Acme Plz.
Andheri-Kurla Rd., An
Mumbai 400 059
India
Company Perspectives:
In India, Sun Pharma intends to reach a top 3 ranking with specialists in all the therapy areas that it has a presence in.
In developing markets the company is creating speciality area product baskets that are customized to a country's needs.
In the high value generic markets of North America and Europe, the company is working to develop and market speciality generics, with a clear plan of action to move on to supergenerics and differentiated generics.
The learning from international markets will equip the company eventually to launch innovative products across international markets of interest.
History of Sun Pharmaceutical Industries Ltd.
Sun Pharmaceutical Industries Ltd. (Sun Pharma) is a rising star of India's fast-growing pharmaceuticals industry. In less than a decade, Sun has lifted itself into fifth position in the country's pharmaceuticals market. Sun manufactures a range of drugs for a range of medical specialties, treatments, and disorders. The company targets especially high-margin niche and specialty medications, including longtime bestseller Monotrate, as well as brands Celact (celecoxib), Oleanz (olanzapine), Rofact (rofecoxib), Nodict (naltrexone), Fexotrol (fexofenadine), Zelast (azolastine), and Ketorid (ketotifen). The company also produces a variety of specialty bulk actives and generic drugs. Sun Pharma manufactures and markets its drugs through a number of subsidiaries and divisions, including Aztec, Inca, Sun, Milmet, Synergy, TDPL, Symbiosis, and Solares. More than 70 percent of the company's sales come from within India. Sun is also present in the United States, through its control of publicly listed Caraco Pharmaceutical Laboratories, based in Detroit. The company continues to be led by founder, Chairman, and Managing Director Dilip S. Shanghvi.
Pharmaceutical Manufacturing Dream in the 1980s
While in college, Dilip Shanghvi had worked for his family's Calcutta-based wholesale drug trading business. Yet Shanghvi's own ambitions turned toward the manufacturing and development of the pharmaceuticals themselves. Shanghvi founded his company, Sun Pharmaceutical, in 1982 with just $250, and began looking for a first product.
Shanghvi soon spotted an opportunity. Lithosan, a widely used drug for the treatment of manic depressive disorders, remained unavailable in India's eastern provinces. Yet the drug was relatively easy to manufacture, and a friend of Shanghvi owned the equipment and a factory capable of producing it. In 1983, Shanghvi borrowed his friend's equipment and Rs 10,000 from his father and Sun Pharmaceutical officially opened for business.
Sun's sales were initially limited to the Calcutta market. The company quickly expanded its product line, boasting five products targeting the psychiatric segment--an area not subject to the Indian government's highly restrictive drug manufacturing laws. The psychiatric market also provided high margins on sales, a feature that was to mark much of the company's product choices over the following two decades.
By the end of its first year, Sun had moved into its own manufacturing facility--spending $50,000 to install its production into a self-described "shed" of 3,000 square feet in the town of Vapi, on the country's west coast, near the pharmaceutical center of Mumbai (Bombay). Discussing the reason behind the move with Business World, Shanghvi explained: "The industry was concentrated in the western region and it was easier to get permission there to launch new drugs."
The Vapi shed remained a central production plant for the company, expanding to match Sun's rapid growth. By the end of its first year, the company's sales already topped Rs 750,000. Yet Sun continued to target its production to the Calcutta region and elsewhere along India's east coast. In 1984, the company extended its marketing region to include most of the Indian eastern seaboard states.
Sun began locating and developing new drugs for its range, and began looking beyond the psychiatric segment in the mid-1980s. In the meantime, Sun moved to extend its marketing reach to India's west coast as well. In support of that effort, Sun moved its administrative offices to Mumbai in 1986. The following year, the company extended its marketing reach throughout all of India.
Sun launched a new range of cardiology products in 1987, including Angizem and, especially, Monotrate. That drug became the company's first success and remained its leading product into the next century. The success of Monotrate also helped bring the company into the scope of the ORG (Operations Research Group) audit of retail pharmacy sales for the first time, with a rating of 107 and a 0.1 percent share of the Indian drug market.
Expansion in the 1990s
Sun Pharmaceutical added another new product area in 1989 when it began marketing gastroenterology products. That year also marked the debut of the company's export operations; initial foreign markets remained in the Asian region, however.
At the start of the 1990s, Sun stepped up its research and development operations as it sought to boost its position in the Indian pharmaceutical market. In 1991, the company began construction on its own research facility in Vadodara, which opened as the Sun Pharmaceutical Advanced Research Center (Sparc) in 1993. In that year, also, Sun began to market its drugs farther afield, opening offices in Moscow and in Toronto.
The year 1994 marked a turning point for the company. Sun went public that year, listing on several of India's stock exchanges in an initial public offering (IPO) that was oversubscribed by some 55 times. The company also had placed one of its products among the top 250 pharmaceutical brands in India that year. Sun's manufacturing base grew in 1994 with the opening of a new production plant, in Panoli, supporting its entry into the bulk actives market. Sun then opened a second facility, in Silvassa, for dosage form manufacturing, while the company's main Vapi plant underwent a new and large-scale expansion program.
In 1995, the company began developing a divisional operational structure, which already included Synergy, grouping its psychiatric and neurology products, created in 1994. The company now created the Aztec division for its cardiology products, and the Inca division for its line of critical care medication.
Sun itself, backed by its IPO, embarked on its own expansion drive in the mid-1990s. Acquisitions now formed a major part of the company's growth, starting with the purchase of Knoll Pharma's bulk actives manufacturing business based in Ahmednagar in 1996. In that year, also, Sun took a step to break into the important U.S. healthcare market, with its purchase of a controlling share of Detroit-based Caraco Pharmaceutical Laboratories, which specialized in the manufacture of generic dosage form medications and gave the company its first USFDA-approved production plant.
Also in 1996, Sun purchased a shareholding in Gujarat Lyka Organics, which, in addition to adding its production of cephalexin bulk active, brought Sun a USFDA-approved manufacturing facility. The company completed its acquisition of Gujurat in 1999.
In the meantime, its acquisition drive continued, bringing it a stake in MJ Pharmaceuticals Ltd., based in Halol. With a 60,000-square-foot, UKMCA-approved plant, MJ Pharma brought Sun its strong insulin production, as well as a springboard for entry into the European market.
Sun's acquisition spurt had enabled it to boost its position to number 27 among India's pharmaceutical companies by the end of 1996. Yet the company retained its appetite for growth, adding Tamil Nadu Dadha Pharmaceuticals (TND), based in Madras, the following year. That company brought Sun such new product areas as oncology, fertility, anesthesiology, and pain management. Following the TND purchase, Sun reorganized its operations, regrouping its businesses into six operating divisions.
Indian Top Five in the New Century
Sun opened a second research and development (R&D) facility in 1997, specializing in developing dosage forms and documentation for the fast-growing U.S. and European generic drugs markets. The following year the company expanded its line with the purchase of a number of brands from Natco Pharma, adding some Rs 500 million to its sales. The Natco brands gave the company new products in the gastroenterology, orthopedics, pediatrics, and other categories, as well as access to Natco's time-release technology. In 1998, also, Sun bought Milmet Labs, enabling the company to enter the ophthalmology products market for the first time. Meanwhile, the company added a new production plant in Silvas.
By 1999, Sun had jumped into the Indian pharmaceutical industry's top ten. The company also boasted six brands in the country's top 300. Of importance, the company also had achieved leadership status in most of its specialty drug areas. By then, too, it had boosted its bulk actives business with the purchase of Madras-based Pradeep Drug Company Ltd. That company was merged into Sun itself in 2001. During that year, too, the company's Caraco subsidiary gained USFDA approval for a number of new generic drugs, as the U.S. market for generics was poised to boom in the early years of the new century.
After selling off a number of "tail end" brands at the end of 2001, the company merged its MJ Pharmaceuticals subsidiary into its core operation at the beginning of 2002. The company also began submitting applications as part of its plan to enter the U.K. and German pharmaceutical markets. During that year, the company commissioned a new manufacturing facility, capable of producing some three billion tabs per year, in Dadra. That company also began construction on another plant, in Jammu, that year. As its Caraco subsidiary, which had been losing money since its acquisition, finally broke even that year, Sun Pharmaceutical itself cracked the India top five.
Sun, which had withdrawn its listing from a number of Indian stock exchanges during 2002, announced a stock split at the end of that year. At the same time, the company boosted its holding of Caraco to 65 percent in a stock-for-technology deal, which involved the transfer of some 25 off-patent drugs from Sun to Caraco, to boost its position in the U.S. generics market.
Meanwhile, Sun's new product launches had become the company's primary motor for growth, representing half of its turnover from products less than four years old. While acquisitions accounted for a major portion of Sun's growth since the late 1990s, in 2003 the company put its acquisition drive on hold--at least temporarily--as it turned its focus toward its R&D and exports business. In support of these, the company expected to commission a third research and development facility in Baroda in September 2003, while planning began that year for a new product development laboratory, specifically created to support the company's exports to the United States and Europe, in Mumbai. Now one of India's largest and most respected pharmaceutical companies, Sun prepared to take on the industry's global giants.
Principal Subsidiaries: Sun Pharma Global Inc.; Milmet Pharma Ltd.; Sun Pharmaceutical (Bangladesh) Ltd.; Zao Sun Pharma Ind-Russia; Sun Pharma Global Inc-BVI; Milmet Pharma; Caraco Pharmaceutical Laboratories Inc. (U.S.A.; 65%).
Principal Competitors: RPG Enterprises; GlaxoSmithKline Consumer Healthcare Ltd.; East India Pharmaceutical Works Ltd.; Dr. Reddy's Laboratories Ltd.; Cipla Ltd.; Concept Pharmaceuticals Ltd.; Khandelwal Laboratories Ltd.; Dabur India Ltd.; Claris Lifesciences Ltd.; ICI India Ltd.
Related information about Sun
The central object of our Solar System and the nearest star to
the Earth. Its basic characteristics are: mass
99×1030 kg; radius
696 000 km/432 500 mi; mean density
4 g/cm3; mean rotation period 2 4 days; luminosity
85×1024 J/s. Its average distance from Earth is 150
million km/93 million mi, and on account of this
proximity it is studied more than any other star. The source of its
energy is nuclear reactions in the central core (temperature 15
million K, relative density 155) extending to a quarter of the
solar radius and including half the mass. Our Sun is nearly 5000
million years old, and is about halfway through its expected
life-cycle. Every second it annihilates 5 million tonnes of matter,
to maintain power output of
39 × 1026 watts of energy.otheruses
Observation
data
|
Mean distance from
Earth
|
149.6 km
(92.95 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
|
17}} km
(26,000-28,000 light-years)
|
Galactic period
|
8}} 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 km
(109 Earth diameters)
|
Circumference
|
4.373 km
(342 Earth diameters)
|
Oblateness
|
−6}}
|
Surface area
|
6.09 km²
(11,900 Earths)
|
Volume
|
1.41 km³
(1,300,000 Earths)
|
Mass
|
30}} kg(332,946 Earths)
|
Density
|
1.408 g/cm³
|
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)
|
26}} W~9 cd[[cite journal
|
last=Menat
|
first=M.
|
year=1980
|
month=10
|
url=adsabs.harvard.edu/cgi-bin/nph-bib_query?bibcode=1980ApOpt..19.3458M&db_key=AST&data_type=HTML&format=&high=44b52c369030002 |
title=Atmospheric phenomena before and during
sunset
|
journal=Applied Optics
|
volume=19
|
27]] cd (V band)
(~100 lm/W
efficacy)
|
Mean Intensity (Isol)
|
7}} W m-2sr-1
|
Rotation
characteristics
|
Obliquity
|
7.25 °
(to the ecliptic)
67.23°
(to the galactic
plane)
|
Right ascension
of North pole[[cite web
|
url=www.hnsky.org/iau-iag.htm |
title=Report Of The IAU/IAG Working Group On Cartographic
Coordinates And Rotational Elements Of The Planets And
Satellites: 2000
|
accessdate=2006-03-22
|
first=P. Thomas
|
year=2000]] |
286.13°
(19 h 4 min 30 s)
|
Declination
of North pole
|
+63.87°
(63°52' North)
|
Rotation period
at equator
|
25.3800 days
(25 d 9 h 7 min 13 s)
|
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
|
0.04 %
|
The Sun is the star
of our 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: bigodot.
The sun's history and destiny
The Sun is about 4.6 billion years old and 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.
In about 5 billion years, the Sun will evolve into a red giant and then a white dwarf, creating a
planetary
nebula in the process. 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 a 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.
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. "G2" means that it has a surface temperature of
approximately 5,500 K, giving it a white color, which
because of atmospheric scattering appears yellow. 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. Because of logarithmic size distribution, the Sun is
actually brighter than 85% of the stars in the Galaxy, most of
which are red dwarfs.
www.space.com/scienceastronomy/060130_mm_single_stars.html
The Sun orbits the center of the Milky Way galaxy at a distance of about 25,000 to 28,000 light-years from the galactic center,
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.
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 near the surface of 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 meter 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.
Sunlight has several interesting biological properties. 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. Its current age,
determined using computer models of stellar evolution and nucleocosmochronology, is thought to be about 4.57
billion years.
The Sun does not have enough mass to explode as a supernova. The Sun is a
near-perfect sphere, with
an oblateness
estimated at about 9 millionths, 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; Tidal effects from the planets do not
significantly affect the shape of the Sun, although the Sun itself
orbits the center of
mass of the solar system, which is located nearly a solar
radius away from the center of the Sun mostly because of the large
mass of Jupiter.
The Sun does not have a definite boundary as rocky planets do; This
is simply the layer below which the gases are thick enough to be
opaque but above which
they are transparent; Most of the Sun's mass lies within about
0.7 radii of the
center.
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.
Energy is produced by exothermic thermonuclear reactions (nuclear fusion) that
mainly convert hydrogen
into helium, helium into carbon, carbon into iron. 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 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 W) or 9.15 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. 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. 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. Convective
overshoot is thought to occur at the base of the convection
zone, carrying turbulent downflows 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 supergranulation. Sunlight has approximately a black-body spectrum that
indicates its temperature is about 6,000 K (10,340°F / 5,727 °C), 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. 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 increase is because of a
phase
transition as helium
within the region becomes fully ionized by the high temperatures. 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. 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. 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. 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 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 a strong influence on the Earth's climate. During this
era, which is known as the Maunder minimum or Little Ice Age, Europe experienced very cold
temperatures. Earlier extended minima have been discovered through
analysis of tree rings
and also appear to have coincided with lower-than-average global
temperatures. The Van Allen belts consist of an inner belt composed
primarily of protons and
an outer belt composed mostly of electrons. The most energetic particles can 'leak out'
of the belts and strike the Earth's upper atmosphere, causing
auroras, known as aurorae borealis in the northern
hemisphere and aurorae australis in the southern hemisphere.
In periods of normal solar activity, aurorae can be seen in
oval-shaped regions centered on the magnetic poles and lying roughly at a geomagnetic
latitude of 65°, but at times of high solar activity the
auroral oval can expand greatly, moving towards the equator.
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. 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.
Coronal heating problem
The optical surface of the Sun (the photosphere) is known to
have a temperature of approximately 6,000 K. 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.
Currently, it is unclear whether waves are an efficient heating
mechanism.
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. 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.
Magnetic field
All matter in the Sun
is in the form of gas and
plasma
because of its high temperatures. 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.
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. 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 in the Western world 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). 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. Isaac Newton observed the
Sun's light using a prism,
and showed that it was made up of light of many colors, while in
1800 William
Herschel discovered infrared radiation beyond the red part of the solar
spectrum. 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. Kelvin and Hermann von
Helmholtz then proposed the Kelvin-Helmholtz
mechanism to explain the energy output. Ernest Rutherford
suggested that the energy could be maintained by an internal source
of heat, and suggested radioactive decay as the source. However it would be
Albert Einstein
who would provide the essential clue to the source of a Sun's
energy 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. This theoretical concept was developed
in the 1930s by the astrophysicists Subrahmanyan
Chandrasekhar and Hans Bethe.
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. Pioneer 9 operated
for a particularly long period of time, transmitting data until
1987.
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.
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. 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.
Japan's Yohkoh (Sunbeam)
satellite, launched in 1991, observed solar flares at X-ray
wavelengths. It was destroyed by atmospheric reentry in 2005.
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. 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.
All these satellites have observed the Sun from the plane of the
ecliptic, and so have only observed its equatorial regions in
detail. 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.
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. 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.
When looking at the sun, either with or without optical aid, using
a proper filter is important as some improvised filters pass UV or
IR rays that can damage the eye at high brightness levels. For
example, any kind of photographic color film transmits IR light and
must not be used.
Viewing the Sun through light-concentrating optics such as binoculars is very hazardous
without an attenuating (ND) filter to dim the sunlight. These
filters can be made of mirrored glass or metallised plastic
film.
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. This can damage or kill those cells,
resulting in small permanent blind spots for the viewer. 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).
See also
- List of Solar System bodies formerly considered
planets
- Formation and evolution of the solar
system
References
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