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Solar cycle

400 year sunspot history

The *solar cycle*, or the *solar magnetic activity cycle*, is the main
source of the ~10.7 year periodic solar variation (changing the level of
irradiation experienced on Earth) which drives variations in space weather
and to some degree weather on the ground and possibly climate change .^[1]
The cycle is observed by counting the frequency and placement of sunspots
visible on the Sun . Powered by a hydromagnetic dynamo process driven by
the inductive action of internal solar flows, the solar cycle:

* Structures the Sun's atmosphere , corona and wind; * Modulates the solar
irradiance; * Modulates the flux of short-wavelength solar radiation, from
ultraviolet to X-ray; * Modulates the occurrence frequency of flares,
coronal mass ejections, and other geoeffective solar eruptive phenomena; *
Indirectly modulates the flux of high-energy galactic cosmic rays entering
the solar system.


Contents

[hide ]

* 1 History 
* 2 Phenomena, measurement, and causes

* 3 Impacts of the solar cycle 
o 3.1 Surface magnetism 
o 3.2 Solar irradiance 
o 3.3 Short-wavelength radiation 
o 3.4 Solar radio flux 
o 3.5 Geoeffective eruptive phenomena

o 3.6 Cosmic ray flux 
o 3.7 Effects on Earth 
* 4 See also 
* 5 References 
* 6 External links 


[edit ] History



Samuel Heinrich Schwabe (1789–1875). German astronomer, discovered the
solar cycle through extended observations of sunspots


Rudolf Wolf (1816–1893), Swiss astronomer, carried out historical
reconstruction of solar activity back to the seventeenth century

The solar cycle was discovered in 1843 by Samuel Heinrich Schwabe , who
after 17 years of observations noticed a periodic variation in the average
number of sunspots seen from year to year on the solar disk. Rudolf Wolf
compiled and studied these and other observations, reconstructing the
cycle back to 1745, eventually pushing these reconstructions to the
earliest observations of sunspots by Galileo and contemporaries in the
early seventeenth century. Starting with Wolf, solar astronomers have
found it useful to define a standard sunspot number index, which continues
to be used today.

Until recently it was thought that there were 28 cycles in the 309 years
between 1699 and 2008, giving an average length of 11.04 years, but recent
research has showed that the longest of these (1784–99) seems actually
to have been two cycles,^[2] ^[3] so that the average length is only
around 10.66 years. Cycles as short as 9 years and as long as 14 years
have been observed. Significant variations in amplitude also occur. Solar
maximum and solar minimum refer respectively to epochs of maximum and
minimum sunspot counts. Individual sunspot cycles are partitioned from one
minimum to the next.

Following the numbering scheme established by Wolf, the 1755–1766 cycle
is traditionally numbered "1". The period between 1645 and 1715, a time
during which very few sunspots were observed, is a real feature, as
opposed to an artifact due to missing data,^[/citation needed /] and
coincides with the Little Ice Age . This epoch is now known as the Maunder
minimum , after Edward Walter Maunder , who extensively researched this
peculiar event, first noted by Gustav Spörer . In the second half of the
nineteenth century it was also noted (independently) by Richard Carrington
and by Spörer that as the cycle progresses, sunspots appear first at
mid-latitudes, and then closer and closer to the equator until solar
minimum is reached. This pattern is best visualized in the form of the
so-called butterfly diagram, first constructed by the husband-wife team of
E. Walter and Annie Maunder in the early twentieth century (see graph
below). Images of the Sun are divided into latitudinal strips, and the
monthly-averaged fractional surface of sunspots calculated. This is
plotted vertically as a color-coded bar, and the process is repeated month
after month to produce this time-latitude diagram.



The sunspot butterfly diagram. This modern version is constructed (and
regularly updated) by the solar group at NASA Marshall Space Flight
Center.

The physical basis of the solar cycle was elucidated in the early
twentieth century by George Ellery Hale and collaborators, who in 1908
showed that sunspots were strongly magnetized (this was the first
detection of magnetic fields outside the Earth), and in 1919 went on to
show that the magnetic polarity of sunspot pairs:

* Is always the same in a given solar hemisphere throughout a given
sunspot cycle; * Is opposite across hemispheres throughout a cycle; *
Reverses itself in both hemispheres from one sunspot cycle to the next.

Hale's observations revealed that the solar cycle is a magnetic cycle with
an average duration of 22 years. However, because very nearly all
manifestations of the solar cycle are insensitive to magnetic polarity, it
remains common usage to speak of the "11-year solar cycle".

Half a century later, the father-and-son team of Harold Babcock and Horace
Babcock showed that the solar surface is magnetized even outside of
sunspots; that this weaker magnetic field is to first order a dipole; and
that this dipole also undergoes polarity reversals with the same period as
the sunspot cycle (see graph below). These various observations
established that the solar cycle is a spatiotemporal magnetic process
unfolding over the Sun as a whole.



Time vs. solar latitude diagram of the radial component of the solar
magnetic field, averaged over successive solar rotation. The "butterfly"
signature of sunspots is clearly visible at low latitudes. Diagram
constructed (and regularly updated) by the solar group at NASA Marshall
Space Flight Center.


[edit ] Phenomena, measurement, and causes

Spots from multiple cycles can co-exist for some time and since it was
discovered the sun reverses magnetic polarity one solar half cycle to the
next, spots from different cycles can be told apart. However it takes some
months before a definite decision to be made on the true date of solar
minimum, which is announced by the relevant expert authorities.

One of the main authorities is SIDAC (the Solar Influences Data Analysis
Center ) which is located in Belgium , and works with agencies such as
NASA and ESA .

The most important information today comes from SOHO (a project of
international cooperation between ESA and NASA), such as the MDI
magnetogram , where the solar "surface" magnetic field can be seen.

It has been noticed that sunspots from a dying solar cycle tend to appear
near the solar equator whereas spots from a new cycle tend to appear at
mid-latitudes.^[/citation needed /]

The basic causes of the solar variability and solar cycles are still under
debate, with some researchers suggesting a link with the tidal forces due
to the gas giants Jupiter and Saturn ,^[4] ^[5] or due to the solar
inertial motion.^[6] ^[7] Another cause of sun spots can be solar jet
stream "torsional oscillation".


[edit ] Impacts of the solar cycle



11,000 year sunspot reconstruction


Numbers of sunspots since 1610.^[8] ^[9] Several periodic cycles are
evident, most notably the 11 year (131 ± 14 month) cycle. The green line
represents continuous monthly averages reported by the Solar Influences
Data Center since 1749. Red data points represent sporadic observations
since 1610.


Activity cycles 21, 22 and 23 seen in sunspot number index, TSI, 10.7cm
radio flux, and flare index. The vertical scales for each quantity have
been adjusted to permit overplotting on the same vertical axis as TSI.
Temporal variations of all quantities are tightly locked in phase, but the
degree of correlation in amplitudes is variable to some degree.

The Sun's magnetic field structures its atmosphere and outer layers all
the way through the corona and into the solar wind . Its spatiotemporal
variations lead to a host of phenomena collectively known as solar
activity. All of solar activity is strongly modulated by the solar
magnetic cycle, since the latter serves as the energy source and dynamical
engine for the former.


[edit ] Surface magnetism

Sunspots may exist anywhere from a few days to a few months, but they
eventually decay, and this releases magnetic flux in the solar
photosphere. This magnetic field is dispersed and churned by turbulent
convection, and solar large-scale flows. These transport mechanisms lead
to the accumulation of the magnetized decay products at high solar
latitudes, eventually reversing the polarity of the polar fields (notice
how the blue and yellow fields reverse in the graph above).

The dipolar component of the solar magnetic field is observed to reverse
polarity around the time of solar maximum, and reaches peak strength at
the time of solar minimum. Sunspots, on the other hand, are produced from
a strong toroidal (longitudinally-directed) magnetic field within the
solar interior. Physically, the solar cycle can be thought of as a
regenerative loop where the toroidal component produces a poloidal field,
which later produces a new toroidal component of sign such as to reverse
the polarity of the original toroidal field, which then produces a new
poloidal component of reversed polarity, and so on.


[edit ] Solar irradiance

The total solar irradiance (TSI) is the amount of solar radiative energy
incident on the Earth's upper atmosphere. TSI variations were undetectable
until satellite observations began in late 1978. The major finding of
satellite observations is that TSI varies in phase with the solar magnetic
activity cycle^[10] with an amplitude of about 0.1% and an average value
of about 1366 W/m^2 . Variations about the average up to −0.3% are
caused by large sunspot groups and of +0.05% by large faculae and bright
network on a week to 10 day timescale.^[11] (see TSI variation graphics
[1] .) The sunspot cycle variation of 0.1% has small but detectable
effects on the Earth's climate.^[12] TSI variations over the several
decades of continuous satellite observation show small but detectable
trends.^[13] ^[14]

TSI is higher at solar maximum, even though sunspots are darker (cooler)
than the average photosphere. This is caused by magnetized structures
other than sunspots during solar maxima, such as faculae and active
elements of the 'bright' network, that are brighter (hotter) than the
average photosphere. They collectively overcompensate for the irradiance
deficit associated with the cooler but less numerous sunspots. The primary
driver of TSI changes on solar rotational and sunspot cycle timescales is
the varying photospheric coverage of these radiatively active solar
magnetic structures.


[edit ] Short-wavelength radiation



The solar disk seen by the Yohkoh soft-X-ray imager, over the time period
1991–1995 (left to right), spanning the descending phase of cycle 22.

With a temperature of 5870 kelvins , the photosphere of the Sun emits very
little short-wavelength radiation, such as extreme ultraviolet (EUV) and
X-rays . However, hotter upper layers of the Sun's atmosphere
(chromosphere and corona ) emit more short-wavelength radiation. Since the
upper atmosphere is not homogeneous and contains significant magnetic
structure, the solar UV , EUV and X-ray flux varies markedly in the course
of the solar cycle.

The photo montage to the left illustrates this variation for soft X-ray,
as observed by the Japanese satellite Yohkoh . Similar cycle-related
variations are observed in the flux of solar UV or EUV radiation, as
observed, for example, by the SOHO or TRACE satellites.

Even though it only accounts for a minuscule fraction of total solar
radiation, the impact of solar UV, EUV and X-ray radiation on the Earth's
upper atmosphere is profound. Solar UV flux is a major driver of
stratospheric chemistry , and increases in ionizing radiation
significantly affect ionosphere -influenced temperature and electrical
conductivity.


[edit ] Solar radio flux

Emission from the Sun at centimetric (radio) wavelength is due primarily
to coronal plasma trapped in the magnetic fields overlying active
regions.^[15] The F10.7 index is a measure of the solar radio flux per
unit frequency at a wavelength of 10.7 cm, near the peak of the observed
solar radio emission. It represents a measure of diffuse, nonradiative
heating of the coronal plasma trapped by magnetic fields over active
regions, and is an excellent indicator of overall solar activity levels.
The solar F10.7 cm record extends back to 1947, and is the longest direct
record of solar activity available, other than sunspot-related quantities.

Sunspot activity has a major effect on long distance radio communications
particularly on the shortwave bands although medium wave and low VHF
frequencies are also affected. High levels of sunspot activity lead to
improved signal propagation on higher frequency bands, although they also
increase the levels of solar noise and ionospheric disturbances. These
effects are caused by impact of the increased level of solar radiation on
the ionosphere .

It has been proposed that 10.7 cm solar flux can interfere with
point-to-point terrestrial communications.^[16]


[edit ] Geoeffective eruptive phenomena

The solar magnetic field structures the corona, giving it its
characteristic shape visible at times of solar eclipses. Complex coronal
magnetic field structures evolve in response to fluid motions at the solar
surface, and emergence of magnetic flux produced by dynamo action in the
solar interior. For reasons not yet understood in detail, sometimes these
structures lose stability, leading to coronal mass ejections into
interplanetary space, or flares , caused by sudden localized release of
magnetic energy driving copious emission of ultraviolet and X-ray
radiation as well as energetic particles. These eruptive phenomena can
have a significant impact on Earth's upper atmosphere and space
environment, and are the primary drivers of what is now called space
weather.

The occurrence frequency of coronal mass ejections and flares is strongly
modulated by the solar activity cycle. Flares of any given size are some
50 times more frequent at solar maximum than at minimum. Large coronal
mass ejections occur on average a few times a day at solar maximum, down
to one every few days at solar minimum. The size of these events
themselves does not depend sensitively on the phase of the solar cycle. A
good recent case in point are the three large X-class flares having
occurred in December 2006, very near solar minimum; one of these (an X9.0
flare on Dec 5) stands as one of the brightest on record.^[17]



[edit ] Cosmic ray flux

The outward expansion of solar ejecta into interplanetary space provides
overdensities of plasma that are efficient at scattering high-energy
cosmic rays entering the solar system from elsewhere in the galaxy. Since
the frequency of solar eruptive events is strongly modulated by the solar
cycle, the degree of cosmic ray scattering in the outer solar system
varies in step. As a consequence, the cosmic ray flux in the inner solar
system is anticorrelated with the overall level of solar activity. This
anticorrelation is clearly detected in cosmic ray flux measurements at the
Earth's surface.



A drawing of a sunspot in the Chronicles of John of Worcester .

Some high-energy cosmic rays entering Earth's atmosphere collide hard
enough with molecular atmospheric constituents to cause occasionally
nuclear spallation reactions . Some of the fission products include
radionuclides such as ^14 C and ^10 Be, which settle down on Earth's
surface. Their concentration can be measured in ice cores, allowing a
reconstruction of solar activity levels into the distant past.^[18] Such
reconstructions indicate that the overall level of solar activity since
the middle of the twentieth century stands amongst the highest of the past
10,000 years, and that Maunder minimum-like epochs of suppressed activity,
of varying durations have occurred repeatedly over that time span.


[edit ] Effects on Earth

Main article: Solar variation

The impact of Solar cycle on living organisms has been investigated (see
chronobiology ). Some researchers claim to have found connections with
human health.^[19] ^[20]


The amount of UVB light at 300 nm reaching the Earth varies by as much as
400% over the solar cycle due to variations in the protective ozone layer
. In the stratosphere, ozone is continuously regenerated by the splitting
of O_2 molecules by ultraviolet light. During a solar minimum, the
decrease in ultraviolet light received from the Sun leads to a decrease in
the concentration of ozone, allowing increased UVB to penetrate to the
Earth's surface.^[21]

The sunspot cycle has been implicated in having effects on climate, and
may play a part in determining global temperature.

Main article: Skywave

Skywave modes of radio communication operate by bending (refracting )
radio waves (electromagnetic radiation ) off of the Ionosphere . During
the "peaks" of the solar cycle, the ionosphere becomes ionized by solar
photons and cosmic rays . This affects the path (propagation ) of the
radio wave in complex ways which can both facilitate or hinder local and
long distance communications. Forecasting of skywave modes is of
considerable interest to commercial marine and aircraft communications ,
amateur radio operators , and shortwave broadcasters . These users utilize
frequencies within the High Frequency or 'HF' radio spectrum which are
most affected by these solar and ionospheric variances. Changes in solar
output affect the maximum usable frequency , a limit on the highest
frequency usable for communications.