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H II region

February 16, 2023

An H II region or HII region is a region of interstellar atomic hydrogen that is ionized.[1] It is typically in a molecular cloud of partially ionized gas in which star formation has recently taken place, with a size ranging from one to hundreds of light years, and density from a few to about a million particles per cubic centimetre. The Orion Nebula, now known to be an H II region, was observed in 1610 by Nicolas-Claude Fabri de Peiresc by telescope, the first such object discovered.

NGC 604, a giant H II region in the Triangulum Galaxy

The regions may be of any shape because the distribution of the stars and gas inside them is irregular. The short-lived blue stars created in these regions emit copious amounts of ultraviolet light that ionize the surrounding gas. H II regions—sometimes several hundred light-years across—are often associated with giant molecular clouds. They often appear clumpy and filamentary, sometimes showing intricate shapes such as the Horsehead Nebula. H II regions may give birth to thousands of stars over a period of several million years. In the end, supernova explosions and strong stellar winds from the most massive stars in the resulting star cluster disperse the gases of the H II region, leaving a cluster of stars which have formed.

H II regions can be observed at considerable distances in the universe, and the study of extragalactic H II regions is important in determining the distances and chemical composition of galaxies. Spiral and irregular galaxies contain many H II regions, while elliptical galaxies are almost devoid of them. In spiral galaxies, including our Milky Way, H II regions are concentrated in the spiral arms, while in irregular galaxies they are distributed chaotically. Some galaxies contain huge H II regions, which may contain tens of thousands of stars. Examples include the 30 Doradus region in the Large Magellanic Cloud and NGC 604 in the Triangulum Galaxy.

Terminology

 
Bubbles of brand new stars LHA 120-N 180B.[2]

The term H II is pronounced "H two" by astronomers. "H" is the chemical symbol for hydrogen, and "II" is the Roman numeral for 2. It is customary in astronomy to use the Roman numeral I for neutral atoms, II for singly-ionised—H II is H+ in other sciences—III for doubly-ionised, e.g. O III is O2+, etc.[3] H II, or H+, consists of free protons. An H I region consists of neutral atomic hydrogen, and a molecular cloud of molecular hydrogen, H2. In spoken discussion with non-astronomers there is sometimes confusion between the identical spoken forms of "H II" and "H2".

Observations

 
Dark star-forming regions within the Eagle Nebula commonly referred to as the Pillars of Creation

A few of the brightest H II regions are visible to the naked eye. However, none seem to have been noticed before the advent of the telescope in the early 17th century. Even Galileo did not notice the Orion Nebula when he first observed the star cluster within it (previously cataloged as a single star, θ Orionis, by Johann Bayer). The French observer Nicolas-Claude Fabri de Peiresc is credited with the discovery of the Orion Nebula in 1610.[4] Since that early observation large numbers of H II regions have been discovered in the Milky Way and other galaxies.[5]

William Herschel observed the Orion Nebula in 1774, and described it later as "an unformed fiery mist, the chaotic material of future suns".[6] In early days astronomers distinguished between "diffuse nebulae" (now known to be H II regions), which retained their fuzzy appearance under magnification through a large telescope, and nebulae that could be resolved into stars, now known to be galaxies external to our own.[7]

Confirmation of Herschel's hypothesis of star formation had to wait another hundred years, when William Huggins together with his wife Mary Huggins turned his spectroscope on various nebulae. Some, such as the Andromeda Nebula, had spectra quite similar to those of stars, but turned out to be galaxies consisting of hundreds of millions of individual stars. Others looked very different. Rather than a strong continuum with absorption lines superimposed, the Orion Nebula and other similar objects showed only a small number of emission lines.[8] In planetary nebulae, the brightest of these spectral lines was at a wavelength of 500.7 nanometres, which did not correspond with a line of any known chemical element. At first it was hypothesized that the line might be due to an unknown element, which was named nebulium—a similar idea had led to the discovery of helium through analysis of the Sun's spectrum in 1868.[9] However, while helium was isolated on earth soon after its discovery in the spectrum of the sun, nebulium was not. In the early 20th century, Henry Norris Russell proposed that rather than being a new element, the line at 500.7 nm was due to a familiar element in unfamiliar conditions.[10]

Interstellar matter, considered dense in an astronomical context, is at high vacuum by laboratory standards. Physicists showed in the 1920s that in gas at extremely low density, electrons can populate excited metastable energy levels in atoms and ions, which at higher densities are rapidly de-excited by collisions.[11] Electron transitions from these levels in doubly ionized oxygen give rise to the 500.7 nm line.[12] These spectral lines, which can only be seen in very low density gases, are called forbidden lines. Spectroscopic observations thus showed that planetary nebulae consisted largely of extremely rarefied ionised oxygen gas (OIII).

During the 20th century, observations showed that H II regions often contained hot, bright stars.[12] These stars are many times more massive than the Sun, and are the shortest-lived stars, with total lifetimes of only a few million years (compared to stars like the Sun, which live for several billion years). Therefore, it was surmised that H II regions must be regions in which new stars were forming.[12] Over a period of several million years, a cluster of stars will form in an H II region, before radiation pressure from the hot young stars causes the nebula to disperse.[13]

Origin and lifetime

See also: Stellar evolution
 
A small portion of the Tarantula Nebula, a giant H II region in the Large Magellanic Cloud

The precursor to an H II region is a giant molecular cloud (GMC). A GMC is a cold (10–20 K) and dense cloud consisting mostly of molecular hydrogen.[5] GMCs can exist in a stable state for long periods of time, but shock waves due to supernovae, collisions between clouds, and magnetic interactions can trigger its collapse. When this happens, via a process of collapse and fragmentation of the cloud, stars are born (see stellar evolution for a lengthier description).[13]

As stars are born within a GMC, the most massive will reach temperatures hot enough to ionise the surrounding gas.[5] Soon after the formation of an ionising radiation field, energetic photons create an ionisation front, which sweeps through the surrounding gas at supersonic speeds. At greater and greater distances from the ionising star, the ionisation front slows, while the pressure of the newly ionised gas causes the ionised volume to expand. Eventually, the ionisation front slows to subsonic speeds, and is overtaken by the shock front caused by the expansion of the material ejected from the nebula. The H II region has been born.[14]

The lifetime of an H II region is of the order of a few million years.[15] Radiation pressure from the hot young stars will eventually drive most of the gas away. In fact, the whole process tends to be very inefficient, with less than 10 percent of the gas in the H II region forming into stars before the rest is blown off.[13] Contributing to the loss of gas are the supernova explosions of the most massive stars, which will occur after only 1–2 million years.

Destruction of stellar nurseries

 
Bok globules in H II region IC 2944

Stars form in clumps of cool molecular gas that hide the nascent stars. It is only when the radiation pressure from a star drives away its 'cocoon' that it becomes visible. The hot, blue stars that are powerful enough to ionize significant amounts of hydrogen and form H II regions will do this quickly, and light up the region in which they just formed. The dense regions which contain younger or less massive still-forming stars and which have not yet blown away the material from which they are forming are often seen in silhouette against the rest of the ionised nebula. Bart Bok and E. F. Reilly searched astronomical photographs in the 1940s for "relatively small dark nebulae", following suggestions that stars might be formed from condensations in the interstellar medium; they found several such "approximately circular or oval dark objects of small size", which they referred to as "globules", since referred to as Bok globules.[16] Bok proposed at the December 1946 Harvard Observatory Centennial Symposia that these globules were likely sites of star formation.[17] It was confirmed in 1990 that they were indeed stellar birthplaces.[18] The hot young stars dissipate these globules, as the radiation from the stars powering the H II region drives the material away. In this sense, the stars which generate H II regions act to destroy stellar nurseries. In doing so, however, one last burst of star formation may be triggered, as radiation pressure and mechanical pressure from supernova may act to squeeze globules, thereby enhancing the density within them.[19]

The young stars in H II regions show evidence for containing planetary systems. The Hubble Space Telescope has revealed hundreds of protoplanetary disks (proplyds) in the Orion Nebula.[20] At least half the young stars in the Orion Nebula appear to be surrounded by disks of gas and dust,[21] thought to contain many times as much matter as would be needed to create a planetary system like the Solar System.

Characteristics

Physical properties

 
Messier 17 is an H II region in the constellation Sagittarius.

H II regions vary greatly in their physical properties. They range in size from so-called ultra-compact (UCHII) regions perhaps only a light-year or less across, to giant H II regions several hundred light-years across.[5] Their size is also known as the Stromgren radius and essentially depends on the intensity of the source of ionising photons and the density of the region. Their densities range from over a million particles per cm3 in the ultra-compact H II regions to only a few particles per cm3 in the largest and most extended regions. This implies total masses between perhaps 100 and 105 solar masses.[22]

There are also "ultra-dense H II" regions (UDHII).[23]

Depending on the size of an H II region there may be several thousand stars within it. This makes H II regions more complicated than planetary nebulae, which have only one central ionising source. Typically H II regions reach temperatures of 10,000 K.[5] They are mostly ionised gases with weak magnetic fields with strengths of several nanoteslas.[24] Nevertheless, H II regions are almost always associated with a cold molecular gas, which originated from the same parent GMC.[5] Magnetic fields are produced by these weak moving electric charges in the ionised gas, suggesting that H II regions might contain electric fields.[25]

 
Stellar nursery N159 is an HII region over 150 light-years across.[26]

A number of H II regions also show signs of being permeated by a plasma with temperatures exceeding 10,000,000 K, sufficiently hot to emit X-rays. X-ray observatories such as Einstein and Chandra have noted diffuse X-ray emissions in a number of star-forming regions, notably the Orion Nebula, Messier 17, and the Carina Nebula.[27] The hot gas is likely supplied by the strong stellar winds from O-type stars, which may be heated by supersonic shock waves in the winds, through collisions between winds from different stars, or through colliding winds channeled by magnetic fields. This plasma will rapidly expand to fill available cavities in the molecular clouds due to the high speed of sound in the gas at this temperature. It will also leak out through holes in the periphery of the H II region, which appears to be happening in Messier 17.[28]

Chemically, H II regions consist of about 90% hydrogen. The strongest hydrogen emission line, the H-alpha line at 656.3 nm, gives H II regions their characteristic red colour. (This emission line comes from excited un-ionized hydrogen.) H-beta is also emitted, but at approximately 1/3 of the intensity of H-alpha. Most of the rest of an H II region consists of helium, with trace amounts of heavier elements. Across the galaxy, it is found that the amount of heavy elements in H II regions decreases with increasing distance from the galactic centre.[29] This is because over the lifetime of the galaxy, star formation rates have been greater in the denser central regions, resulting in greater enrichment of those regions of the interstellar medium with the products of nucleosynthesis.

Numbers and distribution

 
Strings of red H II regions delineate the arms of the Whirlpool Galaxy.

H II regions are found only in spiral galaxies like the Milky Way and irregular galaxies. They are not seen in elliptical galaxies. In irregular galaxies, they may be dispersed throughout the galaxy, but in spirals they are most abundant within the spiral arms. A large spiral galaxy may contain thousands of H II regions.[22]

The reason H II regions rarely appear in elliptical galaxies is that ellipticals are believed to form through galaxy mergers.[30] In galaxy clusters, such mergers are frequent. When galaxies collide, individual stars almost never collide, but the GMCs and H II regions in the colliding galaxies are severely agitated.[30] Under these conditions, enormous bursts of star formation are triggered, so rapid that most of the gas is converted into stars rather than the normal rate of 10% or less.

Galaxies undergoing such rapid star formation are known as starburst galaxies. The post-merger elliptical galaxy has a very low gas content, and so H II regions can no longer form.[30] Twenty-first century observations have shown that a very small number of H II regions exist outside galaxies altogether. These intergalactic H II regions may be the remnants of tidal disruptions of small galaxies, and in some cases may represent a new generation of stars in a galaxy's most recently accreted gas.[31]

Morphology

See also: Strömgren sphere

H II regions come in an enormous variety of sizes. They are usually clumpy and inhomogeneous on all scales from the smallest to largest.[5] Each star within an H II region ionises a roughly spherical region—known as a Strömgren sphere—of the surrounding gas, but the combination of ionisation spheres of multiple stars within a H II region and the expansion of the heated nebula into surrounding gases creates sharp density gradients that result in complex shapes.[32] Supernova explosions may also sculpt H II regions. In some cases, the formation of a large star cluster within an H II region results in the region being hollowed out from within. This is the case for NGC 604, a giant H II region in the Triangulum Galaxy.[33] For a H II region which cannot be resolved, some information on the spatial structure (the electron density as a function of the distance from the center, and an estimate of the clumpiness) can be inferred by performing an inverse Laplace transform on the frequency spectrum.

Notable regions

 
An optical image (left) reveals clouds of gas and dust in the Orion Nebula; an infrared image (right) reveals new stars shining within.

Notable Galactic H II regions include the Orion Nebula, the Eta Carinae Nebula, and the Berkeley 59 / Cepheus OB4 Complex.[34] The Orion Nebula, about 500 pc (1,500 light-years) from Earth, is part of OMC-1, a giant molecular cloud that, if visible, would be seen to fill most of the constellation of Orion.[12] The Horsehead Nebula and Barnard's Loop are two other illuminated parts of this cloud of gas.[35] The Orion Nebula is actually a thin layer of ionised gas on the outer border of the OMC-1 cloud. The stars in the Trapezium cluster, and especially θ1 Orionis, are responsible for this ionisation.[12]

The Large Magellanic Cloud, a satellite galaxy of the Milky Way at about 50 kpc (160 thousand light years), contains a giant H II region called the Tarantula Nebula. Measuring at about 200 pc (650 light years) across, this nebula is the most massive and the second-largest H II region in the Local Group.[36] It is much bigger than the Orion Nebula, and is forming thousands of stars, some with masses of over 100 times that of the sun—OB and Wolf-Rayet stars. If the Tarantula Nebula were as close to Earth as the Orion Nebula, it would shine about as brightly as the full moon in the night sky. The supernova SN 1987A occurred in the outskirts of the Tarantula Nebula.[32]

Another giant H II region—NGC 604 is located in M33 spiral galaxy, which is at 817 kpc (2.66 million light years). Measuring at approximately 240 × 250 pc (800 × 830 light years) across, NGC 604 is the second-most-massive H II region in the Local Group after the Tarantula Nebula, although it is slightly larger in size than the latter. It contains around 200 hot OB and Wolf-Rayet stars, which heat the gas inside it to millions of degrees, producing bright X-ray emissions. The total mass of the hot gas in NGC 604 is about 6,000 Solar masses.[33]

Current issues

 
Trifid Nebula seen at different wavelengths

As with planetary nebulae, estimates of the abundance of elements in H II regions are subject to some uncertainty.[37] There are two different ways of determining the abundance of metals (metals in this case are elements other than hydrogen and helium) in nebulae, which rely on different types of spectral lines, and large discrepancies are sometimes seen between the results derived from the two methods.[36] Some astronomers put this down to the presence of small temperature fluctuations within H II regions; others claim that the discrepancies are too large to be explained by temperature effects, and hypothesise the existence of cold knots containing very little hydrogen to explain the observations.[37]

The full details of massive star formation within H II regions are not yet well known. Two major problems hamper research in this area. First, the distance from Earth to large H II regions is considerable, with the nearest H II (California Nebula) region at 300 pc (1,000 light-years);[38] other H II regions are several times that distance from Earth. Secondly, the formation of these stars is deeply obscured by dust, and visible light observations are impossible. Radio and infrared light can penetrate the dust, but the youngest stars may not emit much light at these wavelengths.[35]

See also

References

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External links

 
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  • Information from SEDS
  • Harvard astronomy course notes on H II regions

February 16, 2023
region, region, region, interstellar, atomic, hydrogen, that, ionized, typically, molecular, cloud, partially, ionized, which, star, formation, recently, taken, place, with, size, ranging, from, hundreds, light, years, density, from, about, million, particles,. An H II region or HII region is a region of interstellar atomic hydrogen that is ionized 1 It is typically in a molecular cloud of partially ionized gas in which star formation has recently taken place with a size ranging from one to hundreds of light years and density from a few to about a million particles per cubic centimetre The Orion Nebula now known to be an H II region was observed in 1610 by Nicolas Claude Fabri de Peiresc by telescope the first such object discovered NGC 604 a giant H II region in the Triangulum Galaxy The regions may be of any shape because the distribution of the stars and gas inside them is irregular The short lived blue stars created in these regions emit copious amounts of ultraviolet light that ionize the surrounding gas H II regions sometimes several hundred light years across are often associated with giant molecular clouds They often appear clumpy and filamentary sometimes showing intricate shapes such as the Horsehead Nebula H II regions may give birth to thousands of stars over a period of several million years In the end supernova explosions and strong stellar winds from the most massive stars in the resulting star cluster disperse the gases of the H II region leaving a cluster of stars which have formed H II regions can be observed at considerable distances in the universe and the study of extragalactic H II regions is important in determining the distances and chemical composition of galaxies Spiral and irregular galaxies contain many H II regions while elliptical galaxies are almost devoid of them In spiral galaxies including our Milky Way H II regions are concentrated in the spiral arms while in irregular galaxies they are distributed chaotically Some galaxies contain huge H II regions which may contain tens of thousands of stars Examples include the 30 Doradus region in the Large Magellanic Cloud and NGC 604 in the Triangulum Galaxy Contents 1 Terminology 2 Observations 3 Origin and lifetime 4 Destruction of stellar nurseries 5 Characteristics 5 1 Physical properties 5 2 Numbers and distribution 5 3 Morphology 6 Notable regions 7 Current issues 8 See also 9 References 10 External linksTerminology Edit Bubbles of brand new stars LHA 120 N 180B 2 The term H II is pronounced H two by astronomers H is the chemical symbol for hydrogen and II is the Roman numeral for 2 It is customary in astronomy to use the Roman numeral I for neutral atoms II for singly ionised H II is H in other sciences III for doubly ionised e g O III is O2 etc 3 H II or H consists of free protons An H I region consists of neutral atomic hydrogen and a molecular cloud of molecular hydrogen H2 In spoken discussion with non astronomers there is sometimes confusion between the identical spoken forms of H II and H2 Observations Edit Dark star forming regions within the Eagle Nebula commonly referred to as the Pillars of Creation A few of the brightest H II regions are visible to the naked eye However none seem to have been noticed before the advent of the telescope in the early 17th century Even Galileo did not notice the Orion Nebula when he first observed the star cluster within it previously cataloged as a single star 8 Orionis by Johann Bayer The French observer Nicolas Claude Fabri de Peiresc is credited with the discovery of the Orion Nebula in 1610 4 Since that early observation large numbers of H II regions have been discovered in the Milky Way and other galaxies 5 William Herschel observed the Orion Nebula in 1774 and described it later as an unformed fiery mist the chaotic material of future suns 6 In early days astronomers distinguished between diffuse nebulae now known to be H II regions which retained their fuzzy appearance under magnification through a large telescope and nebulae that could be resolved into stars now known to be galaxies external to our own 7 Confirmation of Herschel s hypothesis of star formation had to wait another hundred years when William Huggins together with his wife Mary Huggins turned his spectroscope on various nebulae Some such as the Andromeda Nebula had spectra quite similar to those of stars but turned out to be galaxies consisting of hundreds of millions of individual stars Others looked very different Rather than a strong continuum with absorption lines superimposed the Orion Nebula and other similar objects showed only a small number of emission lines 8 In planetary nebulae the brightest of these spectral lines was at a wavelength of 500 7 nanometres which did not correspond with a line of any known chemical element At first it was hypothesized that the line might be due to an unknown element which was named nebulium a similar idea had led to the discovery of helium through analysis of the Sun s spectrum in 1868 9 However while helium was isolated on earth soon after its discovery in the spectrum of the sun nebulium was not In the early 20th century Henry Norris Russell proposed that rather than being a new element the line at 500 7 nm was due to a familiar element in unfamiliar conditions 10 Orion Nebula Interstellar matter considered dense in an astronomical context is at high vacuum by laboratory standards Physicists showed in the 1920s that in gas at extremely low density electrons can populate excited metastable energy levels in atoms and ions which at higher densities are rapidly de excited by collisions 11 Electron transitions from these levels in doubly ionized oxygen give rise to the 500 7 nm line 12 These spectral lines which can only be seen in very low density gases are called forbidden lines Spectroscopic observations thus showed that planetary nebulae consisted largely of extremely rarefied ionised oxygen gas OIII During the 20th century observations showed that H II regions often contained hot bright stars 12 These stars are many times more massive than the Sun and are the shortest lived stars with total lifetimes of only a few million years compared to stars like the Sun which live for several billion years Therefore it was surmised that H II regions must be regions in which new stars were forming 12 Over a period of several million years a cluster of stars will form in an H II region before radiation pressure from the hot young stars causes the nebula to disperse 13 Origin and lifetime EditSee also Stellar evolution A small portion of the Tarantula Nebula a giant H II region in the Large Magellanic Cloud The precursor to an H II region is a giant molecular cloud GMC A GMC is a cold 10 20 K and dense cloud consisting mostly of molecular hydrogen 5 GMCs can exist in a stable state for long periods of time but shock waves due to supernovae collisions between clouds and magnetic interactions can trigger its collapse When this happens via a process of collapse and fragmentation of the cloud stars are born see stellar evolution for a lengthier description 13 As stars are born within a GMC the most massive will reach temperatures hot enough to ionise the surrounding gas 5 Soon after the formation of an ionising radiation field energetic photons create an ionisation front which sweeps through the surrounding gas at supersonic speeds At greater and greater distances from the ionising star the ionisation front slows while the pressure of the newly ionised gas causes the ionised volume to expand Eventually the ionisation front slows to subsonic speeds and is overtaken by the shock front caused by the expansion of the material ejected from the nebula The H II region has been born 14 The lifetime of an H II region is of the order of a few million years 15 Radiation pressure from the hot young stars will eventually drive most of the gas away In fact the whole process tends to be very inefficient with less than 10 percent of the gas in the H II region forming into stars before the rest is blown off 13 Contributing to the loss of gas are the supernova explosions of the most massive stars which will occur after only 1 2 million years Destruction of stellar nurseries Edit Bok globules in H II region IC 2944 Stars form in clumps of cool molecular gas that hide the nascent stars It is only when the radiation pressure from a star drives away its cocoon that it becomes visible The hot blue stars that are powerful enough to ionize significant amounts of hydrogen and form H II regions will do this quickly and light up the region in which they just formed The dense regions which contain younger or less massive still forming stars and which have not yet blown away the material from which they are forming are often seen in silhouette against the rest of the ionised nebula Bart Bok and E F Reilly searched astronomical photographs in the 1940s for relatively small dark nebulae following suggestions that stars might be formed from condensations in the interstellar medium they found several such approximately circular or oval dark objects of small size which they referred to as globules since referred to as Bok globules 16 Bok proposed at the December 1946 Harvard Observatory Centennial Symposia that these globules were likely sites of star formation 17 It was confirmed in 1990 that they were indeed stellar birthplaces 18 The hot young stars dissipate these globules as the radiation from the stars powering the H II region drives the material away In this sense the stars which generate H II regions act to destroy stellar nurseries In doing so however one last burst of star formation may be triggered as radiation pressure and mechanical pressure from supernova may act to squeeze globules thereby enhancing the density within them 19 The young stars in H II regions show evidence for containing planetary systems The Hubble Space Telescope has revealed hundreds of protoplanetary disks proplyds in the Orion Nebula 20 At least half the young stars in the Orion Nebula appear to be surrounded by disks of gas and dust 21 thought to contain many times as much matter as would be needed to create a planetary system like the Solar System Characteristics EditPhysical properties Edit Messier 17 is an H II region in the constellation Sagittarius H II regions vary greatly in their physical properties They range in size from so called ultra compact UCHII regions perhaps only a light year or less across to giant H II regions several hundred light years across 5 Their size is also known as the Stromgren radius and essentially depends on the intensity of the source of ionising photons and the density of the region Their densities range from over a million particles per cm3 in the ultra compact H II regions to only a few particles per cm3 in the largest and most extended regions This implies total masses between perhaps 100 and 105 solar masses 22 There are also ultra dense H II regions UDHII 23 Depending on the size of an H II region there may be several thousand stars within it This makes H II regions more complicated than planetary nebulae which have only one central ionising source Typically H II regions reach temperatures of 10 000 K 5 They are mostly ionised gases with weak magnetic fields with strengths of several nanoteslas 24 Nevertheless H II regions are almost always associated with a cold molecular gas which originated from the same parent GMC 5 Magnetic fields are produced by these weak moving electric charges in the ionised gas suggesting that H II regions might contain electric fields 25 Stellar nursery N159 is an HII region over 150 light years across 26 A number of H II regions also show signs of being permeated by a plasma with temperatures exceeding 10 000 000 K sufficiently hot to emit X rays X ray observatories such as Einstein and Chandra have noted diffuse X ray emissions in a number of star forming regions notably the Orion Nebula Messier 17 and the Carina Nebula 27 The hot gas is likely supplied by the strong stellar winds from O type stars which may be heated by supersonic shock waves in the winds through collisions between winds from different stars or through colliding winds channeled by magnetic fields This plasma will rapidly expand to fill available cavities in the molecular clouds due to the high speed of sound in the gas at this temperature It will also leak out through holes in the periphery of the H II region which appears to be happening in Messier 17 28 Chemically H II regions consist of about 90 hydrogen The strongest hydrogen emission line the H alpha line at 656 3 nm gives H II regions their characteristic red colour This emission line comes from excited un ionized hydrogen H beta is also emitted but at approximately 1 3 of the intensity of H alpha Most of the rest of an H II region consists of helium with trace amounts of heavier elements Across the galaxy it is found that the amount of heavy elements in H II regions decreases with increasing distance from the galactic centre 29 This is because over the lifetime of the galaxy star formation rates have been greater in the denser central regions resulting in greater enrichment of those regions of the interstellar medium with the products of nucleosynthesis Numbers and distribution Edit Strings of red H II regions delineate the arms of the Whirlpool Galaxy H II regions are found only in spiral galaxies like the Milky Way and irregular galaxies They are not seen in elliptical galaxies In irregular galaxies they may be dispersed throughout the galaxy but in spirals they are most abundant within the spiral arms A large spiral galaxy may contain thousands of H II regions 22 The reason H II regions rarely appear in elliptical galaxies is that ellipticals are believed to form through galaxy mergers 30 In galaxy clusters such mergers are frequent When galaxies collide individual stars almost never collide but the GMCs and H II regions in the colliding galaxies are severely agitated 30 Under these conditions enormous bursts of star formation are triggered so rapid that most of the gas is converted into stars rather than the normal rate of 10 or less Galaxies undergoing such rapid star formation are known as starburst galaxies The post merger elliptical galaxy has a very low gas content and so H II regions can no longer form 30 Twenty first century observations have shown that a very small number of H II regions exist outside galaxies altogether These intergalactic H II regions may be the remnants of tidal disruptions of small galaxies and in some cases may represent a new generation of stars in a galaxy s most recently accreted gas 31 Morphology Edit See also Stromgren sphere H II regions come in an enormous variety of sizes They are usually clumpy and inhomogeneous on all scales from the smallest to largest 5 Each star within an H II region ionises a roughly spherical region known as a Stromgren sphere of the surrounding gas but the combination of ionisation spheres of multiple stars within a H II region and the expansion of the heated nebula into surrounding gases creates sharp density gradients that result in complex shapes 32 Supernova explosions may also sculpt H II regions In some cases the formation of a large star cluster within an H II region results in the region being hollowed out from within This is the case for NGC 604 a giant H II region in the Triangulum Galaxy 33 For a H II region which cannot be resolved some information on the spatial structure the electron density as a function of the distance from the center and an estimate of the clumpiness can be inferred by performing an inverse Laplace transform on the frequency spectrum Notable regions Edit An optical image left reveals clouds of gas and dust in the Orion Nebula an infrared image right reveals new stars shining within Notable Galactic H II regions include the Orion Nebula the Eta Carinae Nebula and the Berkeley 59 Cepheus OB4 Complex 34 The Orion Nebula about 500 pc 1 500 light years from Earth is part of OMC 1 a giant molecular cloud that if visible would be seen to fill most of the constellation of Orion 12 The Horsehead Nebula and Barnard s Loop are two other illuminated parts of this cloud of gas 35 The Orion Nebula is actually a thin layer of ionised gas on the outer border of the OMC 1 cloud The stars in the Trapezium cluster and especially 81 Orionis are responsible for this ionisation 12 The Large Magellanic Cloud a satellite galaxy of the Milky Way at about 50 kpc 160 thousand light years contains a giant H II region called the Tarantula Nebula Measuring at about 200 pc 650 light years across this nebula is the most massive and the second largest H II region in the Local Group 36 It is much bigger than the Orion Nebula and is forming thousands of stars some with masses of over 100 times that of the sun OB and Wolf Rayet stars If the Tarantula Nebula were as close to Earth as the Orion Nebula it would shine about as brightly as the full moon in the night sky The supernova SN 1987A occurred in the outskirts of the Tarantula Nebula 32 Another giant H II region NGC 604 is located in M33 spiral galaxy which is at 817 kpc 2 66 million light years Measuring at approximately 240 250 pc 800 830 light years across NGC 604 is the second most massive H II region in the Local Group after the Tarantula Nebula although it is slightly larger in size than the latter It contains around 200 hot OB and Wolf Rayet stars which heat the gas inside it to millions of degrees producing bright X ray emissions The total mass of the hot gas in NGC 604 is about 6 000 Solar masses 33 Current issues Edit Trifid Nebula seen at different wavelengths As with planetary nebulae estimates of the abundance of elements in H II regions are subject to some uncertainty 37 There are two different ways of determining the abundance of metals metals in this case are elements other than hydrogen and helium in nebulae which rely on different types of spectral lines and large discrepancies are sometimes seen between the results derived from the two methods 36 Some astronomers put this down to the presence of small temperature fluctuations within H II regions others claim that the discrepancies are too large to be explained by temperature effects and hypothesise the existence of cold knots containing very little hydrogen to explain the observations 37 The full details of massive star formation within H II regions are not yet well known Two major problems hamper research in this area First the distance from Earth to large H II regions is considerable with the nearest H II California Nebula region at 300 pc 1 000 light years 38 other H II regions are several times that distance from Earth Secondly the formation of these stars is deeply obscured by dust and visible light observations are impossible Radio and infrared light can penetrate the dust but the youngest stars may not emit much light at these wavelengths 35 See also EditEmission nebula Reflection nebula Astronomical object H I region Planetary nebula Protoplanetary nebula Astronomical spectroscopy Interstellar mediumReferences Edit Ian Ridpath 2012 A Dictionary of Astronomy H II region 2nd 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2008ApJ 680 398L doi 10 1086 587503 S2CID 16924851 a b Tsamis Y G Barlow M J Liu X W et al 2003 Heavy elements in Galactic and Magellanic Cloud H II regions recombination line versus forbidden line abundances Monthly Notices of the Royal Astronomical Society 338 3 687 710 arXiv astro ph 0209534 Bibcode 2003MNRAS 338 687T doi 10 1046 j 1365 8711 2003 06081 x S2CID 18253949 Straizys V Cernis K Bartasiute S 2001 Interstellar extinction in the California Nebula region PDF Astronomy amp Astrophysics 374 1 288 293 Bibcode 2001A amp A 374 288S doi 10 1051 0004 6361 20010689 External links Edit Wikimedia Commons has media related to H II regions Hubble images of nebulae including several H II regions Information from SEDS Harvard astronomy course notes on H II regions Portals Astronomy Stars Spaceflight Outer space Solar System Retrieved from https en wikipedia org w index php title H II region amp oldid 1135258623, wikipedia, wiki, book, books, library,

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