolution, space physics, spectroscopy, radiative transfer, applied optics, signal processing, computer vision, computational physics, stellar physics and solar astronomy.

Because the Sun is uniquely situated for close-range observing (other stars cannot be resolved with anything like the spatial or temporal resolution that the Sun can), there is a split between the related discipline of observational astrophysics (of distant stars) and observational solar physics.

The study of solar physics is also important as it provides a "physical laboratory" for the study of plasma physics.[1]

History

Ancient times

Babylonians were keeping a record of solar eclipses, with the oldest record originating from the ancient city of Ugarit, in modern-day Syria. This record dates to about 1300 BC.[2] Ancient Chinese astronomers were also observing solar phenomena (such as solar eclipses and visible sunspots) with the purpose of keeping track of calendars, which were based on lunar and solar cycles. Unfortunately, records kept before 720 BC are very vague and offer no useful information. However, after 720 BC, 37 solar eclipses were noted over the course of 240 years.[3]

Medieval times

Astronomical knowledge flourished in the Islamic world during medieval times. Many observatories were built in cities from Damascus to Baghdad, where detailed astronomical observations were taken. Particularly, a few solar parameters were measured and detailed observations of the Sun were taken. Solar observations were taken with the purpose of navigation, but mostly for timekeeping. Islam requires its followers to pray five times a day, at specific position of the Sun in the sky. As such, accurate observations of the Sun and its trajectory on the sky were needed. In the late 10th century, Iranian astronomer Abu-Mahmud Khojandi built a massive observatory near Tehran. There, he took accurate measurements of a series of meridian transits of the Sun, which he later used to calculate the obliquity of the ecliptic.[4] Following the fall of the Western Roman Empire, Western Europe was cut from all sources of ancient scientific knowledge, especially those written in Greek. This, plus de-urbanisation and diseases such as the Black Death led to a decline in scientific knowledge in Medieval Europe, especially in the early Middle Ages. During this period, observations of the Sun were taken either in relation to the zodiac, or to assist in building places of worship such as churches and cathedrals.[5]

Renaissance period

In astronomy, the renaissance period started with the work of Nicolaus Copernicus. He proposed that planets revolve around the Sun and not around the Earth, as it was believed at the time. This model is known as the heliocentric model.[6] His work was later expanded by Johannes Kepler and Galileo Galilei. Particularly, Galilei used his new telescope to look at the Sun. In 1610, he discovered sunspots on its surface. In the autumn of 1611, Johannes Fabricius wrote the first book on sunspots, De Maculis in Sole Observatis ("On the spots observed in the Sun").[7]

Modern times

Modern day solar physics is focused towards understanding the many phenomena observed with the help of modern telescopes and satellites. Of particular interest are the structure of the solar photosphere, the coronal heat problem and sunspots.

Research

The Solar Physics Division of the American Astronomical Society boasts 555 members (as of May 2007), compared to several thousand in the parent organization.[8]

A major thrust of current (2009) effort in the field of solar physics is integrated understanding of the entire Solar System including the Sun and its effects throughout interplanetary space within the heliosphere and on planets and planetary atmospheres. Studies of phenomena that affect multiple systems in the heliosphere, or that are considered to fit within a heliospheric context, are called heliophysics, a new coinage that entered usage in the early years of the current millennium.

Space based

Helios

Helios-A and Helios-B are a pair of spacecraft launched in December 1974 and January 1976 from Cape Canaveral, as a joint venture between the German Aerospace Center and NASA. Their orbits approach the Sun closer than Mercury. They included instruments to measure the solar wind, magnetic fields, cosmic rays, and interplanetary dust. Helios-A continued to transmit data until 1986.[9][10]

SOHO

Image of SOHO spacecraft

The Solar and Heliospheric Observatory, SOHO, is a joint project between NASA and ESA that was launched in December 1995. It was launched to probe the interior of the Sun, make observations of the solar wind and phenomena associated with it and investigate the outer layers of the Sun.[11]

HINODE

A publicly funded mission led by the Japanese Aerospace Exploration Agency, the HINODE satellite, launched in 2006, consists of a coordinated set of optical, extreme ultraviolet and X-ray instruments. These investigate the interaction between the solar corona and the Sun's magnetic field.[12][13]

SDO

The SDO satellite

The Solar Dynamics Observatory (SDO) was launched by NASA in February 2010 from Cape Canaveral. The main goals of the mission are understanding how solar activity arises and how it affects life on Earth by determining how the Sun's magnetic field is generated and structured and how the stored magnetic energy is converted and released into space.[14]

PSP

The Parker Solar Probe (PSP) was launched in 2018 with the mission of making detailed observations of the outer solar corona. It has made the closest approaches to the Sun of any artificial object.[15]

Ground based

ATST

The Advanced Technology Solar Telescope (ATST) is a solar telescope facility that is under construction in Maui. Twenty-two institutions are collaborating on the ATST project, with the main funding agency being the National Science Foundation.[16]

SSO

Sunspot Solar Observatory (SSO) operates the Richard B. Dunn Solar Telescope (DST) on behalf of the NSF.

Big Bear

The Big Bear Solar Observatory in California houses several telescopes including the New Solar Telescope(NTS) which is a 1.6 meter, clear-aperture, off-axis Gregorian telescope. The NTS saw first light in December 2008. Until the ATST comes on line, the NTS remains the largest solar telescope in the world. The Big Bear Observatory is one of several facilities operated by the Center for Solar-Terrestrial Research at New Jersey Institute of Technology (NJIT).[17]

Other

EUNIS

The Extreme Ultraviolet Normal Incidence Spectrograph (EUNIS) is a two channel imaging spectrograph that first flew in 2006. It observes the solar corona with high spectral resolution. So far, it has provided information on the nature of coronal bright points, cool transients and coronal loop arcades. Data from it also helped calibrating SOHO and a few other telescopes.[18]

See also

Further reading

  • Mullan, Dermott J. (2009). Physics of the Sun: A First Course. Taylor & Francis. ISBN 978-1-4200-8307-1.
  • Zirin, Harold (1988). Astrophysics of the Sun. Cambridge University Press. ISBN 0-521-30268-4.

References

  1. Solar Physics, Marshall Space Flight Center. "Why we study the Sun". NASA. Retrieved 28 January 2014.
  2. Littman, M.; Willcox, F; Espenak, F. (2000). Totality: Eclipses of the Sun (2nd ed.). Oxford University Press.
  3. Sten, Odenwald. "Ancient eclipses in China". NASA Goddard Space Flight Center. Retrieved 17 January 2014.
  4. "Arab and Islamic astronomy". StarTeach Astronomy Education. Retrieved 18 January 2014.
  5. Portal to the heritage of astronomy. "Theme: medieval astronomy in Europe". UNESCO. Retrieved 18 January 2014.
  6. Taylor Redd, Nola. "Nicolaus Copernicus biography: facts & discoveries". Space.com. Retrieved 18 January 2014.
  7. "Sunspots". The Galileo Project. Retrieved 18 January 2014.
  8. Solar Physics Division. "Membership". American Astronomical Society. Archived from the original on 22 March 2014. Retrieved 28 January 2014.
  9. "Helios-A – Trajectory Details". National Space Science Data Center. NASA. Retrieved May 26, 2021.
  10. "Helios-B – Trajectory Details". National Space Science Data Center. NASA. Retrieved May 26, 2021.
  11. SOHO, Solar and Heliospheric Observatory. "About the SOHO mission". ESA; NASA. Retrieved 17 January 2014.
  12. Solar Physics Laboratory, Code 671. "HINODE". NASA Goddard Space Flight Centre. Retrieved 17 January 2014.{{cite web}}: CS1 maint: numeric names: authors list (link)
  13. "Hinode". NASA Marshall Space Flight Centre. Retrieved 17 January 2014.
  14. SDO, Solar Dynamics Observatory. "About the SDO mission". NASA Goddard Space Flight Centre. Archived from the original on 30 June 2007. Retrieved 17 January 2014.
  15. "NASA Press Kit: Parker Solar Probe" (PDF). nasa.gov. NASA. August 2018.
  16. "Welcome to the ATST". NSO. Retrieved 17 January 2014.
  17. "Center for Solar-Terrestrial Research Welcome!". NJIT. Retrieved 29 May 2016.
  18. Sciences and Exploration Directorate, Code 600. "Extreme Ultraviolet Normal Incidence Spectrograph". NASA Goddard Space Flight Centre. Retrieved 17 January 2014.{{cite web}}: CS1 maint: numeric names: authors list (link)
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