Aprotoplanetary nebula orpreplanetary nebula[1] (PPN, pluralPPNe) is anastronomical object which is at the short-lived episode during astar's rapidevolution between the lateasymptotic giant branch (LAGB)[a] phase and the subsequentplanetary nebula (PN) phase. A PPN emits strongly ininfrared radiation, and is a kind ofreflection nebula. It is the second-from-the-last high-luminosity evolution phase in the life cycle of intermediate-mass stars (1–8M☉).[2]: 469
The nameprotoplanetary nebula is an unfortunate choice due to the possibility of confusion with the same term being sometimes employed when discussing the unrelated concept ofprotoplanetary disks. The nameprotoplanetary nebula is a consequence of the older termplanetary 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 asNeptune andUranus. To avoid any possible confusion,Sahai, Sánchez Contreras & Morris 2005 suggested employing a new termpreplanetary nebula which does not overlap with any other disciplines of astronomy. They are often referred to aspost-AGB stars, although that category also includes stars that will never ionize their ejected matter.
During the lateasymptotic 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 theHertzsprung–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, theeffective 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)
During the ensuing protoplanetary nebula phase, the central star'seffective 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, collimatedwinds 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 arebipolar, knotty jets andHerbig–Haro-like "bow shocks". These shapes appear even in relatively "young" PPNe. (Davis et al. 2005)
The PPN phase continues until the central star reaches around 30,000 K and it is hot enough (producing enoughultraviolet radiation) to ionize the circumstellar nebula (ejected gases) and it becomes a kind ofemission nebula called a Planetary Nebula. This transition must take place in less than around 10,000 years or else the density of thecircumstellar 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)
Bujarrabal et al. (2001)[4]found that the "interactingstellar winds" model of Kwoket al. (1978)[5] 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;[6]Reyes-Ruiz & Lopez 1999;[7] Soker & Rappaport 2000;[8] Blackman, Frank & Welch 2001[9]) investigated whetheraccretion disk scenarios, similar to models used to explain jets fromactive galactic nuclei andyoung 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.[9] If the accretion-disk jet paradigm is correct andmagneto-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)
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