The Sun is the
star at the centre
of the
Solar System. The
Earth and other matter (including other
planets,
asteroids,
meteoroids,
comets and
dust)
orbit the Sun,
which by itself accounts for more than 99% of the
solar
system's mass.
Energy from the
Sun—in the form of
insolation
from sunlight—supports
almost all
life
on Earth via
photosynthesis, and drives the Earth's
climate and
weather.
The Sun is sometimes referred to by its
Latin name
Sol or by its
Greek name Helios. Its
astrological
and
astronomical symbol is a
circle
with a point at its center:
The ancient Greeks grouped the Sun together with the other
celestial bodies which moved across the
sky (in relation to
the
starfield), calling them all
planets.
This was before the acceptance of
heliocentrism.
Overview
About 74% of the Sun's mass is
hydrogen,
25% is helium,
and the rest is made up of trace quantities of heavier elements. The Sun has a
spectral class of G2V. "G2" means that it has a surface temperature of
approximately 5,500 K, giving it a
white colour, which, because of atmospheric
scattering, appears yellow. Its spectrum contains
lines
of ionized and neutral metals as well as very weak hydrogen lines. The "V"
suffix indicates that the Sun, like most stars, is a
main
sequence star. This means that it generates its energy by
nuclear fusion of
hydrogen
nuclei into helium
and is in a state of
hydrostatic balance, neither contracting nor expanding over time. There are
more than 100 million G2 class stars in our galaxy. Because of logarithmic size
distribution, the Sun is actually brighter than 85% of the stars in the Galaxy,
most of which are
red dwarfs.[1]
The Sun orbits the centre of the
Milky Way galaxy at a
distance of approximately 25,000 to 28,000
light-years
from the
galactic centre, completing one revolution in about
225–250 million
years. The
orbital speed is 217 km/s, equivalent to one light-year every 1,400 years,
and one
AU every 8 days.[2]
The Sun is a
third generation star, whose formation may have been triggered by shockwaves
from a nearby
supernova. This is suggested by a high
abundance
of
heavy elements such as
gold and
uranium in
the solar system; these elements could most plausibly have been produced by
endergonic
nuclear reactions during a supernova, or by
transmutation via
neutron
absorption inside a massive second-generation star.
Sunlight is the main source of energy to the surface of
Earth. The
solar constant is the amount of power that the Sun deposits per unit area
that is directly exposed to sunlight. The solar constant is equal to
approximately 1,370 watts
per square metre of area at a distance of one
AU from the Sun (that is, on or near Earth). Sunlight on the surface of
Earth is
attenuated by the Earth's atmosphere so that less power arrives at the
surface—closer to 1,000 watts per directly exposed square metre in clear
conditions when the Sun is near the
zenith. This
energy can be harnessed via a variety of natural and synthetic processes—photosynthesis
by plants captures the energy of sunlight and converts it to chemical form
(oxygen and reduced carbon compounds), while direct heating or electrical
conversion by
solar
cells are used by
solar
power equipment to generate
electricity or to do other useful work. The energy stored in
petroleum
and other
fossil
fuels was originally converted from sunlight by
photosynthesis in the distant past.
| Observation data |
| Mean distance from
Earth |
149.6×106 km
(92.95×106
mi)
(8.31 minutes at the
speed of light) |
|
Visual brightness (V) |
−26.8m |
|
Absolute magnitude |
4.8m |
|
Spectral classification |
G2V |
|
Orbital
characteristics |
| Mean distance from
Milky Way
core |
~2.5×1017 km
(26,000-28,000
light-years) |
| Galactic
period |
2.25-2.50×108
a |
| Velocity |
217 km/s
orbit around the center of the Galaxy, 20 km/s relative to average velocity of
other stars in stellar neighborhood |
| Physical characteristics |
| Mean diameter |
1.392×106 km
(109 Earths) |
| Circumference |
4.373×106 km |
| Oblateness |
9×10−6 |
| Surface area |
6.09×1018 m²
(11,900 Earths) |
| Volume |
1.41×1027 m³
(1,300,000 Earths) |
| Mass |
1.988 435×1030 kg
(332,946 Earths) |
| Density |
1,408 kg/m³ |
| Surface
gravity |
273.95 m s-2 (27.9
g) |
Escape velocity
from the surface |
617.54 km/s (55 Earths) |
| Surface temperature |
5785 K |
| Temperature of
corona |
5 MK |
| Core temperature |
~13.6 MK |
| Luminosity (Lsol) |
3.827×1026 W
~3.75×1028 lm
(~98 lm/W
efficacy) |
| Mean
Intensity (Isol) |
2.009×107 W m-2 sr-1 |
|
Rotation
characteristics |
| Obliquity |
7.25°
(to the
ecliptic)
67.23° (to the
galactic
plane) |
|
Right ascension of North pole[41] |
286.13°
(19 h 4 min 30 s) |
| Declination of North pole |
+63.87°
(63°52' North) |
|
Rotation period at equator |
25.38 days
(25 d 9 h 7 min 13 s)[41] |
| Rotation velocity at equator |
7174 km/h |
|
Photospheric composition (by mass) |
| Hydrogen |
73.46 % |
| Helium |
24.85 % |
| Oxygen |
0.77 % |
| Carbon |
0.29 % |
| Iron |
0.16 % |
| Neon |
0.12 % |
| Nitrogen |
0.09 % |
| Silicon |
0.07 % |
| Magnesium |
0.05 % |
| Sulphur |
0.12 % |
|
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|
A recent theory claims that the sun's temperature and power output varies
over periods of thousands of years (see below on Solar cycles).
Sunlight has several interesting biological properties. The ratio of
lumens to watts is comparable to the best
fluorescent lights, which means that sunlight gives a large amount of light
for the amount of heating it provides.[3]
Ultraviolet light from the Sun has
antiseptic
properties and can be used to sterilize tools. It also causes
sunburn, and
has other medical effects such as the production of
Vitamin D.
Ultraviolet light is strongly attenuated by Earth's atmosphere, so that the
amount of UV varies greatly with
latitude
because of the longer passage of sunlight through the atmosphere at high
latitudes. This variation is responsible for many biological adaptations,
including variations in human
skin color
in different regions of the globe.
Observed from Earth, the path of the Sun across the sky varies throughout the
year. The shape described by the Sun's position, considered at the same time
each day for a complete year, is called the
analemma
and resembles a figure 8 aligned along a North/South axis. While the most
obvious variation in the Sun's apparent position through the year is a
North/South swing over 47 degrees of angle (because of the 23.5-degree tilt of
the Earth with respect to the Sun), there is an East/West component as well. The
North/South swing in apparent angle is the main source of
seasons on
Earth.
The Sun is a magnetically active star; it supports a strong, changing
magnetic field that varies year-to-year and reverses direction about every
eleven years. The Sun's magnetic field gives rise to many effects that are
collectively called
solar activity, including
sunspots on
the surface of the Sun,
solar
flares, and variations in the
solar wind
that carry material through the solar system. The effects of solar activity on
Earth include
auroras at moderate to high latitudes, and the disruption of radio
communications and
electric power. Solar activity is thought to have played a large role in the
formation and evolution of the
solar
system, and strongly affects the structure of Earth's
outer
atmosphere.
Although it is the nearest star to Earth and has been intensively studied by
scientists, many questions about the Sun remain unanswered, such as why its
outer atmosphere has a temperature of over 1 million
K while its
visible surface (the
photosphere) has a temperature of less than 6,000 K. Current topics of
scientific inquiry include the Sun's regular cycle of
sunspot
activity, the physics and origin of
solar
flares and
prominences, the magnetic interaction between the
chromosphere and the
corona, and the
origin of the
solar wind.
Life cycle
The Sun's current age, determined using
computer models of
stellar evolution and
nucleocosmochronology, is thought to be about 4.57 billion years.[4]
The Sun is about halfway through its
main-sequence
evolution, during which
nuclear fusion reactions in its core fuse hydrogen into helium. Each second,
more than 4 million
tonnes of matter are converted into energy within the Sun's core, producing
neutrinos
and
solar radiation. The Sun will spend a total of approximately 10
billion years as a main sequence star.
The Sun does not have enough mass to explode as a
supernova.
Instead, in 4-5 billion years, it will enter a
red giant
phase, its outer layers expanding as the hydrogen fuel in the core is consumed
and the core contracts and heats up. Helium fusion will begin when the core
temperature reaches around 100 MK, and will produce carbon and oxygen. While it
is likely that the expansion of the outer layers of the Sun will reach the
current position of Earth's orbit, recent research suggests that mass lost from
the Sun earlier in its red giant phase will cause the Earth's orbit to move
further out, preventing it from being engulfed. However, Earth's water will be
boiled away and most of its atmosphere will escape into space.
Following the red giant phase, intense thermal pulsations will cause the Sun
to throw off its outer layers, forming a
planetary nebula. The only object that will remain after the outer layers
are ejected is the extremely hot stellar core, which will slowly cool and fade
as a
white dwarf over many billions of years. This
stellar evolution scenario is typical of low- to medium-mass stars.[5][6]
|
(Click picture to get a better view) |
|
Source |
|
An illustration of
the structure of the Sun |
Structure
While the Sun is an averaged-sized star, it contains approximately 99% of the
total mass of the solar system. The Sun is a near-perfect
sphere, with an
oblateness
estimated at about 9 millionths,[7]
which means that its polar diameter differs from its equatorial diameter by only
10 km. While the Sun does not rotate as a solid body (the rotational period is
25 days at the
equator and about 35 days at the
poles), it takes
approximately 28 days to complete one full rotation; the centrifugal effect of
this slow
rotation is 18 million times weaker than the surface gravity at the Sun's
equator. Tidal effects from the planets do not significantly affect the shape of
the Sun.
The Sun does not have a definite boundary as rocky planets do, nor even a
radius where the density suddenly begins to fall off; in its outer parts the
density of its gases drops approximately
exponentially with increasing distance from the centre of the Sun.
Nevertheless, the Sun has a well-defined interior structure, described below.
The Sun's radius is measured from its centre to the edge of the
photosphere. This is simply the layer above which the gases are too cool or
too thin to radiate a significant amount of light; the photosphere is the
surface most readily visible to the
naked eye.
Most of the Sun's mass lies within about 0.7
radii of the
centre.
The solar interior is not directly observable, and the Sun itself is opaque
to
electromagnetic radiation. However, just as
seismology
uses waves generated by
earthquakes
to reveal the interior structure of the Earth, the discipline of
helioseismology makes use of pressure waves (infrasound)
traversing the Sun's interior to measure and visualize the Sun's inner
structure.
Computer modelling of the Sun is also used as a theoretical tool to
investigate its deeper layers.
Core
The core of the
Sun is considered to extend from the centre to about 0.2 solar radii. It has a
density of up to 150,000 kg/m3 (150 times the density of water on
Earth) and a temperature of close to 13,600,000 Kelvins (by contrast, the
surface of the Sun is close to 5,785 Kelvins (1/2350th of the core)).
Through most of the Sun's life, energy is produced by
nuclear fusion through a series of steps called the p-p (proton-proton)
chain; this process converts
hydrogen
into helium.
The core is the only location in the Sun that produces an appreciable amount of
heat via fusion:
the rest of the star is heated by energy that is transferred outward from the
core. All of the energy produced by fusion in the core must travel through many
successive layers to the solar photosphere before it escapes into space as
sunlight or
kinetic energy of particles.
About 8.9×1037
protons
(hydrogen nuclei) are converted into helium nuclei every second, releasing
energy at the matter-energy conversion rate of 4.26 million tonnes per second,
383 yottawatts
(383×1024 W) or 9.15×1010
megatons of
TNT per second. The rate of nuclear fusion depends strongly on density, so
the fusion rate in the core is in a self-correcting equilibrium: a slightly
higher rate of fusion would cause the core to heat up more and
expand slightly against the
weight of the
outer layers, reducing the fusion rate and correcting the
perturbation; and a slightly lower rate would cause the core to cool and
shrink slightly, increasing the fusion rate and again reverting it to its
present level.
The high-energy
photons (gamma and X-rays) released in
fusion
reactions take a long time to reach the Sun's surface, slowed down by the
indirect path taken, as well as by constant absorption and reemission at lower
energies in the solar mantle. Estimates of the "photon travel time" range from
as much as 50 million years[8]
to as little as 17,000 years.[9]
After a final trip through the convective outer layer to the transparent
"surface" of the photosphere, the photons escape as
visible light. Each gamma ray in the Sun's core is converted into several
million visible light photons before escaping into space.
Neutrinos
are also released by the fusion reactions in the core, but unlike photons they
very rarely interact with matter, so almost all are able to escape the Sun
immediately. For many years measurements of the number of neutrinos produced in
the Sun were
much lower than theories predicted, a problem which was recently resolved
through a better understanding of the effects of
neutrino oscillation.
Radiation zone
From about 0.2 to about 0.7 solar radii, solar material is hot and dense
enough that
thermal radiation is sufficient to transfer the intense heat of the core
outward. In this zone there is no thermal
convection;
while the material grows cooler as altitude increases, this temperature
gradient is
slower than the
adiabatic lapse rate and hence cannot drive convection. Heat is transferred
by radiation—ions
of hydrogen
and helium emit
photons,
which travel a brief distance before being reabsorbed by other ions. Light in
this layer takes millions of years to escape and from there takes about 8
minutes to reach Earth.
Convection zone
From about 0.7 solar radii to the Sun's visible surface, the material in the
Sun is not dense enough or hot enough to transfer the heat energy of the
interior outward via radiation. As a result, thermal convection occurs as
thermal columns
carry hot material to the surface (photosphere) of the Sun. Once the material
cools off at the surface, it plunges back downward to the base of the convection
zone, to receive more heat from the top of the radiative zone.
Convective overshoot is thought to occur at the base of the convection zone,
carrying turbulent down flows into the outer layers of the radiative zone.
The thermal columns in the convection zone form an imprint on the surface of
the Sun, in the form of the
solar granulation and
super granulation. The turbulent convection of this outer part of the solar
interior gives rise to a "small-scale" dynamo that produces magnetic north and
south poles all over the surface of the Sun.
Photosphere
The visible surface of the Sun, the photosphere, is the layer below which the
Sun becomes opaque to visible light. Above the photosphere visible sunlight is
free to propagate into space, and its energy escapes the Sun entirely. The
change in opacity is due to the decreasing amount of H- ions, which
absorb visible light easily. Conversely, the visible light we see is produced as
electrons react with
hydrogen
atoms to produce H- ions.
[10]
[11] The
photosphere is actually tens to hundreds of kilometres thick, being slightly
less opaque than air
on Earth. Sunlight has approximately a
black-body
spectrum that indicates its temperature is about 6,000
K, interspersed
with atomic
absorption lines from the tenuous layers above the photosphere. The
photosphere has a particle density of about 1023 m−3 (this
is about 1% of the particle density of
Earth's atmosphere at sea level).
During early studies of the
optical spectrum of the photosphere, some absorption lines were found that
did not correspond to any
chemical elements then known on Earth. In 1868,
Norman Lockyer hypothesized that these absorption lines were because of a
new element which he dubbed "helium",
after the Greek Sun god
Helios. It was
not until 25 years later that helium was isolated on Earth.[12]
Atmosphere
The parts of the Sun above the photosphere are referred to collectively as
the solar atmosphere. They can be viewed with telescopes operating across
the
electromagnetic spectrum, from radio through
visible light to
gamma rays,
and comprise five principal zones: the temperature minimum, the
chromosphere, the
transition region, the
corona, and the
heliosphere. The heliosphere, which may be considered the tenuous outer
atmosphere of the Sun, extends outward past the orbit of
Pluto to the
heliopause,
where it forms a sharp
shock front
boundary with the
interstellar medium. The chromosphere, transition region, and corona are
much hotter than the surface of the Sun; the reason why is not yet known.
The coolest layer of the Sun is a temperature minimum region about 500 km
above the photosphere, with a temperature of about 4,000 K.
This part of the Sun is cool enough to support simple molecules such as
carbon monoxide and water, which can be detected by their absorption
spectra.
Above the temperature minimum layer is a thin layer about 2,000 km thick,
dominated by a spectrum of emission and absorption lines. It is called the
chromosphere from the Greek root chroma, meaning color, because the
chromosphere is visible as a colored flash at the beginning and end of
total
eclipses of the Sun. The temperature in the chromosphere increases gradually
with altitude, ranging up to around 100,000 K near the top.
Above the
chromosphere is a
transition region in which the temperature rises rapidly from around
100,000 K to
coronal temperatures closer to one million K. The increase is because of a
phase transition as
helium within
the region becomes fully
ionized
by the high temperatures. The transition region does not occur at a well-defined
altitude. Rather, it forms a kind of
nimbus around
chromospheric features such as
spicules and
filaments,
and is in constant, chaotic motion. The transition region is not easily visible
from Earth's surface, but is readily observable from
space
by instruments sensitive to the
far
ultraviolet portion of the
spectrum.
The corona is the extended outer atmosphere of the Sun, which is much larger
in volume than the Sun itself. The corona merges smoothly with the
solar wind
that fills the
solar
system and
heliosphere. The low corona, which is very near the surface of the Sun, has
a particle density of 1014 m−3–1016 m−3.
(Earth's atmosphere near sea level has a particle density of about 2×1025 m−3.)
The temperature of the corona is several million kelvin. While no complete
theory yet exists to account for the temperature of the corona, at least some of
its heat is known to be from
magnetic reconnection.
The
heliosphere extends from approximately 20 solar radii (0.1 AU) to the outer
fringes of the solar system. Its inner boundary is defined as the layer in which
the flow of the
solar wind
becomes superalfvénic—that is, where the flow becomes faster than the
speed of
Alfvén waves. Turbulence and dynamic forces outside this boundary cannot
affect the shape of the solar corona within, because the information can only
travel at the speed of Alfvén waves. The solar wind travels outward continuously
through the heliosphere, forming the solar magnetic field into a
spiral shape, until it impacts the
heliopause
more than 50 AU from the Sun. In December 2004, the
Voyager 1 probe passed through a
shock
front that is thought to be part of the heliopause. Both of the Voyager
probes have recorded higher levels of energetic particles as they approach the
boundary.[13]
Solar cycles
Sunspots and the sunspot cycle
When observing the Sun with appropriate filtration, the most immediately
visible features are usually its
sunspots,
which are well-defined surface areas that appear darker than their surroundings
because of lower temperatures. Sunspots are regions of intense magnetic activity
where
convection is inhibited by strong magnetic fields, reducing energy transport
from the hot interior to the surface. The magnetic field gives rise to strong
heating in the corona, forming
active regions that are the source of intense
solar
flares and
coronal mass ejections. The largest sunspots can be tens of thousands of
kilometres across.
The number of sunspots visible on the Sun is not constant, but varies over a
10-12 year cycle known as the
Solar
cycle. At a typical solar minimum, few sunspots are visible, and
occasionally none at all can be seen. Those that do appear are at high solar
latitudes. As the sunspot cycle progresses, the number of sunspots increases and
they move closer to the equator of the Sun, a phenomenon described by
Spörer's law. Sunspots usually exist as pairs with opposite magnetic
polarity. The polarity of the leading sunspot alternates every solar cycle, so
that it will be a north magnetic pole in one solar cycle and a south magnetic
pole in the next.
The solar cycle has a great influence on
space weather, and seems also to have an influence on the Earth's climate.
Solar minima tend to be correlated with colder temperatures, and longer than
average solar cycles tend to be correlated with hotter temperatures. In the 17th
century, the solar cycle appears to have stopped entirely for several decades;
very few sunspots were observed during this period. During this era, which is
known as the
Maunder minimum or
Little Ice Age, Europe experienced very cold temperatures.[14]
Earlier extended minima have been discovered through analysis of
tree rings
and also appear to have coincided with lower-than-average global temperatures.
Possible long term cycle
A recent theory by
Robert Ehrlich claims that there are magnetic instabilities in the core of
the sun which cause fluctuations with periods of either 41,000 or 100,000 years.
These could provide a better explanation of the
ice ages than
the
Milankovitch cycles. Unfortunately it is a theory that is hard to test![15]
Theoretical problems
Solar neutrino problem
For many years the number of solar
electron neutrinos detected on Earth was only a third of the number
expected, according to theories describing the nuclear reactions in the Sun.
This anomalous result was termed the
solar neutrino problem. Theories proposed to resolve the problem either
tried to reduce the temperature of the Sun's interior to explain the lower
neutrino flux, or posited that electron neutrinos could
oscillate - that is, change into undetectable
tau
and
muon neutrinos as they traveled between the Sun and the Earth.[16]
Several neutrino observatories were built in the 1980s to measure the solar
neutrino flux as accurately as possible, including the
Sudbury Neutrino Observatory and
Kamiokande.
Results from these observatories eventually led to the discovery that neutrinos
have a very small
rest mass
and can indeed oscillate.[17].
Moreover, in 2001 the Sudbury Neutrino Observatory was able to detect all three
types of neutrinos directly, and found that the Sun's total neutrino
emission rate agreed with the Standard Solar Model, although only one-third of
the neutrinos seen at Earth were of the electron type. This proportion agrees
with that predicted by the
MSW effect which describes neutrino oscillation. Hence, the problem is
completely resolved.
Coronal heating problem
The optical surface of the Sun (the
photosphere) is known to have a temperature of approximately 6,000
K. Above it
lies the solar corona at a temperature of 1,000,000 K. The high temperature of
the corona shows that it is heated by something other than direct heat
conduction
from the photosphere.
It is thought that the energy necessary to heat the corona is provided by
turbulent motion in the convection zone below the photosphere, and two main
mechanisms have been proposed to explain coronal heating. The first is
wave heating, in
which sound, gravitational and magnetohydrodynamic waves are produced by
turbulence in the convection zone. These waves travel upward and dissipate in
the corona, depositing their energy in the ambient gas in the form of heat. The
other is
magnetic heating, in which magnetic energy is continuously built up by
photospheric motion and released through
magnetic reconnection in the form of large
solar
flares and myriad similar but smaller events.[18]
Currently, it is unclear whether waves are an efficient heating mechanism.
All waves except Alfvén waves have been found to dissipate or refract before
reaching the corona.[19]
In addition, Alfvén waves do not easily dissipate in the corona. Current
research focus has therefore shifted towards flare heating mechanisms. One
possible candidate to explain coronal heating is continuous flaring at small
scales,[20]
but this remains an open topic of investigation.
Faint young Sun problem
Theoretical models of the Sun's development suggest that 3.8 to 2.5 billion
years ago, during the
Archean period,
the Sun was only about 75% as bright as it is today. Such a weak star would not
have been able to sustain liquid water on the Earth's surface, and thus life
should not have been able to develop. However, the geological record
demonstrates that the Earth has remained at a fairly constant temperature
throughout its history, and in fact that the young Earth was somewhat warmer
than it is today. The general consensus among scientists is that the young
Earth's atmosphere contained much larger quantities of
greenhouse gases (such as
carbon dioxide and/or
ammonia) than
are present today, which trapped enough heat to compensate for the lesser amount
of solar energy reaching the planet.[21]
Magnetic field
All matter
in the Sun is in the form of
gas and
plasma because of its high temperatures. This makes it possible for the Sun
to rotate faster at its equator (about 25 days) than it does at higher latitudes
(about 35 days near its poles). The
differential rotation of the Sun's latitudes causes its
magnetic field lines to become twisted together over time, causing magnetic
field loops to erupt from the Sun's surface and trigger the formation of the
Sun's dramatic
sunspots and
solar prominences (see
magnetic reconnection). This twisting action gives rise to the
solar
dynamo and an 11-year
solar
cycle of magnetic activity as the Sun's magnetic field reverses itself about
every 11 years.
The influence of the Sun's
rotating magnetic field on the plasma in the
interplanetary medium creates the
heliospheric current sheet, which separates regions with magnetic fields
pointing in different directions. The plasma in the interplanetary medium is
also responsible for the strength of the Sun's magnetic field at the orbit of
the Earth. If space were a vacuum, then the Sun's 10-4
tesla magnetic dipole field would reduce with the cube of the distance to
about 10-11 tesla. But satellite observations show that it is about
100 times greater at around 10-9 tesla.
Magnetohydrodynamic (MHD) theory predicts that the motion of a conducting
fluid (e.g., the interplanetary medium) in a magnetic field, induces electric
currents which in turn generates magnetic fields, and in this respect it behaves
like an MHD
dynamo.
History of solar observation
Early understanding of the Sun
Humanity's most fundamental understanding of the Sun is as the luminous disk
in the heavens, whose
presence above the
horizon
creates day and whose absence causes night. In many prehistoric and ancient
cultures, the Sun was thought to be a
solar
deity or other
supernatural phenomenon, and
worship
of the Sun was central to civilizations such as the
Inca of
South
America and the
Aztecs of what is now
Mexico. Many
ancient monuments were constructed with solar phenomena in mind; for example,
stone megaliths
accurately mark the summer
solstice
(some of the most prominent megaliths are located in
Nabta
Playa, Egypt,
and at
Stonehenge in
England); the pyramid of
El Castillo at
Chichén
Itzá in Mexico is designed to cast shadows in the shape of serpents climbing
the pyramid at the vernal and autumn
equinoxes.
With respect to the
fixed stars,
the Sun appears from Earth to revolve once a year along the
ecliptic
through the zodiac,
and so the Sun was considered by Greek astronomers to be one of the seven
planets (Greek
planetes, "wanderer"), after which the seven days of the
week are named in
some languages.
Development of modern scientific understanding
One of the first people to offer a scientific explanation for the Sun was the
Greek
philosopher Anaxagoras,
who reasoned that it was a giant flaming ball of metal even larger than the
Peloponnesus, and not the
chariot of
Helios. For
teaching this
heresy, he was imprisoned by the authorities and
sentenced to death (though later released through the intervention of
Pericles).
Eratosthenes might have been the first person to have accurately calculated
the distance from the Earth to the Sun, in the 3rd century BCE, as 149 million
kilometres, roughly the same as the modern accepted figure.
The theory that the sun is the center around which the planets move was
apparently proposed by ancient Greeks and Indians (see
Heliocentrism). This view was revived in the
16th
century by
Nicolaus Copernicus. In the early 17th century,
Galileo
pioneered
telescopic observations of the Sun, making some of the first known
observations of sunspots and positing that they were on the surface of the Sun
rather than small objects passing between the Earth and the Sun.[22]
In 1672
Giovanni Cassini and
Jean Richer determined the distance to
Mars and were
thereby able to calculate the distance to the sun.
Isaac
Newton observed the Sun's light using a
prism, and showed
that it was made up of light of many colors,[23]
while in 1800
William Herschel discovered
infrared
radiation beyond the red part of the solar spectrum.[24]
The 1800s saw spectroscopic studies of the Sun advance, and
Joseph von Fraunhofer made the first observations of
absorption lines in the spectrum, the strongest of which are still often
referred to as Fraunhofer lines.
In the early years of the modern scientific era, the source of the Sun's
energy was a significant puzzle.
Lord
Kelvin suggested that the Sun was a gradually cooling liquid body that was
radiating an internal store of heat.[25]
Kelvin and
Hermann von Helmholtz then proposed the
Kelvin-Helmholtz mechanism to explain the energy output. Unfortunately the
resulting age estimate was only 20 million years, well short of the time span of
several billion years suggested by geology. In 1890
Joseph Lockyer, the discoverer of helium in the solar spectrum, proposed a
meteoritic hypothesis for the formation and evolution of the sun.[26]
It would be 1904 before a potential solution was offered.
Ernest Rutherford suggested that the energy could be maintained by an
internal source of heat, and suggested
radioactive decay as the source.[27]
However it would be
Albert Einstein who would provide the essential clue to the source of the
Sun's energy output with his mass-energy relation
E=mc². In 1920
Sir
Arthur Eddington proposed that the pressures and temperatures at the core of
the Sun could produce a nuclear fusion reaction that merged hydrogen into
helium, resulting in a production of energy from the net change in mass.[28]
This theoretical concept was developed in the 1930s by the astrophysicists
Subrahmanyan Chandrasekhar and
Hans Bethe.
Hans Bethe calculated the details of the two main energy-producing nuclear
reactions that power the Sun.[29][30]
Finally, in 1957, a paper titled Synthesis of the Elements in Stars
(by
Margaret Burbidge,
Geoffrey Burbidge,
William A. Fowler and
Fred Hoyle)
[31] was
published which demonstrated convincingly that most of the elements in the
universe had been created by nuclear reactions inside stars like the Sun.
Solar space missions
The first satellites designed to observe the Sun were
NASA's
Pioneers 5, 6, 7, 8 and 9, which were launched between 1959 and 1968. These
probes orbited the Sun at a distance similar to that of the Earth's orbit, and
made the first detailed measurements of the solar wind and the solar magnetic
field. Pioneer 9 operated for a particularly long period of time, transmitting
data until 1987.[32]
In the 1970s,
Helios 1 and the
Skylab
Apollo Telescope Mount provided scientists with significant new data on
solar wind and the solar corona. The Helios 1 satellite was a joint
U.S.-German
probe that studied the solar wind from an orbit carrying the spacecraft inside
Mercury's orbit at
perihelion.
The Skylab space station, launched by NASA in 1973, included a solar
observatory module called the Apollo Telescope Mount that was operated by
astronauts resident on the station. Skylab made the first time-resolved
observations of the solar transition region and of ultraviolet emissions from
the solar corona. Discoveries included the first observations of
coronal mass ejections, then called "coronal transients", and of
coronal
holes, now known to be intimately associated with the
solar wind.
In 1980, the
Solar Maximum Mission was launched by
NASA. This
spacecraft was designed to observe
gamma rays,
X-rays and
UV radiation from
solar
flares during a time of high solar activity. Just a few months after launch,
however, an electronics failure caused the probe to go into standby mode, and it
spent the next three years in this inactive state. In 1984
Space
Shuttle
Challenger mission STS-41C retrieved the satellite and repaired its
electronics before re-releasing it into orbit. The Solar Maximum Mission
subsequently acquired thousands of images of the solar corona before
re-entering
the Earth's atmosphere in June 1989.[33]
Japan's
Yohkoh (Sunbeam)
satellite, launched in 1991, observed solar flares at X-ray wavelengths. Mission
data allowed scientists to identify several different types of flares, and also
demonstrated that the corona away from regions of peak activity was much more
dynamic and active than had previously been supposed. Yohkoh observed an entire
solar cycle but went into standby mode when an
annular eclipse in 2001 caused it to lose its lock on the Sun. It was
destroyed by atmospheric reentry in 2005.[34]
One of the most important solar missions to date has been the
Solar and Heliospheric Observatory, jointly built by the
European Space Agency and
NASA and launched
on December
2, 1995.
Originally a two-year mission, SOHO has now operated for over ten years (as
of 2007). It has proved so useful that a follow-on mission, the
Solar Dynamics Observatory, is planned for launch in 2008. Situated at the
Lagrangian point between the Earth and the Sun (at which the gravitational
pull from both is equal), SOHO has provided a constant view of the Sun at many
wavelengths since its launch. In addition to its direct solar observation, SOHO
has enabled the discovery of large numbers of comets, mostly very tiny
sungrazing comets which incinerate as they pass the Sun.[35]
All these satellites have observed the Sun from the plane of the ecliptic,
and so have only observed its equatorial regions in detail. The
Ulysses probe was launched in 1990 to study the Sun's polar regions. It
first traveled to
Jupiter, to 'slingshot' past the planet into an orbit which would take it
far above the plane of the ecliptic. Serendipitously, it was well-placed to
observe the collision of
Comet Shoemaker-Levy 9 with Jupiter in 1994. Once Ulysses was in its
scheduled orbit, it began observing the solar wind and magnetic field strength
at high solar latitudes, finding that the solar wind from high latitudes was
moving at about 750 km/s (slower than expected), and that there were large
magnetic waves emerging from high latitudes which scattered galactic
cosmic rays.[36]
Elemental abundances in the photosphere are well known from
spectroscopic studies, but the composition of the interior of the Sun is
more poorly understood. A
solar wind
sample return mission,
Genesis, was designed to allow astronomers to directly measure the
composition of solar material. Genesis returned to Earth in 2004 but was damaged
by a crash landing after its
parachute
failed to deploy on reentry into Earth's atmosphere. Despite severe damage, some
usable samples have been recovered from the spacecraft's sample return module
and are undergoing analysis.
Sun observation and eye damage
Sunlight is very bright, and looking directly at the Sun with the
naked eye
for brief periods can be painful, but is generally not hazardous. Looking
directly at the Sun causes
phosphene
visual artifacts and temporary partial blindness. It also delivers about
4 milliwatts of sunlight to the retina, slightly heating it and potentially
(though not normally) damaging it.
UV
exposure gradually yellows the lens of the eye over a period of years and can
cause
cataracts, but those depend on general exposure to solar UV, not on whether
one looks directly at the Sun.
Viewing the Sun through light-concentrating
optics
such as
binoculars is very hazardous without an
attenuating (ND) filter to dim the sunlight. Unfiltered binoculars can
deliver over 500 times the intensity of normal sunlight to the retina than does
the naked eye, killing retinal cells almost instantly. Even brief glances at the
midday Sun through unfiltered binoculars can cause permanent blindness.[37]
One way to view the Sun safely is by projecting an image onto a screen using
binoculars. This should only be done with a small refracting telescope (or
binoculars) with a clean eyepiece. Other kinds of telescope can be damaged by
this procedure.
Partial
solar
eclipses are hazardous to view because the eye's
pupil is not
adapted to the unusually high visual contrast: the pupil dilates according to
the total amount of light in the field of view, not by the brightest
object in the field. During partial eclipses most sunlight is blocked by the
Moon passing in front of the Sun, but the uncovered parts of the photosphere
have the same
surface brightness as during a normal day. In the overall gloom, the pupil
expands from ~2 mm to ~6 mm, and each retinal cell exposed to the solar image
receives about ten times more light than it would looking at the non-eclipsed
Sun. This can damage or kill those cells, resulting in small permanent blind
spots for the viewer.[38]
The hazard is insidious for inexperienced observers and for children, because
there is no perception of pain: it is not immediately obvious that one's vision
is being destroyed.
During sunrise
and sunset,
sunlight is attenuated through
Rayleigh and
Mie
scattering of light by a particularly long passage through Earth's
atmosphere, and the direct Sun is sometimes faint enough to be viewed directly
without discomfort or safely with binoculars (provided there is no risk of
bright sunlight suddenly appearing in a break between clouds). Hazy conditions,
atmospheric dust, and high humidity contribute to this atmospheric attenuation.
Wearing UV protective
sunglasses
can help protect the eye, but sunglasses without good UV protection may cause
one's pupil to dilate so that more of the lens is exposed to the UV, and more UV
goes into the interior of the eye.
Attenuating filters to view the Sun should be specifically designed for that
use: some improvised filters pass UV or IR rays that can harm the eye at high
brightness levels. In general, filters on telescopes or binoculars should be on
the
objective lens or
aperture
rather than on the
eyepiece,
because eyepiece filters can suddenly shatter due to high heat loads from the
absorbed sunlight. Welding glass is an acceptable solar filter, but "black"
exposed photographic film is not (it passes too much infrared).
The Sun in human culture
Christian
Early Christian
iconography reveals
Jesus as
reflecting several attributes of Sol Invictus, such as a radiated
crown or,
occasionally, a solar chariot.
It is also speculated that the observation of
Christmas
on
December 25th is derived from the
pagan Sun holiday
which occurred on the same date. Jesus was also considered the "Sun
of Righteousness" (Malachi
3:20).
Greek mythology
Many Greek
myths personify the Sun as a
Titan named
Helios, who wore a shining crown and rode a
chariot
across the sky, causing day. Over time, the sun became increasingly associated
with Apollo.
The
Roman Empire adopted Helios into their own mythology as
Sol. The title
Sol
Invictus ("the undefeated Sun") was applied to several solar deities, and
depicted on several types of Roman
coins during the
3rd
and 4th
centuries. The birth of "the undefeated Sun" was celebrated on the
25th
of December from at least as early as
354.
Hinduism
In Hindu
religious literature, the Sun is notably mentioned as the visible form of
God that one can see
every day. In
Hinduism, Surya
(Devanagari: सूर्य, sūrya) is the chief solar deity, son of Dyaus Pitar. The
ritual of
sandhyavandanam, performed by some
Hindus, is meant
to worship the sun. The Sun was also worshiped in
Inca,
Aztec and
Egyptian culture.[39]
Islamic
In the Qur'an,
the Islamic religious scripture, the Sun like other celestial objects is not
endowed with any particular religious significance or symbolic meaning. Due to
the widespread presence of Sun-worshiping cults in Pre-Islamic Arabia,
Muslim
doctrine, the
Shariah forbade all prayers during the rising and setting of the Sun, to
symbolically refute its divinity. pre-Islamic Arab pagans considered
solar eclipses and other celestial occurrences as omens signalling the
passing of an important figure or other earthly events. However, this belief was
refuted explicitly by the Prophet
Muhammad in
the year 632 C.E, when the death of his son coincided with a solar eclipse: "The
Sun and the Moon are from among the evidences of God. They do not eclipse
because of someone's death or life."[40].
