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Chemistry and dynamics of the pulsating starless core Barnard 68 Matt Redman National University of Ireland, Galway Matt Redman NUI Galway Collaborators • Eric Keto (CfA, Harvard, USA) • Jonathan Rawlings (University College London, UK)¸ • David Williams (University College London, UK) Matt Redman NUI Galway Star formation models The many models can be divided into two types 1. Dynamic/turbulent (e.g. Klessen et al 2000; Padoan & Norlund 2002; Ballesteros-Palledes 2003) • Rapid formation of interacting protostellar cores from density fluctuations generated by supersonic turbulence. Stars ‘freeze out’ as energy dissipated 2. Hydrostatic Shu model (e.g. Shu 1977; Shu, Adams & Lizano 1987) • Initially stable cloud gradually loses pressure support (thermal and/or magnetic) against gravity and collapses Matt Redman NUI Galway Observing molecular cloud cores • Stars form inside cold (~10 K) dense (~106 cm-3) dusty ‘cores’ in molecular clouds • These cores are highly obscured so need to observe in mm or sub-mm regimes • Continuum observations detect the dust emission • Line observations (from gas phase molecules or ions) trace the gas and its dynamics Matt Redman NUI Galway Barnard 68 • A Bok globule discovered in 1919 by Barnard • Contains a few solar masses of molecular gas and is gravitationally bound • Can we determine whether Barnard 68 (and objects like it) will, or will not, form a star? • Where does it fit into the turbulent or hydrostatic scenarios Matt Redman NUI Galway Barnard 68 Initial density structure Very direct approach carried out by Alves et al (2001) • Measure reddening of background stars through core to sample extinction at thousands of positions across the face of the core • Relies on the core being projected against a suitable star field such as the galactic bulge • Can then make an extinction map Matt Redman NUI Galway Initial density structure • Obtain a radial extinction profile by azimuthally averaging the sampled positions • Model the profile to find central density Matt Redman NUI Galway Initial density structure • Density profile well matched by a Bonner-Ebert sphere (Bonner 1956, Ebert 1955) • A Bonner-Ebert sphere is a self-gravitating cloud in hydrostatic equilibrium with a surrounding pressurised medium • Density profile can be roughly approximated as Matt Redman NUI Galway Bonner-Ebert spheres • Described by a modified Lane-Emden equation: where Matt Redman NUI Galway Bonner-Ebert spheres • Solution defined by a single parameter which contains the radius, central density and sound speed If collapse then the sphere is unstable to gravitational • B68 appears to be just about stable with a central density of ~few x 105 cm-3 Matt Redman NUI Galway Initial density structure Couple of objections to the Bonner-Ebert modelling: • Almost any shaped cloud can then be fitted by spherical geometries - should fit with a 3D code (Steinacker et al) • Transient structures in turbulent star formation models may also be fitted in this way even though not hydrostatic (Ballesteros-Paredes et al 2003) • Temperature not constant and other sources of pressure available (magnetic) Matt Redman NUI Galway Temperature structure • Dust heated by starlight and then re-radiates at longer wavelengths • Can map the dust emission in the mm/sub-mm continuum (e.g. using SCUBA Shirley et al 2001; Evans et al 2001) • Make assumptions about the dust properties (such as the opacity) to then model the dust density structure using dust radiative transfer codes • Gives a fit to the temperature profile: cores are warmer at the edge than the centre. Bianchi et al (2003) measure ~14 K outer regions, dropping to ~9 K inner regions Matt Redman NUI Galway Stability of cores • Recently suggested by Casselli et al (2004, in press) that cores should be divided as follows according to whether temperature and density are greater or less than Tc~10 K and nc ~ 105 cm-3 Stable starless cores - those whose Bonner-Ebert parameter suggests they will never become stars (‘failed cores’). These cores will not dissipate as expected in the turbulent models. Unstable pre-stellar cores - those whose parameters indicate they are unstable against collapse and may well show evidence of the onset of collapse Matt Redman NUI Galway Is Barnard 68 stable? • Barnard 68 is not cold enough and dense enough to suggest imminent collapse • Is it a transient or long lived structure? • If it is stable, there should be no collapse signature Matt Redman NUI Galway Chemical age • The centre of Barnard 68 is heavily depleted in CO and CS • N2H+ survives in the central regions • The depletion implies that B68 is a long-lived structure: freeze-out occurs in the centre first and moves outwards • Supported by dust emissivity measurements by Bianchi et al (2003) that suggest dust is composed of ice covered coagulated grains • B68 must have been dense and cold long enough for freezeout to occur Matt Redman NUI Galway Dynamics • Rich chemistry in molecular clouds initiated by cosmic rays. Lines excited by CMB. • Use gas phase rotational lines to probe the kinematics of the interiors of the cloud • Shape and strength of the line profile can reveal the internal velocity structure Matt Redman NUI Galway Line profiles and dynamics • Evans (1999) reviews the line profile shape expected from a collapse model (such as the Shu model) • Expect a double-peaked line profile with the blue wing stronger • Simple molecules such as CS and HCO+ are observed - not too abundant so not too optically thick and chemically ‘well behaved’ • If a blue asymmetric profile is seen then the rare isotope (e.g. H13CO+) is checked - should be optically thin single peaked gaussian Matt Redman NUI Galway Kinematics of B68 • If B68 is a stable starless core, should be no evidence of collapse or outflow • But it shows strange alternating pattern of red and blue asymmetric profiles Matt Redman NUI Galway Red Red Blue Blue Red CS (2-1) Lada et al (2001) Red HCO+ 3-2 Origin of velocity pattern • Alternating pattern of red and blue asymmetric profiles confirmed in another molecule • Turbulence of outer layers of cloud one possibility • Or some combination of rotation, infall and freeze-out • Keto & Field (2005) describe an instability in dusty BonnerEbert spheres - may be applicable to B68 Matt Redman NUI Galway Instability in Bonner-Ebert spheres • Consider a cloud in which the density is low and close to that of dust-gas thermal coupling • Cosmic rays heat the dust but the low density means the dust does not efficiently warm the gas - temperatures of dust and gas de-couple • If the cloud is perturbed by an increase in external pressure, the cloud contracts but the warmer dust heats the gas. The cloud then reexpands • Can set up an oscillation in the outer layers Matt Redman NUI Galway Application to B68 • This effect could be occuring in a non-uniform way in B68: some parts of the cloud are expanding, others contracting • If correct then stable starless cores could display ‘infall’ signatures that are in fact caused by instabilities in the cloud • As long as the oscillations are not too severe, the cloud will not collapse and will be long-lived • True infall indicated by infall signatures in the most volatile species such as N2H+ that trace the central gas plus a central density and temperature on the unstable side of the BonnerEbert solution Matt Redman NUI Galway Conclusions • The temperature and density of Barnard 68 indicate that it is gravitationally stable - it is not dense enough and too warm to collapse • The chemistry indicates that it is not a transient structure sufficient time with comparable physical conditions must have elapsed to allow freeze-out to take place • However the core is not quiescent but dynamically active in a complex but not entirely random way • Barnard 68 is unlikely to form a star unless external conditions change - it is a stable starless core Matt Redman NUI Galway