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A&A 409, L9-L12 (2003)
DOI: 10.1051/0004-6361:20031238
Letter
Gamma-ray bursts and X-ray melting of material to form chondrules and planets
P. Duggan1, B. McBreen1, A. J. Carr2, E. Winston1, G. Vaughan3, L. Hanlon1, S. McBreen1, L. Metcalfe4, Å. Kvick3 and A. E. Terry31 Department of Experimental Physics, University College Dublin, Dublin 4, Ireland
2 Mechanical Engineering Department, University College Dublin, Dublin 4, Ireland
3 European Synchrotron Radiation Facility, BP 220, 38043 Grenoble Cedex, France
4 XMM-Newton science Operations Center, European Space Agency, Villafranca del Castillo, 28080 Madrid, Spain
(Received 19 June 2003 / Accepted 8 August 2003 )
Abstract
Chondrules are millimeter sized objects of spherical to
irregular shape that constitute the major component of chondritic
meteorites that originate in the region between Mars and Jupiter
and which fall to Earth. They appear to have solidified rapidly
from molten or partially molten drops. The heat source that melted
the chondrules remains uncertain. The intense radiation from a
gamma-ray burst (GRB) is capable of melting material at distances
up to 300 light years. These conditions were created in the
laboratory for the first time when millimeter sized pellets were
placed in a vacuum chamber in the white synchrotron beam at the
European Synchrotron Radiation Facility (ESRF). The pellets were
rapidly heated in the X-ray and gamma-ray furnace to above
1400 °C melted and cooled. This process heats from the
inside unlike normal furnaces. The melted spherical samples were
examined with a range of techniques and found to have
microstructural properties similar to the chondrules that come
from meteorites. This experiment demonstrates that GRBs can melt
precursor material to form chondrules that may subsequently
influence the formation of planets. This work extends the field of
laboratory astrophysics to include high power synchrotron sources.
Key words: methods: laboratory -- gamma rays: bursts -- X-rays: general planetary systems: formation -- solar system: general
Offprint request: B. McBreen, brian.mcbreen@ucd.ie
© ESO 2003
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