Protoplanetary nebula IRAS 13208-6020 is formed from material that is shed by a central star.
The name protoplanetary nebula is an unfortunate choice due to the possibility of confusion with the same term being sometimes employed when discussing the unrelated concept of protoplanetary disks. The name protoplanetary nebula is a consequence of the older term planetary nebula, which was chosen due to early astronomers looking through telescopes and finding a similarity in appearance of planetary nebula to the gas giants such as Neptune and Uranus. To avoid any possible confusion, Sahai, Sánchez Contreras & Morris 2005 suggested employing a new term preplanetary nebula which does not overlap with any other disciplines of astronomy. They are often referred to as post-AGB stars, although that category also includes stars that will never ionize their ejected matter.
Evolutionedit
Beginningedit
During the late asymptotic giant branch (LAGB)[a] phase, when mass loss reduces the hydrogen envelope's mass to around 10−2M☉ for a core mass of 0.60 M☉, a star will begin to evolve towards the blue side of the Hertzsprung–Russell diagram. When the hydrogen envelope has been further reduced to around 10−3M☉, the envelope will have been so disrupted that it is believed further significant mass loss is not possible. At this point, the effective temperature of the star, T*, will be around 5,000 K and it is defined to be the end of the LAGB and the beginning of the PPN. (Davis et al. 2005)
Protoplanetary nebula phaseedit
Protoplanetary nebula known as IRAS 20068+4051 taken by Hubble's Advanced Camera for Surveys.
During the ensuing protoplanetary nebula phase, the central star's effective temperature will continue rising as a result of the envelope's mass loss as a consequence of the hydrogen shell's burning. During this phase, the central star is still too cool to ionize the slow-moving circumstellar shell ejected during the preceding AGB phase. However, the star does appear to drive high-velocity, collimated winds which shape and shock this shell, and almost certainly entrain slow-moving AGB ejecta to produce a fast molecular wind. Observations and high-resolution imaging studies from 1998 to 2001, demonstrate that the rapidly evolving PPN phase ultimately shapes the morphology of the subsequent PN. At a point during or soon after the AGB envelope detachment, the envelope shape changes from roughly spherically symmetric to axially symmetric. The resultant morphologies are bipolar, knotty jets and Herbig–Haro-like "bow shocks". These shapes appear even in relatively "young" PPNe. (Davis et al. 2005)
Endedit
The PPN phase continues until the central star reaches around 30,000 K and it is hot enough (producing enough ultraviolet radiation) to ionize the circumstellar nebula (ejected gases) and it becomes a kind of emission nebula called a Planetary Nebula. This transition must take place in less than around 10,000 years or else the density of the circumstellar envelope will fall below the PN formulation density threshold of around 100[clarification needed] per cm³ and no PN will result, such a case is sometimes referred to as a 'lazy planetary nebula'. (Volk & Kwok 1989)
Recent conjecturesedit
An interstellar butterfly - protoplanetary nebula Roberts 22[1]
Bujarrabal et al. (2001) [2] found that the "interacting stellar winds" model of Kwok et al. (1978) [3] of radiatively-driven winds is insufficient to account for their CO observations of PPN fast winds which imply high momentum and energy inconsistent with that model. Complementarily, theorists (Soker & Livio 1994; [4] Reyes-Ruiz & Lopez 1999;[5] Soker & Rappaport 2000;[6] Blackman, Frank & Welch 2001[7]) investigated whether accretion disk scenarios, similar to models used to explain jets from active galactic nuclei and young stars, could account for both the point symmetry and the high degree of collimation seen in many PPN jets. In such models applied to the PPN context, the accretion disk forms through binary interactions. Magneto-centrifugal launching from the disk surface is then a way to convert gravitational energy into the kinetic energy of a fast wind in these systems.[7] If the accretion-disk jet paradigm is correct and magneto-hydrodynamics (MHD) processes mediate the energetics and collimation of PPN outflows, then they will also determine physics of the shocks in these flows, and this can be confirmed with high-resolution pictures of the emission regions that go with the shocks. (Davis et al. 2005)
^ The late asymptotic giant branch begins at the point on the asymptotic giant branch (AGB) where a star is no longer observable in visible light and becomes an infrared object. (Volk & Kwok 1989)
Referencesedit
^"An interstellar butterfly". ESA / HUBBLE. Retrieved 11 March 2014.
^"Bujarrabal, V., Castro-Carrizo, A., Alcolea, J., S{\'a}nchez Contreras, C.; 2001.; Mass, linear momentum and kinetic energy of bipolar flows in protoplanetary nebulae.; Astronomy and Astrophysics 377, 868–897. doi:10.1051/0004-6361:20011090".
^"Kwok, S., Purton, C.R., Fitzgerald, P.M.; 1978; On the origin of planetary nebulae; The Astrophysical Journal 219, L125–L127. doi:10.1086/182621".
^"Soker, N., Livio, M.; 1994; Disks and jets in planetary nebulae; The Astrophysical Journal 421, 219. doi:10.1086/173639".
^"Reyes-Ruiz, M., López, J.A.; 1999; Accretion Disks in Pre-Planetary Nebulae; The Astrophysical Journal 524, 952–960. doi:10.1086/307827".
^"Soker, N., Rappaport, S.; 2000; The Formation of Very Narrow Waist Bipolar Planetary Nebulae; The Astrophysical Journal 538, 241–259. doi:10.1086/309112".
^ ab"Blackman, E.G., Frank, A., Welch, C.; 2001; Magnetohydrodynamic Stellar and Disk Winds: Application to Planetary Nebulae; The Astrophysical Journal 546, 288–298. doi:10.1086/318253".
Davis, C. J.; Smith, M. D.; Gledhill, T. M.; Varricatt, W. P. (2005), "Near-infrared echelle spectroscopy of protoplanetary nebulae: probing the fast wind in H2", Monthly Notices of the Royal Astronomical Society, 360 (1): 104–118, arXiv:astro-ph/0503327, Bibcode:2005MNRAS.360..104D, doi:10.1111/j.1365-2966.2005.09018.x.
Kastner, J. H. (2005), "Near-death Transformation: Mass Ejection in Planetary Nebulae and Protoplanetary Nebulae", American Astronomical Society Meeting 206, #28.04; Bulletin of the American Astronomical Society, 37: 469, Bibcode:2005AAS...206.2804K.
Sahai, Raghvendra; Sánchez Contreras, Carmen; Morris, Mark (2005), "A Starfish Preplanetary Nebula: IRAS 19024+0044" (PDF), The Astrophysical Journal, 620 (2): 948–960, Bibcode:2005ApJ...620..948S, doi:10.1086/426469.
Volk, Kevin M.; Kwok, Sun (July 1, 1989), "Evolution of protoplanetary nebulae", The Astrophysical Journal, 342: 345–363, Bibcode:1989ApJ...342..345V, doi:10.1086/167597.
Szczerba, Ryszard; Siódmiak, Natasza; Stasińska, Grażyna; Borkowski, Jerzy (April 23, 2007), "An evolutive catalogue of Galactic post-AGB and related objects", Astronomy and Astrophysics, 469 (2): 799–806, arXiv:astro-ph/0703717, Bibcode:2007A&A...469..799S, doi:10.1051/0004-6361:20067035.
December 14, 2023
protoplanetary, nebula, confused, with, protoplanetary, disk, protoplanetary, nebula, preplanetary, nebula, sahai, sánchez, contreras, morris, 2005, plural, ppne, astronomical, object, which, short, lived, episode, during, star, rapid, evolution, between, late. Not to be confused with Protoplanetary disk A protoplanetary nebula or preplanetary nebula Sahai Sanchez Contreras amp Morris 2005 PPN plural PPNe is an astronomical object which is at the short lived episode during a star s rapid evolution between the late asymptotic giant branch LAGB a phase and the subsequent planetary nebula PN phase A PPN emits strongly in infrared radiation and is a kind of reflection nebula It is the second from the last high luminosity evolution phase in the life cycle of intermediate mass stars 1 8 M Kastner 2005 The Westbrook Nebula a protoplanetary nebula Contents 1 Naming 2 Evolution 2 1 Beginning 2 2 Protoplanetary nebula phase 2 3 End 3 Recent conjectures 4 See also 5 Notes 6 ReferencesNaming edit nbsp Protoplanetary nebula IRAS 13208 6020 is formed from material that is shed by a central star The name protoplanetary nebula is an unfortunate choice due to the possibility of confusion with the same term being sometimes employed when discussing the unrelated concept of protoplanetary disks The name protoplanetary nebula is a consequence of the older term planetary nebula which was chosen due to early astronomers looking through telescopes and finding a similarity in appearance of planetary nebula to the gas giants such as Neptune and Uranus To avoid any possible confusion Sahai Sanchez Contreras amp Morris 2005 suggested employing a new term preplanetary nebula which does not overlap with any other disciplines of astronomy They are often referred to as post AGB stars although that category also includes stars that will never ionize their ejected matter Evolution editBeginning edit During the late asymptotic giant branch LAGB a phase when mass loss reduces the hydrogen envelope s mass to around 10 2 M for a core mass of 0 60 M a star will begin to evolve towards the blue side of the Hertzsprung Russell diagram When the hydrogen envelope has been further reduced to around 10 3 M the envelope will have been so disrupted that it is believed further significant mass loss is not possible At this point the effective temperature of the star T will be around 5 000 K and it is defined to be the end of the LAGB and the beginning of the PPN Davis et al 2005 Protoplanetary nebula phase edit nbsp Protoplanetary nebula known as IRAS 20068 4051 taken by Hubble s Advanced Camera for Surveys During the ensuing protoplanetary nebula phase the central star s effective temperature will continue rising as a result of the envelope s mass loss as a consequence of the hydrogen shell s burning During this phase the central star is still too cool to ionize the slow moving circumstellar shell ejected during the preceding AGB phase However the star does appear to drive high velocity collimated winds which shape and shock this shell and almost certainly entrain slow moving AGB ejecta to produce a fast molecular wind Observations and high resolution imaging studies from 1998 to 2001 demonstrate that the rapidly evolving PPN phase ultimately shapes the morphology of the subsequent PN At a point during or soon after the AGB envelope detachment the envelope shape changes from roughly spherically symmetric to axially symmetric The resultant morphologies are bipolar knotty jets and Herbig Haro like bow shocks These shapes appear even in relatively young PPNe Davis et al 2005 End edit The PPN phase continues until the central star reaches around 30 000 K and it is hot enough producing enough ultraviolet radiation to ionize the circumstellar nebula ejected gases and it becomes a kind of emission nebula called a Planetary Nebula This transition must take place in less than around 10 000 years or else the density of the circumstellar envelope will fall below the PN formulation density threshold of around 100 clarification needed per cm and no PN will result such a case is sometimes referred to as a lazy planetary nebula Volk amp Kwok 1989 Recent conjectures edit nbsp An interstellar butterfly protoplanetary nebula Roberts 22 1 Bujarrabal et al 2001 2 found that the interacting stellar winds model of Kwok et al 1978 3 of radiatively driven winds is insufficient to account for their CO observations of PPN fast winds which imply high momentum and energy inconsistent with that model Complementarily theorists Soker amp Livio 1994 4 Reyes Ruiz amp Lopez 1999 5 Soker amp Rappaport 2000 6 Blackman Frank amp Welch 2001 7 investigated whether accretion disk scenarios similar to models used to explain jets from active galactic nuclei and young stars could account for both the point symmetry and the high degree of collimation seen in many PPN jets In such models applied to the PPN context the accretion disk forms through binary interactions Magneto centrifugal launching from the disk surface is then a way to convert gravitational energy into the kinetic energy of a fast wind in these systems 7 If the accretion disk jet paradigm is correct and magneto hydrodynamics MHD processes mediate the energetics and collimation of PPN outflows then they will also determine physics of the shocks in these flows and this can be confirmed with high resolution pictures of the emission regions that go with the shocks Davis et al 2005 See also editBipolar nebula Bipolar outflow List of protoplanetary nebulae Planetary nebulaNotes edit The late asymptotic giant branch begins at the point on the asymptotic giant branch AGB where a star is no longer observable in visible light and becomes an infrared object Volk amp Kwok 1989 References edit An interstellar butterfly ESA HUBBLE Retrieved 11 March 2014 Bujarrabal V Castro Carrizo A Alcolea J S a nchez Contreras C 2001 Mass linear momentum and kinetic energy of bipolar flows in protoplanetary nebulae Astronomy and Astrophysics 377 868 897 doi 10 1051 0004 6361 20011090 Kwok S Purton C R Fitzgerald P M 1978 On the origin of planetary nebulae The Astrophysical Journal 219 L125 L127 doi 10 1086 182621 Soker N Livio M 1994 Disks and jets in planetary nebulae The Astrophysical Journal 421 219 doi 10 1086 173639 Reyes Ruiz M Lopez J A 1999 Accretion Disks in Pre Planetary Nebulae The Astrophysical Journal 524 952 960 doi 10 1086 307827 Soker N Rappaport S 2000 The Formation of Very Narrow Waist Bipolar Planetary Nebulae The Astrophysical Journal 538 241 259 doi 10 1086 309112 a b Blackman E G Frank A Welch C 2001 Magnetohydrodynamic Stellar and Disk Winds Application to Planetary Nebulae The Astrophysical Journal 546 288 298 doi 10 1086 318253 Davis C J Smith M D Gledhill T M Varricatt W P 2005 Near infrared echelle spectroscopy of protoplanetary nebulae probing the fast wind in H2 Monthly Notices of the Royal Astronomical Society 360 1 104 118 arXiv astro ph 0503327 Bibcode 2005MNRAS 360 104D doi 10 1111 j 1365 2966 2005 09018 x Kastner J H 2005 Near death Transformation Mass Ejection in Planetary Nebulae and Protoplanetary Nebulae American Astronomical Society Meeting 206 28 04 Bulletin of the American Astronomical Society 37 469 Bibcode 2005AAS 206 2804K Sahai Raghvendra Sanchez Contreras Carmen Morris Mark 2005 A Starfish Preplanetary Nebula IRAS 19024 0044 PDF The Astrophysical Journal 620 2 948 960 Bibcode 2005ApJ 620 948S doi 10 1086 426469 Volk Kevin M Kwok Sun July 1 1989 Evolution of protoplanetary nebulae The Astrophysical Journal 342 345 363 Bibcode 1989ApJ 342 345V doi 10 1086 167597 Szczerba Ryszard Siodmiak Natasza Stasinska Grazyna Borkowski Jerzy April 23 2007 An evolutive catalogue of Galactic post AGB and related objects Astronomy and Astrophysics 469 2 799 806 arXiv astro ph 0703717 Bibcode 2007A amp A 469 799S doi 10 1051 0004 6361 20067035 Retrieved from https en wikipedia org w index php title Protoplanetary nebula amp oldid 1156361368, wikipedia, wiki, book, books, library,
