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Herbig–Haro object

January 01, 1970

Herbig–Haro (HH) objects are bright patches of nebulosity associated with newborn stars. They are formed when narrow jets of partially ionised gas ejected by stars collide with nearby clouds of gas and dust at several hundred kilometres per second. Herbig–Haro objects are commonly found in star-forming regions, and several are often seen around a single star, aligned with its rotational axis. Most of them lie within about one parsec (3.26 light-years) of the source, although some have been observed several parsecs away. HH objects are transient phenomena that last around a few tens of thousands of years. They can change visibly over timescales of a few years as they move rapidly away from their parent star into the gas clouds of interstellar space (the interstellar medium or ISM). Hubble Space Telescope observations have revealed the complex evolution of HH objects over the period of a few years, as parts of the nebula fade while others brighten as they collide with the clumpy material of the interstellar medium.

Hubble Space Telescope images of HH 24 (left) and HH 32 (right; top) – colourful nebulae are typical of Herbig–Haro objects

First observed in the late 19th century by Sherburne Wesley Burnham, Herbig–Haro objects were recognised as a distinct type of emission nebula in the 1940s. The first astronomers to study them in detail were George Herbig and Guillermo Haro, after whom they have been named. Herbig and Haro were working independently on studies of star formation when they first analysed the objects, and recognised that they were a by-product of the star formation process. Although HH objects are visible-wavelength phenomena, many remain invisible at these wavelengths due to dust and gas, and can only be detected at infrared wavelengths. Such objects, when observed in near infrared, are called molecular hydrogen emission-line objects (MHOs).

Discovery and history of observations edit

The first HH object was observed in the late 19th century by Sherburne Wesley Burnham, when he observed the star T Tauri with the 36-inch (910 mm) refracting telescope at Lick Observatory and noted a small patch of nebulosity nearby.[1] It was thought to be an emission nebula, later becoming known as Burnham's Nebula, and was not recognized as a distinct class of object.[2] T Tauri was found to be a very young and variable star, and is the prototype of the class of similar objects known as T Tauri stars which have yet to reach a state of hydrostatic equilibrium between gravitational collapse and energy generation through nuclear fusion at their centres.[3] Fifty years after Burnham's discovery, several similar nebulae were discovered with almost star-like appearance. Both George Herbig and Guillermo Haro made independent observations of several of these objects in the Orion Nebula during the 1940s. Herbig also looked at Burnham's Nebula and found it displayed an unusual electromagnetic spectrum, with prominent emission lines of hydrogen, sulfur and oxygen. Haro found that all the objects of this type were invisible in infrared light.[2]

Following their independent discoveries, Herbig and Haro met at an astronomy conference in Tucson, Arizona in December 1949. Herbig had initially paid little attention to the objects he had discovered, being primarily concerned with the nearby stars, but on hearing Haro's findings he carried out more detailed studies of them. The Soviet astronomer Viktor Ambartsumian gave the objects their name (Herbig–Haro objects, normally shortened to HH objects), and based on their occurrence near young stars (a few hundred thousand years old), suggested they might represent an early stage in the formation of T Tauri stars.[2] Studies of the HH objects showed they were highly ionised, and early theorists speculated that they were reflection nebulae containing low-luminosity hot stars deep inside. But the absence of infrared radiation from the nebulae meant there could not be stars within them, as these would have emitted abundant infrared light. In 1975 American astronomer R. D. Schwartz theorized that winds from T Tauri stars produce shocks in the ambient medium on encounter, resulting in generation of visible light.[2] With the discovery of the first proto-stellar jet in HH 46/47, it became clear that HH objects are indeed shock-induced phenomena with shocks being driven by a collimated jet from protostars.[2][4]

An image of a question mark associated with the object was reported on 18 August 2023 in The New York Times.[5]

Formation edit

Main articles: Star formation and Astrophysical jet
 
 
HH objects are formed when accreted material is ejected by a protostar as ionized gas along the star's axis of rotation, as exemplified by HH 34 (right).

Stars form by gravitational collapse of interstellar gas clouds. As the collapse increases the density, radiative energy loss decreases due to increased opacity. This raises the temperature of the cloud which prevents further collapse, and a hydrostatic equilibrium is established. Gas continues to fall towards the core in a rotating disk. The core of this system is called a protostar.[6] Some of the accreting material is ejected out along the star's axis of rotation in two jets of partially ionised gas (plasma).[7] The mechanism for producing these collimated bipolar jets is not entirely understood, but it is believed that interaction between the accretion disk and the stellar magnetic field accelerates some of the accreting material from within a few astronomical units of the star away from the disk plane. At these distances the outflow is divergent, fanning out at an angle in the range of 10−30°, but it becomes increasingly collimated at distances of tens to hundreds of astronomical units from the source, as its expansion is constrained.[8][9] The jets also carry away the excess angular momentum resulting from accretion of material onto the star, which would otherwise cause the star to rotate too rapidly and disintegrate.[9] When these jets collide with the interstellar medium, they give rise to the small patches of bright emission which comprise HH objects.[10]

Properties edit

 
Infrared spectrum of HH 46/47 obtained by the Spitzer Space Telescope, showing the medium in immediate vicinity of the star being silicate-rich

Electromagnetic emission from HH objects is caused when their associated shock waves collide with the interstellar medium, creating what is called the "terminal working surfaces".[11] The spectrum is continuous, but also has intense emission lines of neutral and ionized species.[7] Spectroscopic observations of HH objects' doppler shifts indicate velocities of several hundred kilometers per second, but the emission lines in those spectra are weaker than what would be expected from such high-speed collisions. This suggests that some of the material they are colliding with is also moving along the beam, although at a lower speed.[12][13] Spectroscopic observations of HH objects show they are moving away from the source stars at speeds of several hundred kilometres per second.[2][14] In recent years, the high optical resolution of the Hubble Space Telescope has revealed the proper motion (movement along the sky plane) of many HH objects in observations spaced several years apart.[15][16] As they move away from the parent star, HH objects evolve significantly, varying in brightness on timescales of a few years. Individual compact knots or clumps within an object may brighten and fade or disappear entirely, while new knots have been seen to appear.[9][11] These arise likely because of the precession of their jets,[17][18] along with the pulsating and intermittent eruptions from their parent stars.[10] Faster jets catch up with earlier slower jets, creating the so-called "internal working surfaces", where streams of gas collide and generate shock waves and consequent emissions.[19]

The total mass being ejected by stars to form typical HH objects is estimated to be of the order of 10−8 to 10−6 M per year,[17] a very small amount of material compared to the mass of the stars themselves[20] but amounting to about 1–10% of the total mass accreted by the source stars in a year.[21] Mass loss tends to decrease with increasing age of the source.[22] The temperatures observed in HH objects are typically about 9,000–12,000 K,[23] similar to those found in other ionized nebulae such as H II regions and planetary nebulae.[24] Densities, on the other hand, are higher than in other nebulae, ranging from a few thousand to a few tens of thousands of particles per cm3,[23] compared to a few thousand particles per cm3 in most H II regions and planetary nebulae.[24]

Densities also decrease as the source evolves over time.[22] HH objects consist mostly of hydrogen and helium, which account for about 75% and 24% of their mass respectively. Around 1% of the mass of HH objects is made up of heavier chemical elements, including oxygen, sulfur, nitrogen, iron, calcium and magnesium. Abundances of these elements, determined from emission lines of respective ions, are generally similar to their cosmic abundances.[20] Many chemical compounds found in the surrounding interstellar medium, but not present in the source material, such as metal hydrides, are believed to have been produced by shock-induced chemical reactions.[8] Around 20–30% of the gas in HH objects is ionized near the source star, but this proportion decreases at increasing distances. This implies the material is ionized in the polar jet, and recombines as it moves away from the star, rather than being ionized by later collisions.[23] Shocking at the end of the jet can re-ionise some material, giving rise to bright "caps".[7]

Numbers and distribution edit

 
HH 2 (lower right), HH 34 (lower left), and HH 47 (top) were numbered in order of their discovery; it is estimated that there are up to 150,000 such objects in the Milky Way.

HH objects are named approximately in order of their identification; HH 1/2 being the earliest such objects to be identified.[25] More than a thousand individual objects are now known.[8] They are always present in star-forming H II regions, and are often found in large groups.[10] They are typically observed near Bok globules (dark nebulae which contain very young stars) and often emanate from them. Several HH objects have been seen near a single energy source, forming a string of objects along the line of the polar axis of the parent star.[8] The number of known HH objects has increased rapidly over the last few years, but that is a very small proportion of the estimated up to 150,000 in the Milky Way,[26] the vast majority of which are too far away to be resolved. Most HH objects lie within about one parsec of their parent star. Many, however, are seen several parsecs away.[22][23]

HH 46/47 is located about 450 parsecs (1,500 light-years) away from the Sun and is powered by a class I protostar binary. The bipolar jet is slamming into the surrounding medium at a velocity of 300 kilometers per second, producing two emission caps about 2.6 parsecs (8.5 light-years) apart. Jet outflow is accompanied by a 0.3 parsecs (0.98 light-years) long molecular gas outflow which is swept up by the jet itself.[8] Infrared studies by Spitzer Space Telescope have revealed a variety of chemical compounds in the molecular outflow, including water (ice), methanol, methane, carbon dioxide (dry ice) and various silicates.[8][27] Located around 460 parsecs (1,500 light-years) away in the Orion A molecular cloud, HH 34 is produced by a highly collimated bipolar jet powered by a class I protostar. Matter in the jet is moving at about 220 kilometers per second. Two bright bow shocks, separated by about 0.44 parsecs (1.4 light-years), are present on the opposite sides of the source, followed by series of fainter ones at larger distances, making the whole complex about 3 parsecs (9.8 light-years) long. The jet is surrounded by a 0.3 parsecs (0.98 light-years) long weak molecular outflow near the source.[8][28]

Source stars edit

Thirteen-year timelapse of material ejecting from a class I protostar, forming the Herbig–Haro object HH 34

The stars from which HH jets are emitted are all very young stars, a few tens of thousands to about a million years old. The youngest of these are still protostars in the process of collecting from their surrounding gases. Astronomers divide these stars into classes 0, I, II and III, according to how much infrared radiation the stars emit.[29] A greater amount of infrared radiation implies a larger amount of cooler material surrounding the star, which indicates it is still coalescing. The numbering of the classes arises because class 0 objects (the youngest) were not discovered until classes I, II and III had already been defined.[30][29]

Class 0 objects are only a few thousand years old; so young that they are not yet undergoing nuclear fusion reactions at their centres. Instead, they are powered only by the gravitational potential energy released as material falls onto them.[31] They mostly contain molecular outflows with low velocities (less than a hundred kilometres per second) and weak emissions in the outflows.[18] Nuclear fusion has begun in the cores of Class I objects, but gas and dust are still falling onto their surfaces from the surrounding nebula, and most of their luminosity is accounted for by gravitational energy. They are generally still shrouded in dense clouds of dust and gas, which obscure all their visible light and as a result can only be observed at infrared and radio wavelengths.[32] Outflows from this class are dominated by ionized species and velocities can range up to 400 kilometres per second.[18] The in-fall of gas and dust has largely finished in Class II objects (Classical T Tauri stars), but they are still surrounded by disks of dust and gas, and produce weak outflows of low luminosity.[18] Class III objects (Weak-line T Tauri stars) have only trace remnants of their original accretion disk.[29]

About 80% of the stars giving rise to HH objects are binary or multiple systems (two or more stars orbiting each other), which is a much higher proportion than that found for low mass stars on the main sequence. This may indicate that binary systems are more likely to generate the jets which give rise to HH objects, and evidence suggests the largest HH outflows might be formed when multiple–star systems disintegrate.[33] It is thought that most stars originate from multiple star systems, but that a sizable fraction of these systems are disrupted before their stars reach the main sequence due to gravitational interactions with nearby stars and dense clouds of gas.[33][34]

The first and currently only (as of May 2017) large-scale Herbig-Haro object around a proto-brown dwarf is HH 1165, which is connected to the proto-brown dwarf Mayrit 1701117. HH 1165 has a length of 0.8 light-years (0.26 parsec) and is located in the vicinity of the sigma Orionis cluster. Previously only small mini-jets (≤0.03 parsec) were found around proto-brown dwarfs.[35][36]

Infrared counterparts edit

 
HH 49/50 seen in infrared by the Spitzer Space Telescope

HH objects associated with very young stars or very massive protostars are often hidden from view at optical wavelengths by the cloud of gas and dust from which they form. The intervening material can diminish the visual magnitude by factors of tens or even hundreds at optical wavelengths. Such deeply embedded objects can only be observed at infrared or radio wavelengths,[37] usually in the frequencies of hot molecular hydrogen or warm carbon monoxide emission.[38] In recent years, infrared images have revealed dozens of examples of "infrared HH objects". Most look like bow waves (similar to the waves at the head of a ship), and so are usually referred to as molecular "bow shocks". The physics of infrared bow shocks can be understood in much the same way as that of HH objects, since these objects are essentially the same – supersonic shocks driven by collimated jets from the opposite poles of a protostar.[39] It is only the conditions in the jet and surrounding cloud that are different, causing infrared emission from molecules rather than optical emission from atoms and ions.[40]

In 2009 the acronym "MHO", for Molecular Hydrogen emission-line Object, was approved for such objects, detected in near infrared, by the International Astronomical Union Working Group on Designations, and has been entered into their on-line Reference Dictionary of Nomenclature of Celestial Objects. As of 2010, almost 1000 objects are contained in the MHO catalog.[39]

Ultraviolet Herbig-Haro objects edit

HH objects have been observed in the ultraviolet spectrum.[41]

See also edit

References edit

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  2. ^ a b c d e f Reipurth, B.; Bertout, C., eds. (1997). "50 Years of Herbig–Haro Research. From discovery to HST". Herbig–Haro Flows and the Birth of Stars. IAU Symposium No. 182. Dordrecht: Kluwer Academic Publishers. pp. 3–18. Bibcode:1997IAUS..182....3R.
  3. ^ Carroll, Bradley W.; Ostlie, Dale A. (2014). An Introduction to Modern Astrophysics. Harlow: Pearson Education Limited. p. 478. ISBN 978-1-292-02293-2.
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  5. ^ Overbye, Dennis (18 August 2023). "The Biggest Question Mark in Astronomy? You're Looking at It. - Close scrutiny of a recent image from the Webb Space Telescope revealed some questionable punctuation". The New York Times. Archived from the original on 18 August 2023. Retrieved 19 August 2023.
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  24. ^ a b Dyson, J. E.; Franco, J. (2001). "H II Regions". In Murdin, Paul (ed.). Encyclopedia of Astronomy and Astrophysics (First ed.). Hampshire: Nature Publishing Group. pp. 1594–1599. ISBN 978-0333786536.
  25. ^ Herbig, G. H. (1974). "Draft Catalog of Herbig–Haro Objects". Lick Observatory Bulletin. 658 (658): 1–11. Bibcode:1974LicOB.658....1H.
  26. ^ Giulbudagian, A. L. (September 1984). "On a connection between Herbig–Haro objects and flare stars in the neighborhood of the sun". Astrophysics. 20 (2): 147–149. Bibcode:1984Afz....20..277G. doi:10.1007/BF01005825. S2CID 121039271.
  27. ^ "Embedded Outflow in HH 46/47". NASA Spitzer Space Telescope. Jet Propulsion Laboratory, California Institute of Technology. December 18, 2003. from the original on February 17, 2018. Retrieved February 16, 2018.
  28. ^ Reipurth, B.; Heathcote, S.; Morse, J.; et al. (January 2002). "Hubble Space Telescope Images of the HH 34 Jet and Bow Shock: Structure and Proper Motions". Astronomical Journal. 123 (1): 362–381. Bibcode:2002AJ....123..362R. doi:10.1086/324738.
  29. ^ a b c McKee, C. F.; Ostriker, E. C. (September 2007). "Theory of Star Formation". Annual Review of Astronomy and Astrophysics. 45 (1): 565–687. arXiv:0707.3514. Bibcode:2007ARA&A..45..565M. doi:10.1146/annurev.astro.45.051806.110602. S2CID 119714125.
  30. ^ Andre, P.; Montmerle, T. (January 1994). "From T Tauri stars to protostars: Circumstellar material and young stellar objects in the rho Ophiuchi cloud". Astrophysical Journal. 420 (2): 837–862. Bibcode:1994ApJ...420..837A. doi:10.1086/173608.
  31. ^ Andre, P.; Ward-Thompson, D.; Barsony, M. (March 1993). "Submillimeter continuum observations of Rho Ophiuchi A: The candidate protostar VLA 1623 and prestellar clumps". Astrophysical Journal. 406 (1): 122–141. Bibcode:1993ApJ...406..122A. doi:10.1086/172425.
  32. ^ Stahler, S. W.; Palla, F. (2004). The Formation of Stars. Weinheim: WILEY-VCH Verlag. p. 321. ISBN 9783527405596.
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  35. ^ "Punching Above Its Weight, a Brown Dwarf Launches a Parsec-Scale Jet". National Optical Astronomy Observatory. Retrieved 2020-03-06.
  36. ^ Riaz, B.; Briceño, C.; Whelan, E. T.; Heathcote, S. (July 2017). "First Large-scale Herbig-Haro Jet Driven by a Proto-brown Dwarf". The Astrophysical Journal. 844 (1): 47. arXiv:1705.01170. Bibcode:2017ApJ...844...47R. doi:10.3847/1538-4357/aa70e8. ISSN 0004-637X. S2CID 119080074.
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  38. ^ Giannini, T.; McCoey, C.; Nisini, B.; et al. (December 2006). "Molecular line emission in HH54: a coherent view from near to far infrared". Astronomy and Astrophysics. 459 (3): 821–835. arXiv:astro-ph/0607375. Bibcode:2006A&A...459..821G. doi:10.1051/0004-6361:20065127. S2CID 8799418.
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External links edit

 
Wikimedia Commons has media related to Herbig–Haro objects.
  • Catalogue of HH Objects at VizieR
  • Animations of HH object jets from HST observations
  • A Catalogue of Molecular Hydrogen Emission-Line Objects in Outflows from Young Stars: MHO Catalogue

January 01, 1970
herbig, haro, object, herbig, haro, objects, bright, patches, nebulosity, associated, with, newborn, stars, they, formed, when, narrow, jets, partially, ionised, ejected, stars, collide, with, nearby, clouds, dust, several, hundred, kilometres, second, commonl. Herbig Haro HH objects are bright patches of nebulosity associated with newborn stars They are formed when narrow jets of partially ionised gas ejected by stars collide with nearby clouds of gas and dust at several hundred kilometres per second Herbig Haro objects are commonly found in star forming regions and several are often seen around a single star aligned with its rotational axis Most of them lie within about one parsec 3 26 light years of the source although some have been observed several parsecs away HH objects are transient phenomena that last around a few tens of thousands of years They can change visibly over timescales of a few years as they move rapidly away from their parent star into the gas clouds of interstellar space the interstellar medium or ISM Hubble Space Telescope observations have revealed the complex evolution of HH objects over the period of a few years as parts of the nebula fade while others brighten as they collide with the clumpy material of the interstellar medium Hubble Space Telescope images of HH 24 left and HH 32 right top colourful nebulae are typical of Herbig Haro objects First observed in the late 19th century by Sherburne Wesley Burnham Herbig Haro objects were recognised as a distinct type of emission nebula in the 1940s The first astronomers to study them in detail were George Herbig and Guillermo Haro after whom they have been named Herbig and Haro were working independently on studies of star formation when they first analysed the objects and recognised that they were a by product of the star formation process Although HH objects are visible wavelength phenomena many remain invisible at these wavelengths due to dust and gas and can only be detected at infrared wavelengths Such objects when observed in near infrared are called molecular hydrogen emission line objects MHOs Contents 1 Discovery and history of observations 2 Formation 3 Properties 4 Numbers and distribution 5 Source stars 6 Infrared counterparts 7 Ultraviolet Herbig Haro objects 8 See also 9 References 10 External linksDiscovery and history of observations editThe first HH object was observed in the late 19th century by Sherburne Wesley Burnham when he observed the star T Tauri with the 36 inch 910 mm refracting telescope at Lick Observatory and noted a small patch of nebulosity nearby 1 It was thought to be an emission nebula later becoming known as Burnham s Nebula and was not recognized as a distinct class of object 2 T Tauri was found to be a very young and variable star and is the prototype of the class of similar objects known as T Tauri stars which have yet to reach a state of hydrostatic equilibrium between gravitational collapse and energy generation through nuclear fusion at their centres 3 Fifty years after Burnham s discovery several similar nebulae were discovered with almost star like appearance Both George Herbig and Guillermo Haro made independent observations of several of these objects in the Orion Nebula during the 1940s Herbig also looked at Burnham s Nebula and found it displayed an unusual electromagnetic spectrum with prominent emission lines of hydrogen sulfur and oxygen Haro found that all the objects of this type were invisible in infrared light 2 Following their independent discoveries Herbig and Haro met at an astronomy conference in Tucson Arizona in December 1949 Herbig had initially paid little attention to the objects he had discovered being primarily concerned with the nearby stars but on hearing Haro s findings he carried out more detailed studies of them The Soviet astronomer Viktor Ambartsumian gave the objects their name Herbig Haro objects normally shortened to HH objects and based on their occurrence near young stars a few hundred thousand years old suggested they might represent an early stage in the formation of T Tauri stars 2 Studies of the HH objects showed they were highly ionised and early theorists speculated that they were reflection nebulae containing low luminosity hot stars deep inside But the absence of infrared radiation from the nebulae meant there could not be stars within them as these would have emitted abundant infrared light In 1975 American astronomer R D Schwartz theorized that winds from T Tauri stars produce shocks in the ambient medium on encounter resulting in generation of visible light 2 With the discovery of the first proto stellar jet in HH 46 47 it became clear that HH objects are indeed shock induced phenomena with shocks being driven by a collimated jet from protostars 2 4 An image of a question mark associated with the object was reported on 18 August 2023 in The New York Times 5 Formation editMain articles Star formation and Astrophysical jet nbsp nbsp HH objects are formed when accreted material is ejected by a protostar as ionized gas along the star s axis of rotation as exemplified by HH 34 right Stars form by gravitational collapse of interstellar gas clouds As the collapse increases the density radiative energy loss decreases due to increased opacity This raises the temperature of the cloud which prevents further collapse and a hydrostatic equilibrium is established Gas continues to fall towards the core in a rotating disk The core of this system is called a protostar 6 Some of the accreting material is ejected out along the star s axis of rotation in two jets of partially ionised gas plasma 7 The mechanism for producing these collimated bipolar jets is not entirely understood but it is believed that interaction between the accretion disk and the stellar magnetic field accelerates some of the accreting material from within a few astronomical units of the star away from the disk plane At these distances the outflow is divergent fanning out at an angle in the range of 10 30 but it becomes increasingly collimated at distances of tens to hundreds of astronomical units from the source as its expansion is constrained 8 9 The jets also carry away the excess angular momentum resulting from accretion of material onto the star which would otherwise cause the star to rotate too rapidly and disintegrate 9 When these jets collide with the interstellar medium they give rise to the small patches of bright emission which comprise HH objects 10 Properties edit nbsp Infrared spectrum of HH 46 47 obtained by the Spitzer Space Telescope showing the medium in immediate vicinity of the star being silicate rich Electromagnetic emission from HH objects is caused when their associated shock waves collide with the interstellar medium creating what is called the terminal working surfaces 11 The spectrum is continuous but also has intense emission lines of neutral and ionized species 7 Spectroscopic observations of HH objects doppler shifts indicate velocities of several hundred kilometers per second but the emission lines in those spectra are weaker than what would be expected from such high speed collisions This suggests that some of the material they are colliding with is also moving along the beam although at a lower speed 12 13 Spectroscopic observations of HH objects show they are moving away from the source stars at speeds of several hundred kilometres per second 2 14 In recent years the high optical resolution of the Hubble Space Telescope has revealed the proper motion movement along the sky plane of many HH objects in observations spaced several years apart 15 16 As they move away from the parent star HH objects evolve significantly varying in brightness on timescales of a few years Individual compact knots or clumps within an object may brighten and fade or disappear entirely while new knots have been seen to appear 9 11 These arise likely because of the precession of their jets 17 18 along with the pulsating and intermittent eruptions from their parent stars 10 Faster jets catch up with earlier slower jets creating the so called internal working surfaces where streams of gas collide and generate shock waves and consequent emissions 19 The total mass being ejected by stars to form typical HH objects is estimated to be of the order of 10 8 to 10 6 M per year 17 a very small amount of material compared to the mass of the stars themselves 20 but amounting to about 1 10 of the total mass accreted by the source stars in a year 21 Mass loss tends to decrease with increasing age of the source 22 The temperatures observed in HH objects are typically about 9 000 12 000 K 23 similar to those found in other ionized nebulae such as H II regions and planetary nebulae 24 Densities on the other hand are higher than in other nebulae ranging from a few thousand to a few tens of thousands of particles per cm3 23 compared to a few thousand particles per cm3 in most H II regions and planetary nebulae 24 Densities also decrease as the source evolves over time 22 HH objects consist mostly of hydrogen and helium which account for about 75 and 24 of their mass respectively Around 1 of the mass of HH objects is made up of heavier chemical elements including oxygen sulfur nitrogen iron calcium and magnesium Abundances of these elements determined from emission lines of respective ions are generally similar to their cosmic abundances 20 Many chemical compounds found in the surrounding interstellar medium but not present in the source material such as metal hydrides are believed to have been produced by shock induced chemical reactions 8 Around 20 30 of the gas in HH objects is ionized near the source star but this proportion decreases at increasing distances This implies the material is ionized in the polar jet and recombines as it moves away from the star rather than being ionized by later collisions 23 Shocking at the end of the jet can re ionise some material giving rise to bright caps 7 Numbers and distribution edit nbsp HH 2 lower right HH 34 lower left and HH 47 top were numbered in order of their discovery it is estimated that there are up to 150 000 such objects in the Milky Way HH objects are named approximately in order of their identification HH 1 2 being the earliest such objects to be identified 25 More than a thousand individual objects are now known 8 They are always present in star forming H II regions and are often found in large groups 10 They are typically observed near Bok globules dark nebulae which contain very young stars and often emanate from them Several HH objects have been seen near a single energy source forming a string of objects along the line of the polar axis of the parent star 8 The number of known HH objects has increased rapidly over the last few years but that is a very small proportion of the estimated up to 150 000 in the Milky Way 26 the vast majority of which are too far away to be resolved Most HH objects lie within about one parsec of their parent star Many however are seen several parsecs away 22 23 HH 46 47 is located about 450 parsecs 1 500 light years away from the Sun and is powered by a class I protostar binary The bipolar jet is slamming into the surrounding medium at a velocity of 300 kilometers per second producing two emission caps about 2 6 parsecs 8 5 light years apart Jet outflow is accompanied by a 0 3 parsecs 0 98 light years long molecular gas outflow which is swept up by the jet itself 8 Infrared studies by Spitzer Space Telescope have revealed a variety of chemical compounds in the molecular outflow including water ice methanol methane carbon dioxide dry ice and various silicates 8 27 Located around 460 parsecs 1 500 light years away in the Orion A molecular cloud HH 34 is produced by a highly collimated bipolar jet powered by a class I protostar Matter in the jet is moving at about 220 kilometers per second Two bright bow shocks separated by about 0 44 parsecs 1 4 light years are present on the opposite sides of the source followed by series of fainter ones at larger distances making the whole complex about 3 parsecs 9 8 light years long The jet is surrounded by a 0 3 parsecs 0 98 light years long weak molecular outflow near the source 8 28 Source stars edit source source source source source source source Thirteen year timelapse of material ejecting from a class I protostar forming the Herbig Haro object HH 34 The stars from which HH jets are emitted are all very young stars a few tens of thousands to about a million years old The youngest of these are still protostars in the process of collecting from their surrounding gases Astronomers divide these stars into classes 0 I II and III according to how much infrared radiation the stars emit 29 A greater amount of infrared radiation implies a larger amount of cooler material surrounding the star which indicates it is still coalescing The numbering of the classes arises because class 0 objects the youngest were not discovered until classes I II and III had already been defined 30 29 Class 0 objects are only a few thousand years old so young that they are not yet undergoing nuclear fusion reactions at their centres Instead they are powered only by the gravitational potential energy released as material falls onto them 31 They mostly contain molecular outflows with low velocities less than a hundred kilometres per second and weak emissions in the outflows 18 Nuclear fusion has begun in the cores of Class I objects but gas and dust are still falling onto their surfaces from the surrounding nebula and most of their luminosity is accounted for by gravitational energy They are generally still shrouded in dense clouds of dust and gas which obscure all their visible light and as a result can only be observed at infrared and radio wavelengths 32 Outflows from this class are dominated by ionized species and velocities can range up to 400 kilometres per second 18 The in fall of gas and dust has largely finished in Class II objects Classical T Tauri stars but they are still surrounded by disks of dust and gas and produce weak outflows of low luminosity 18 Class III objects Weak line T Tauri stars have only trace remnants of their original accretion disk 29 About 80 of the stars giving rise to HH objects are binary or multiple systems two or more stars orbiting each other which is a much higher proportion than that found for low mass stars on the main sequence This may indicate that binary systems are more likely to generate the jets which give rise to HH objects and evidence suggests the largest HH outflows might be formed when multiple star systems disintegrate 33 It is thought that most stars originate from multiple star systems but that a sizable fraction of these systems are disrupted before their stars reach the main sequence due to gravitational interactions with nearby stars and dense clouds of gas 33 34 The first and currently only as of May 2017 large scale Herbig Haro object around a proto brown dwarf is HH 1165 which is connected to the proto brown dwarf Mayrit 1701117 HH 1165 has a length of 0 8 light years 0 26 parsec and is located in the vicinity of the sigma Orionis cluster Previously only small mini jets 0 03 parsec were found around proto brown dwarfs 35 36 Infrared counterparts edit nbsp HH 49 50 seen in infrared by the Spitzer Space Telescope HH objects associated with very young stars or very massive protostars are often hidden from view at optical wavelengths by the cloud of gas and dust from which they form The intervening material can diminish the visual magnitude by factors of tens or even hundreds at optical wavelengths Such deeply embedded objects can only be observed at infrared or radio wavelengths 37 usually in the frequencies of hot molecular hydrogen or warm carbon monoxide emission 38 In recent years infrared images have revealed dozens of examples of infrared HH objects Most look like bow waves similar to the waves at the head of a ship and so are usually referred to as molecular bow shocks The physics of infrared bow shocks can be understood in much the same way as that of HH objects since these objects are essentially the same supersonic shocks driven by collimated jets from the opposite poles of a protostar 39 It is only the conditions in the jet and surrounding cloud that are different causing infrared emission from molecules rather than optical emission from atoms and ions 40 In 2009 the acronym MHO for Molecular Hydrogen emission line Object was approved for such objects detected in near infrared by the International Astronomical Union Working Group on Designations and has been entered into their on line Reference Dictionary of Nomenclature of Celestial Objects As of 2010 almost 1000 objects are contained in the MHO catalog 39 Ultraviolet Herbig Haro objects editHH objects have been observed in the ultraviolet spectrum 41 See also editBipolar outflow Protostar Protoplanetary diskReferences edit Burnham S W 1890 Note on Hind s Variable Nebula in Taurus Monthly Notices of the Royal Astronomical Society 51 2 94 95 Bibcode 1890MNRAS 51 94B doi 10 1093 mnras 51 2 94 a b c d e f Reipurth B Bertout C eds 1997 50 Years of Herbig Haro Research From discovery to HST Herbig Haro Flows and the Birth of Stars IAU Symposium No 182 Dordrecht Kluwer Academic Publishers pp 3 18 Bibcode 1997IAUS 182 3R Carroll Bradley W Ostlie Dale A 2014 An Introduction to Modern Astrophysics Harlow Pearson Education Limited p 478 ISBN 978 1 292 02293 2 Dopita M A Schwartz R D Evans I December 1982 Herbig Haro Objects 46 and 47 Evidence for bipolar ejection from a young star Astrophysical Journal Letters 263 L73 L77 Bibcode 1982ApJ 263L 73D doi 10 1086 183927 Overbye Dennis 18 August 2023 The Biggest Question Mark in Astronomy You re Looking at It Close scrutiny of a recent image from the Webb Space Telescope revealed some questionable punctuation The New York Times Archived from the original on 18 August 2023 Retrieved 19 August 2023 Prialnik D 2000 An Introduction to the Theory of Stellar Structure and Evolution Cambridge United Kingdom Cambridge University Press pp 198 199 ISBN 978 0 521 65937 6 a b c Raga A C 2001 Herbig Haro Objects and Exciting Stars In Murdin Paul ed Encyclopedia of Astronomy and Astrophysics First ed Hampshire Nature Publishing Group pp 1654 1657 ISBN 978 0333786536 a b c d e f g Bally J September 2016 Protostellar Outflows Annual Review of Astronomy and Astrophysics 54 491 528 Bibcode 2016ARA amp A 54 491B doi 10 1146 annurev astro 081915 023341 a b c Frank A Ray T P Cabrit S et al 2014 Jets and Outflows from Star to Cloud Observations Confront Theory In Beuther S Klessen R S Dullemond C P Henning T eds Protostars and Planets VI Tucson University of Arizona Press pp 451 474 arXiv 1402 3553 Bibcode 2014prpl conf 451F doi 10 2458 azu uapress 9780816531240 ch020 ISBN 9780816531240 S2CID 118539135 a b c P Benvenuti F D Macchetto E J Schreier eds 1996 The Birth of Stars Herbig Haro Jets Accretion and Proto Planetary Disks Science with the Hubble Space Telescope II Baltimore Space Telescope Science Institute Bibcode 1996swhs conf 491B HTML version a b Reipurth B Bally J 2001 Herbig Haro Flows Probes of Early Stellar Evolution Annual Review of Astronomy and Astrophysics 39 1 2 403 455 Bibcode 2001ARA amp A 39 403R doi 10 1146 annurev astro 39 1 403 Dopita M February 1978 The Herbig Haro objects in the GUM Nebula Astronomy and Astrophysics 63 1 2 237 241 Bibcode 1978A amp A 63 237D Schwartz R D 1983 Herbig Haro Objects Annual Review of Astronomy and Astrophysics 21 209 237 Bibcode 1983ARA amp A 21 209S doi 10 1146 annurev aa 21 090183 001233 Heathcote S Reipurth B Raga A C July 1998 Structure Excitation and Kinematics of the Luminous Herbig Haro Objects 80 81 Astronomical Journal 116 4 1940 1960 Bibcode 1998AJ 116 1940H doi 10 1086 300548 Hartigan P Morse J Reipurth B et al September 2001 Proper Motions of the HH 111 Jet Observed with the Hubble Space Telescope Astrophysical Journal Letters 559 2 L157 L161 Bibcode 2001ApJ 559L 157H doi 10 1086 323976 Raga A Reipurth B Velazquez P et al December 2016 The time evolution of HH 2 from four epochs of HST images Astronomical Journal 152 6 186 arXiv 1610 01951 Bibcode 2016AJ 152 186R doi 10 3847 0004 6256 152 6 186 S2CID 58923690 186 a b Zealey W J 1992 Young Stellar Objects and Herbig Haro Objects Australian Journal of Physics 45 4 487 499 Bibcode 1992AuJPh 45 487Z doi 10 1071 PH920487 a b c d Bally J October 2007 Jets from young stars Astrophysics and Space Science 311 1 3 15 24 Bibcode 2007Ap amp SS 311 15B doi 10 1007 s10509 007 9531 7 S2CID 55887210 Raga A Canto J October 2017 The formation of double working surfaces in periodically variable jets Revista Mexicana de Astronomia y Astrofisica 53 2 219 225 Bibcode 2017RMxAA 53 219R a b Brugel E W Boehm K H Mannery E 1981 Emission line spectra of Herbig Haro objects Astrophysical Journal Supplement Series 47 117 138 Bibcode 1981ApJS 47 117B doi 10 1086 190754 Hartigan P Morse J A Raymond J November 1994 Mass loss rates ionization fractions shock velocities and magnetic fields of stellar jets Astrophysical Journal 436 1 125 143 Bibcode 1994ApJ 436 125H doi 10 1086 174887 a b c Bally J Reipurth B Davis C J 2007 Observations of Jets and Outflows from Young Stars PDF In Reipurth B Jewitt D Keil K eds Protostars and Planets V Tucson University of Arizona Press pp 215 230 Bibcode 2007prpl conf 215B a b c d Bacciotti F Eisloffel J February 1999 Ionization and density along the beams of Herbig Haro jets Astronomy and Astrophysics 342 717 735 Bibcode 1999A amp A 342 717B a b Dyson J E Franco J 2001 H II Regions In Murdin Paul ed Encyclopedia of Astronomy and Astrophysics First ed Hampshire Nature Publishing Group pp 1594 1599 ISBN 978 0333786536 Herbig G H 1974 Draft Catalog of Herbig Haro Objects Lick Observatory Bulletin 658 658 1 11 Bibcode 1974LicOB 658 1H Giulbudagian A L September 1984 On a connection between Herbig Haro objects and flare stars in the neighborhood of the sun Astrophysics 20 2 147 149 Bibcode 1984Afz 20 277G doi 10 1007 BF01005825 S2CID 121039271 Embedded Outflow in HH 46 47 NASA Spitzer Space Telescope Jet Propulsion Laboratory California Institute of Technology December 18 2003 Archived from the original on February 17 2018 Retrieved February 16 2018 Reipurth B Heathcote S Morse J et al January 2002 Hubble Space Telescope Images of the HH 34 Jet and Bow Shock Structure and Proper Motions Astronomical Journal 123 1 362 381 Bibcode 2002AJ 123 362R doi 10 1086 324738 a b c McKee C F Ostriker E C September 2007 Theory of Star Formation Annual Review of Astronomy and Astrophysics 45 1 565 687 arXiv 0707 3514 Bibcode 2007ARA amp A 45 565M doi 10 1146 annurev astro 45 051806 110602 S2CID 119714125 Andre P Montmerle T January 1994 From T Tauri stars to protostars Circumstellar material and young stellar objects in the rho Ophiuchi cloud Astrophysical Journal 420 2 837 862 Bibcode 1994ApJ 420 837A doi 10 1086 173608 Andre P Ward Thompson D Barsony M March 1993 Submillimeter continuum observations of Rho Ophiuchi A The candidate protostar VLA 1623 and prestellar clumps Astrophysical Journal 406 1 122 141 Bibcode 1993ApJ 406 122A doi 10 1086 172425 Stahler S W Palla F 2004 The Formation of Stars Weinheim WILEY VCH Verlag p 321 ISBN 9783527405596 a b Reipurth B December 2000 Disintegrating Multiple Systems in Early Stellar Evolution Astronomical Journal 120 6 3177 3191 Bibcode 2000AJ 120 3177R doi 10 1086 316865 Reipurth B Rodrguez L F Anglada G et al March 2004 Radio Continuum Jets from Protostellar Objects Astronomical Journal 127 3 1736 1746 Bibcode 2004AJ 127 1736R doi 10 1086 381062 Punching Above Its Weight a Brown Dwarf Launches a Parsec Scale Jet National Optical Astronomy Observatory Retrieved 2020 03 06 Riaz B Briceno C Whelan E T Heathcote S July 2017 First Large scale Herbig Haro Jet Driven by a Proto brown Dwarf The Astrophysical Journal 844 1 47 arXiv 1705 01170 Bibcode 2017ApJ 844 47R doi 10 3847 1538 4357 aa70e8 ISSN 0004 637X S2CID 119080074 Davis C J Eisloeffel J August 1995 Near infrared imaging in H2 of molecular CO outflows from young stars Astronomy and Astrophysics 300 851 869 Bibcode 1995A amp A 300 851D Giannini T McCoey C Nisini B et al December 2006 Molecular line emission in HH54 a coherent view from near to far infrared Astronomy and Astrophysics 459 3 821 835 arXiv astro ph 0607375 Bibcode 2006A amp A 459 821G doi 10 1051 0004 6361 20065127 S2CID 8799418 a b Davis C J Gell R Khanzadyan T et al February 2010 A general catalogue of molecular hydrogen emission line objects MHOs in outflows from young stars Astronomy and Astrophysics 511 A24 arXiv 0910 5274 Bibcode 2010A amp A 511A 24D doi 10 1051 0004 6361 200913561 S2CID 119306625 Smith M D Khanzadyan T Davis C J February 2003 Anatomy of the Herbig Haro object HH 7 bow shock Monthly Notices of the Royal Astronomical Society 339 2 524 536 Bibcode 2003MNRAS 339 524S doi 10 1046 j 1365 8711 2003 06195 x Bohm Karl Heinz 1989 Tenorio Tagle Guillermo Moles Mariano Melnick Jorge eds Herbig Haro objects Structure and Dynamics of the Interstellar medium Lecture Notes in Physics vol 350 Berlin Heidelberg Springer Berlin Heidelberg pp 282 294 doi 10 1007 bfb0114879 ISBN 978 3 540 51956 0 S2CID 222245602 retrieved 2022 10 18External links edit nbsp Wikimedia Commons has media related to Herbig Haro objects Catalogue of HH Objects at VizieR Animations of HH object jets from HST observations A Catalogue of Molecular Hydrogen Emission Line Objects in Outflows from Young Stars MHO Catalogue Portals nbsp Astronomy nbsp Spaceflight nbsp Outer space nbsp Solar System Retrieved from https en wikipedia org w index php title Herbig Haro object amp oldid 1212748254, wikipedia, wiki, book, books, library,

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