text
stringlengths 4
3.84k
|
|---|
= = = = <unk> stars = = = =
|
The post β main @-@ sequence evolution of binary stars may be significantly different from the evolution of single stars of the same mass . If stars in a binary system are sufficiently close , when one of the stars expands to become a red giant it may overflow its Roche lobe , the region around a star where material is gravitationally bound to that star , leading to transfer of material to the other . When the Roche lobe is violated , a variety of phenomena can result , including contact binaries , common @-@ envelope binaries , <unk> variables , and type <unk> supernovae .
|
= = Distribution = =
|
In addition to isolated stars , a multi @-@ star system can consist of two or more gravitationally bound stars that orbit each other . The simplest and most common multi @-@ star system is a binary star , but systems of three or more stars are also found . For reasons of orbital stability , such multi @-@ star systems are often organized into hierarchical sets of binary stars . Larger groups called star clusters also exist . These range from loose stellar associations with only a few stars , up to enormous globular clusters with hundreds of thousands of stars . Such systems orbit our Milky Way galaxy .
|
It has been a long @-@ held assumption that the majority of stars occur in gravitationally bound , multiple @-@ star systems . This is particularly true for very massive O and B class stars , where 80 % of the stars are believed to be part of multiple @-@ star systems . The proportion of single star systems increases with decreasing star mass , so that only 25 % of red dwarfs are known to have stellar companions . As 85 % of all stars are red dwarfs , most stars in the Milky Way are likely single from birth .
|
Stars are not spread uniformly across the universe , but are normally grouped into galaxies along with interstellar gas and dust . A typical galaxy contains hundreds of billions of stars , and there are more than 100 billion ( <unk> ) galaxies in the observable universe . In 2010 , one estimate of the number of stars in the observable universe was 300 <unk> ( 3 Γ 1023 ) . While it is often believed that stars only exist within galaxies , <unk> stars have been discovered .
|
The nearest star to the Earth , apart from the Sun , is <unk> <unk> , which is 39 @.@ 9 trillion kilometres , or 4 @.@ 2 light @-@ years . Travelling at the orbital speed of the Space Shuttle ( 8 kilometres per second β almost 30 @,@ 000 kilometres per hour ) , it would take about 150 @,@ 000 years to arrive . This it typical of stellar <unk> in galactic discs . Stars can be much closer to each other in the centres of galaxies and in globular clusters , or much farther apart in galactic <unk> .
|
Due to the relatively vast distances between stars outside the galactic nucleus , collisions between stars are thought to be rare . In denser regions such as the core of globular clusters or the galactic center , collisions can be more common . Such collisions can produce what are known as blue stragglers . These abnormal stars have a higher surface temperature than the other main sequence stars with the same luminosity of the cluster to which it belongs .
|
= = Characteristics = =
|
Almost everything about a star is determined by its initial mass , including such characteristics as luminosity , size , evolution , lifespan , and its eventual fate .
|
= = = Age = = =
|
Most stars are between 1 billion and 10 billion years old . Some stars may even be close to 13 @.@ 8 billion years old β the observed age of the universe . The oldest star yet discovered , HD <unk> , nicknamed <unk> star , is an estimated 14 @.@ 46 Β± 0 @.@ 8 billion years old . ( Due to the uncertainty in the value , this age for the star does not conflict with the age of the Universe , determined by the Planck satellite as 13 @.@ 799 Β± 0 @.@ <unk> ) .
|
The more massive the star , the shorter its lifespan , primarily because massive stars have greater pressure on their cores , causing them to burn hydrogen more rapidly . The most massive stars last an average of a few million years , while stars of minimum mass ( red dwarfs ) burn their fuel very slowly and can last tens to hundreds of billions of years .
|
= = = Chemical composition = = =
|
When stars form in the present Milky Way galaxy they are composed of about 71 % hydrogen and 27 % helium , as measured by mass , with a small fraction of heavier elements . Typically the portion of heavy elements is measured in terms of the iron content of the stellar atmosphere , as iron is a common element and its absorption lines are relatively easy to measure . The portion of heavier elements may be an indicator of the likelihood that the star has a planetary system .
|
The star with the lowest iron content ever measured is the dwarf <unk> @-@ <unk> , with only 1 / <unk> the iron content of the Sun . By contrast , the super @-@ metal @-@ rich star <unk> <unk> has nearly double the abundance of iron as the Sun , while the planet @-@ bearing star 14 <unk> has nearly triple the iron . There also exist chemically peculiar stars that show unusual <unk> of certain elements in their spectrum ; especially <unk> and rare earth elements . Stars with cooler outer atmospheres , including the Sun , can form various <unk> and <unk> molecules .
|
= = = <unk> = = =
|
Due to their great distance from the Earth , all stars except the Sun appear to the unaided eye as shining points in the night sky that <unk> because of the effect of the Earth 's atmosphere . The Sun is also a star , but it is close enough to the Earth to appear as a disk instead , and to provide daylight . Other than the Sun , the star with the largest apparent size is R <unk> , with an angular diameter of only 0 @.@ <unk> <unk> .
|
The disks of most stars are much too small in angular size to be observed with current ground @-@ based optical telescopes , and so <unk> telescopes are required to produce images of these objects . Another technique for measuring the angular size of stars is through <unk> . By precisely measuring the drop in brightness of a star as it is <unk> by the Moon ( or the rise in brightness when it reappears ) , the star 's angular diameter can be computed .
|
Stars range in size from neutron stars , which vary anywhere from 20 to 40 km ( 25 mi ) in diameter , to supergiants like <unk> in the Orion constellation , which has a diameter approximately 1 @,@ 070 times that of the Sun β about 1 @,@ 490 @,@ 171 @,@ 880 km ( <unk> @,@ <unk> @,@ 878 mi ) . <unk> , however , has a much lower density than the Sun .
|
= = = <unk> = = =
|
The motion of a star relative to the Sun can provide useful information about the origin and age of a star , as well as the structure and evolution of the surrounding galaxy . The components of motion of a star consist of the radial velocity toward or away from the Sun , and the traverse angular movement , which is called its proper motion .
|
<unk> velocity is measured by the <unk> shift of the star 's spectral lines , and is given in units of km / s . The proper motion of a star , its parallax , is determined by precise <unk> measurements in units of <unk> @-@ arc seconds ( <unk> ) per year . With knowledge of the star 's parallax and its distance , the proper motion velocity can be calculated . Together with the radial velocity , the total velocity can be calculated . Stars with high rates of proper motion are likely to be relatively close to the Sun , making them good candidates for parallax measurements .
|
When both rates of movement are known , the space velocity of the star relative to the Sun or the galaxy can be computed . Among nearby stars , it has been found that younger population I stars have generally lower <unk> than older , population II stars . The latter have elliptical orbits that are inclined to the plane of the galaxy . A comparison of the <unk> of nearby stars has allowed astronomers to trace their origin to common points in giant molecular clouds , and are referred to as stellar associations .
|
= = = Magnetic field = = =
|
The magnetic field of a star is generated within regions of the interior where convective circulation occurs . This movement of <unk> plasma functions like a <unk> , wherein the movement of <unk> charges induce magnetic fields , as does a mechanical <unk> . Those magnetic fields have a great range that extend throughout and beyond the star . The strength of the magnetic field varies with the mass and composition of the star , and the amount of magnetic surface activity depends upon the star 's rate of rotation . This surface activity produces starspots , which are regions of strong magnetic fields and lower than normal surface temperatures . <unk> loops are <unk> magnetic field flux lines that rise from a star 's surface into the star 's outer atmosphere , its corona . The <unk> loops can be seen due to the plasma they conduct along their length . <unk> flares are bursts of high @-@ energy particles that are emitted due to the same magnetic activity .
|
Young , rapidly rotating stars tend to have high levels of surface activity because of their magnetic field . The magnetic field can act upon a star 's stellar wind , functioning as a brake to gradually slow the rate of rotation with time . Thus , older stars such as the Sun have a much slower rate of rotation and a lower level of surface activity . The activity levels of slowly rotating stars tend to vary in a cyclical manner and can shut down altogether for periods of time . During the <unk> minimum , for example , the Sun underwent a 70 @-@ year period with almost no sunspot activity .
|
= = = Mass = = =
|
One of the most massive stars known is <unk> <unk> , which , with 100 β 150 times as much mass as the Sun , will have a lifespan of only several million years . Studies of the most massive open clusters suggests 150 M β as an upper limit for stars in the current era of the universe . This represents an <unk> value for the theoretical limit on the mass of forming stars due to increasing radiation pressure on the <unk> gas cloud . Several stars in the <unk> cluster in the Large <unk> Cloud have been measured with larger masses , but it has been determined that they could have been created through the collision and merger of massive stars in close binary systems , <unk> the 150 M β limit on massive star formation .
|
The first stars to form after the Big Bang may have been larger , up to 300 M β , due to the complete absence of elements heavier than lithium in their composition . This generation of <unk> population III stars is likely to have existed in the very early universe ( i.e. , they are observed to have a high <unk> ) , and may have started the production of chemical elements heavier than hydrogen that are needed for the later formation of planets and life . In June 2015 , astronomers reported evidence for Population III stars in the Cosmos <unk> 7 galaxy at <unk> = 6 @.@ 60 .
|
With a mass only 80 times that of Jupiter ( MJ ) , <unk> <unk> @-@ <unk> is the smallest known star undergoing nuclear fusion in its core . For stars with metallicity similar to the Sun , the theoretical minimum mass the star can have and still undergo fusion at the core , is estimated to be about 75 MJ . When the metallicity is very low , however , the minimum star size seems to be about 8 @.@ 3 % of the solar mass , or about 87 MJ . Smaller bodies called brown dwarfs , occupy a poorly defined grey area between stars and gas giants .
|
The combination of the radius and the mass of a star determines its surface gravity . Giant stars have a much lower surface gravity than do main sequence stars , while the opposite is the case for degenerate , compact stars such as white dwarfs . The surface gravity can influence the appearance of a star 's spectrum , with higher gravity causing a broadening of the absorption lines .
|
= = = <unk> = = =
|
The rotation rate of stars can be determined through spectroscopic measurement , or more exactly determined by tracking their starspots . Young stars can have a rotation greater than 100 km / s at the equator . The B @-@ class star <unk> , for example , has an equatorial velocity of about 225 km / s or greater , causing its equator to be <unk> outward and giving it an equatorial diameter that is more than 50 % greater than between the poles . This rate of rotation is just below the critical velocity of 300 km / s at which speed the star would break apart . By contrast , the Sun <unk> once every 25 β 35 days , with an equatorial velocity of 1 @.@ <unk> km / s . A main sequence star 's magnetic field and the stellar wind serve to slow its rotation by a significant amount as it evolves on the main sequence .
|
<unk> stars have contracted into a compact mass , resulting in a rapid rate of rotation . However they have relatively low rates of rotation compared to what would be expected by conservation of angular momentum β the tendency of a rotating body to compensate for a contraction in size by increasing its rate of spin . A large portion of the star 's angular momentum is dissipated as a result of mass loss through the stellar wind . In spite of this , the rate of rotation for a pulsar can be very rapid . The pulsar at the heart of the Crab nebula , for example , <unk> 30 times per second . The rotation rate of the pulsar will gradually slow due to the emission of radiation .
|
= = = <unk> = = =
|
The surface temperature of a main sequence star is determined by the rate of energy production of its core and by its radius , and is often estimated from the star 's color index . The temperature is normally given in terms of an effective temperature , which is the temperature of an <unk> black body that radiates its energy at the same luminosity per surface area as the star . Note that the effective temperature is only a representative of the surface , as the temperature increases toward the core . The temperature in the core region of a star is several million <unk> .
|
The stellar temperature will determine the rate of ionization of various elements , resulting in characteristic absorption lines in the spectrum . The surface temperature of a star , along with its visual absolute magnitude and absorption features , is used to classify a star ( see classification below ) .
|
Massive main sequence stars can have surface temperatures of 50 @,@ 000 K. Smaller stars such as the Sun have surface temperatures of a few thousand K. Red giants have relatively low surface temperatures of about 3 @,@ 600 K ; but they also have a high luminosity due to their large exterior surface area .
|
= = Radiation = =
|
The energy produced by stars , a product of nuclear fusion , radiates to space as both electromagnetic radiation and particle radiation . The particle radiation emitted by a star is <unk> as the stellar wind , which streams from the outer layers as electrically charged protons and alpha and beta particles . Although almost <unk> , there also exists a steady stream of neutrinos emanating from the star 's core .
|
The production of energy at the core is the reason stars shine so brightly : every time two or more atomic nuclei fuse together to form a single atomic nucleus of a new heavier element , gamma ray photons are released from the nuclear fusion product . This energy is converted to other forms of electromagnetic energy of lower frequency , such as visible light , by the time it reaches the star 's outer layers .
|
The color of a star , as determined by the most intense frequency of the visible light , depends on the temperature of the star 's outer layers , including its photosphere . Besides visible light , stars also emit forms of electromagnetic radiation that are invisible to the human eye . In fact , stellar electromagnetic radiation spans the entire electromagnetic spectrum , from the longest <unk> of radio waves through infrared , visible light , ultraviolet , to the shortest of X @-@ rays , and gamma rays . From the standpoint of total energy emitted by a star , not all components of stellar electromagnetic radiation are significant , but all frequencies provide insight into the star 's physics .
|
Using the stellar spectrum , astronomers can also determine the surface temperature , surface gravity , metallicity and rotational velocity of a star . If the distance of the star is found , such as by measuring the parallax , then the luminosity of the star can be derived . The mass , radius , surface gravity , and rotation period can then be estimated based on stellar models . ( Mass can be calculated for stars in binary systems by measuring their orbital <unk> and distances . <unk> <unk> has been used to measure the mass of a single star . ) With these parameters , astronomers can also estimate the age of the star .
|
= = = <unk> = = =
|
The luminosity of a star is the amount of light and other forms of <unk> energy it radiates per unit of time . It has units of power . The luminosity of a star is determined by its radius and surface temperature . Many stars do not radiate uniformly across their entire surface . The rapidly rotating star Vega , for example , has a higher energy flux ( power per unit area ) at its poles than along its equator .
|
<unk> of the star 's surface with a lower temperature and luminosity than average are known as starspots . Small , dwarf stars such as our Sun generally have essentially <unk> disks with only small starspots . Giant stars have much larger , more obvious starspots , and they also exhibit strong stellar limb darkening . That is , the brightness decreases towards the edge of the stellar disk . Red dwarf flare stars such as <unk> <unk> may also possess prominent <unk> features .
|
= = = <unk> = = =
|
The apparent brightness of a star is expressed in terms of its apparent magnitude . It is a function of the star 's luminosity , its distance from Earth , and the altering of the star 's light as it passes through Earth 's atmosphere . <unk> or absolute magnitude is directly related to a star 's luminosity , and is what the apparent magnitude a star would be if the distance between the Earth and the star were 10 <unk> ( 32 @.@ 6 light @-@ years ) .
|
Both the apparent and absolute magnitude scales are <unk> units : one whole number difference in magnitude is equal to a brightness variation of about 2 @.@ 5 times ( the 5th root of 100 or approximately 2 @.@ 512 ) . This means that a first magnitude star ( + 1 @.@ 00 ) is about 2 @.@ 5 times brighter than a second magnitude ( + 2 @.@ 00 ) star , and about 100 times brighter than a sixth magnitude star ( + 6 @.@ 00 ) . The faintest stars visible to the naked eye under good seeing conditions are about magnitude + 6 .
|
On both apparent and absolute magnitude scales , the smaller the magnitude number , the brighter the star ; the larger the magnitude number , the <unk> the star . The brightest stars , on either scale , have negative magnitude numbers . The variation in brightness ( <unk> ) between two stars is calculated by <unk> the magnitude number of the brighter star ( mb ) from the magnitude number of the <unk> star ( <unk> ) , then using the difference as an exponent for the base number 2 @.@ 512 ; that is to say :
|
<formula>
|
<formula>
|
Relative to both luminosity and distance from Earth , a star 's absolute magnitude ( M ) and apparent magnitude ( m ) are not equivalent ; for example , the bright star Sirius has an apparent magnitude of β 1 @.@ 44 , but it has an absolute magnitude of + 1 @.@ 41 .
|
The Sun has an apparent magnitude of β 26 @.@ 7 , but its absolute magnitude is only + 4 @.@ 83 . Sirius , the brightest star in the night sky as seen from Earth , is approximately 23 times more luminous than the Sun , while Canopus , the second brightest star in the night sky with an absolute magnitude of β 5 @.@ 53 , is approximately 14 @,@ 000 times more luminous than the Sun . Despite Canopus being vastly more luminous than Sirius , however , Sirius appears brighter than Canopus . This is because Sirius is merely 8 @.@ 6 light @-@ years from the Earth , while Canopus is much farther away at a distance of 310 light @-@ years .
|
As of 2006 , the star with the highest known absolute magnitude is <unk> 1806 @-@ 20 , with a magnitude of β 14 @.@ 2 . This star is at least 5 @,@ 000 @,@ 000 times more luminous than the Sun . The least luminous stars that are currently known are located in the <unk> <unk> cluster . The faintest red dwarfs in the cluster were magnitude 26 , while a 28th magnitude white dwarf was also discovered . These faint stars are so dim that their light is as bright as a birthday <unk> on the Moon when viewed from the Earth .
|
= = Classification = =
|
The current stellar classification system originated in the early 20th century , when stars were classified from A to Q based on the strength of the hydrogen line . It thought that the hydrogen line strength was a simple linear function of temperature . Rather , it was more complicated ; it strengthened with increasing temperature , it peaked near 9000 K , and then declined at greater temperatures . When the classifications were <unk> by temperature , it more closely resembled the modern scheme .
|
Stars are given a single @-@ letter classification according to their spectra , ranging from type O , which are very hot , to M , which are so cool that molecules may form in their atmospheres . The main classifications in order of decreasing surface temperature are : O , B , A , F , G , K , and M. A variety of rare spectral types are given special classifications . The most common of these are types L and T , which classify the coldest low @-@ mass stars and brown dwarfs . Each letter has 10 sub @-@ divisions , numbered from 0 to 9 , in order of decreasing temperature . However , this system breaks down at extreme high temperatures as classes <unk> and <unk> may not exist .
|
In addition , stars may be classified by the luminosity effects found in their spectral lines , which correspond to their spatial size and is determined by their surface gravity . These range from 0 ( <unk> ) through III ( giants ) to V ( main sequence dwarfs ) ; some authors add VII ( white dwarfs ) . Most stars belong to the main sequence , which consists of ordinary hydrogen @-@ burning stars . These fall along a narrow , diagonal band when <unk> according to their absolute magnitude and spectral type . The Sun is a main sequence <unk> yellow dwarf of intermediate temperature and ordinary size .
|
Additional nomenclature , in the form of lower @-@ case letters added to the end of the spectral type to indicate peculiar features of the spectrum . For example , an " e " can indicate the presence of emission lines ; " m " represents unusually strong levels of metals , and " <unk> " can mean variations in the spectral type .
|
White dwarf stars have their own class that begins with the letter D. This is further sub @-@ divided into the classes <unk> , <unk> , DC , <unk> , <unk> , and <unk> , depending on the types of prominent lines found in the spectrum . This is followed by a numerical value that indicates the temperature .
|
= = <unk> stars = =
|
<unk> stars have periodic or random changes in luminosity because of intrinsic or <unk> properties . Of the intrinsically variable stars , the primary types can be subdivided into three principal groups .
|
During their stellar evolution , some stars pass through phases where they can become <unk> variables . <unk> variable stars vary in radius and luminosity over time , expanding and contracting with periods ranging from minutes to years , depending on the size of the star . This category includes <unk> and <unk> @-@ like stars , and long @-@ period variables such as Mira .
|
<unk> variables are stars that experience sudden increases in luminosity because of flares or mass <unk> events . This group includes <unk> , Wolf @-@ <unk> stars , and flare stars , as well as giant and <unk> stars .
|
<unk> or explosive variable stars are those that undergo a dramatic change in their properties . This group includes novae and supernovae . A binary star system that includes a nearby white dwarf can produce certain types of these spectacular stellar explosions , including the nova and a Type <unk> supernova . The explosion is created when the white dwarf <unk> hydrogen from the companion star , building up mass until the hydrogen undergoes fusion . Some novae are also recurrent , having periodic outbursts of moderate <unk> .
|
Stars can also vary in luminosity because of <unk> factors , such as eclipsing binaries , as well as rotating stars that produce extreme starspots . A notable example of an eclipsing binary is <unk> , which regularly varies in magnitude from 2 @.@ 3 to 3 @.@ 5 over a period of 2 @.@ 87 days .
|
= = Structure = =
|
The interior of a stable star is in a state of hydrostatic equilibrium : the forces on any small volume almost exactly counterbalance each other . The balanced forces are inward gravitational force and an outward force due to the pressure gradient within the star . The pressure gradient is established by the temperature gradient of the plasma ; the outer part of the star is cooler than the core . The temperature at the core of a main sequence or giant star is at least on the order of 107 K. The resulting temperature and pressure at the hydrogen @-@ burning core of a main sequence star are sufficient for nuclear fusion to occur and for sufficient energy to be produced to prevent further collapse of the star .
|
As atomic nuclei are fused in the core , they emit energy in the form of gamma rays . These photons interact with the surrounding plasma , adding to the thermal energy at the core . Stars on the main sequence convert hydrogen into helium , creating a slowly but steadily increasing proportion of helium in the core . Eventually the helium content becomes predominant , and energy production ceases at the core . Instead , for stars of more than 0 @.@ 4 M β , fusion occurs in a slowly expanding shell around the degenerate helium core .
|
In addition to hydrostatic equilibrium , the interior of a stable star will also maintain an energy balance of thermal equilibrium . There is a radial temperature gradient throughout the interior that results in a flux of energy flowing toward the exterior . The outgoing flux of energy leaving any layer within the star will exactly match the incoming flux from below .
|
The radiation zone is the region of the stellar interior where the flux of energy outward is dependent on radiative heat transfer , since convective heat transfer is inefficient in that zone . In this region the plasma will not be <unk> , and any mass motions will die out . If this is not the case , however , then the plasma becomes unstable and convection will occur , forming a convection zone . This can occur , for example , in regions where very high energy <unk> occur , such as near the core or in areas with high <unk> ( making <unk> heat transfer inefficient ) as in the outer envelope .
|
The occurrence of convection in the outer envelope of a main sequence star depends on the star 's mass . Stars with several times the mass of the Sun have a convection zone deep within the interior and a radiative zone in the outer layers . Smaller stars such as the Sun are just the opposite , with the convective zone located in the outer layers . Red dwarf stars with less than 0 @.@ 4 M β are convective throughout , which prevents the <unk> of a helium core . For most stars the convective zones will also vary over time as the star ages and the constitution of the interior is modified .
|
The photosphere is that portion of a star that is visible to an observer . This is the layer at which the plasma of the star becomes transparent to photons of light . From here , the energy generated at the core becomes free to propagate into space . It is within the photosphere that sun spots , regions of lower than average temperature , appear .
|
Above the level of the photosphere is the stellar atmosphere . In a main sequence star such as the Sun , the lowest level of the atmosphere , just above the photosphere , is the thin <unk> region , where <unk> appear and stellar flares begin . Above this is the transition region , where the temperature rapidly increases within a distance of only 100 km ( 62 mi ) . Beyond this is the corona , a volume of super @-@ heated plasma that can extend outward to several million kilometres . The existence of a corona appears to be dependent on a convective zone in the outer layers of the star . Despite its high temperature , and the corona emits very little light , due to its low gas density . The corona region of the Sun is normally only visible during a solar eclipse .
|
From the corona , a stellar wind of plasma particles expands outward from the star , until it interacts with the interstellar medium . For the Sun , the influence of its solar wind extends throughout a bubble @-@ shaped region called the <unk> .
|
= = Nuclear fusion reaction pathways = =
|
A variety of nuclear fusion reactions take place in the cores of stars , that depend upon their mass and composition . When nuclei fuse , the mass of the fused product is less than the mass of the original parts . This lost mass is converted to electromagnetic energy , according to the mass @-@ energy equivalence relationship E = <unk> .
|
The hydrogen fusion process is temperature @-@ sensitive , so a moderate increase in the core temperature will result in a significant increase in the fusion rate . As a result , the core temperature of main sequence stars only varies from 4 million kelvin for a small M @-@ class star to 40 million kelvin for a massive O @-@ class star .
|
In the Sun , with a 10 @-@ million @-@ kelvin core , hydrogen fuses to form helium in the proton @-@ proton chain reaction :
|
<unk> β <unk> + 2e + + <unk> ( 2 x 0 @.@ 4 MeV )
|
2e + + <unk> β 2Ξ³ ( 2 x 1 @.@ 0 MeV )
|
<unk> + <unk> β <unk> + 2Ξ³ ( 2 x 5 @.@ 5 MeV )
|
<unk> β 4He + <unk> ( 12 @.@ 9 MeV )
|
These reactions result in the overall reaction :
|
<unk> β 4He + 2e + + 2Ξ³ + <unk> ( 26 @.@ 7 MeV )
|
where e + is a positron , Ξ³ is a gamma ray <unk> , <unk> is a neutrino , and H and He are isotopes of hydrogen and helium , respectively . The energy released by this reaction is in millions of electron volts , which is actually only a tiny amount of energy . However enormous numbers of these reactions occur constantly , producing all the energy necessary to sustain the star 's radiation output . In comparison , the combustion of two hydrogen gas molecules with one oxygen gas molecule releases only 5 @.@ 7 <unk> .
|
In more massive stars , helium is produced in a cycle of reactions <unk> by carbon called the carbon @-@ nitrogen @-@ oxygen cycle .
|
In evolved stars with cores at 100 million kelvin and masses between 0 @.@ 5 and 10 M β , helium can be transformed into carbon in the triple @-@ alpha process that uses the intermediate element beryllium :
|
4He + 4He + 92 keV β 8 * Be
|
4He + 8 * Be + 67 keV β 12 * C
|
12 * C β <unk> + Ξ³ + 7 @.@ 4 MeV
|
For an overall reaction of :
|
<unk> β <unk> + Ξ³ + 7 @.@ 2 MeV
|
In massive stars , heavier elements can also be burned in a contracting core through the neon burning process and oxygen burning process . The final stage in the stellar nucleosynthesis process is the silicon burning process that results in the production of the stable isotope iron @-@ 56 , an <unk> process that consumes energy , and so further energy can only be produced through gravitational collapse .
|
The example below shows the amount of time required for a star of 20 M β to consume all of its nuclear fuel . As an O @-@ class main sequence star , it would be 8 times the solar radius and 62 @,@ 000 times the Sun 's luminosity .
|
= Perry the <unk> =
|
Perry the <unk> , also known as Agent P or simply Perry , is an anthropomorphic platypus from the animated series Phineas and Ferb . Perry was created by the series ' co @-@ founders , Dan Povenmire and Jeff " <unk> " Marsh . He first appeared along with the majority of the main cast in the pilot episode " <unk> . " Perry is featured as the star of the B @-@ plot for every episode of the series , alongside his nemesis Dr. Heinz Doofenshmirtz . A mostly silent character , his lone vocal characteristic ( a <unk> of Perry 's beak ) was provided by Dee Bradley Baker .
|
Perry is the pet platypus of the Flynn @-@ Fletcher family , and is perceived as mindless and domesticated . In secret , however , he lives a double life as a member of an all @-@ animal espionage organization referred to as O.W.C.A. ( The Organization Without a Cool <unk> ) . Many secret entrances to his underground lair exist all around the house ; such as the side of the house , most notably the tree that his owners sit under in the backyard , and several other everyday objects that seem to <unk> the family 's attention . He engages in daily battles with Dr. Heinz Doofenshmirtz , an evil scientist who desires to take over the Tri @-@ state area with obscure contraptions that work perfectly according to his intended function but fail in his application of them every time .
|
Subsets and Splits
No community queries yet
The top public SQL queries from the community will appear here once available.