===================================================================== ==> in this proposal, more time is being requested for gvdsteen.cno_abun ==> this proposal requests an upgrade from priority 3 for gvdsteen.cno_abun ===================================================================== accurate determinations of abundances have been hampered by the so called t^2-problem. this is probably one of the most important problems in present day pn research. the t^2-parameter is a measure for the degree of electron temperature (te) fluctuations in the ionized region. such fluctuations increase the strength of emission lines. this effect is stronger for lines originating from higher energy levels. consequently, if optical line ratios (e.g. o iii 4363,4959,5007) are used to calculate te, and if the fluctuations in te are present, the result will be systematically too high. since te is used to convert ionic abundances to elemental abundances, the t^2-parameter has a substantial influence on abundance determinations. models do not predict fluctuations in te, but observational evidence gathered so far contradicts this. the first goal of this proposal is to increase the small amount of observational data currently available and thus to obtain a stronger basis for investigating the t^2-problem. the second goal is to determine accurate abundances for the pn in our sample. the abundances in planetary nebulae (pn) reflect the evolutionary history of the central star. evolutionary models predict correlations between the core mass of the star and the ratios he/h, c/o and n/o. however no clear observational evidence for such relations exists and it is unclear whether this is caused by errors in the models or the abundance determinations. we want to use the iso data to search for possible correlations between the above mentioned abundance ratios and luminosity, which is directly related to the core mass.
Instrument
LWS01 , SWS01
Temporal Coverage
1997-03-02T22:37:51Z/1997-03-29T14:16:39Z
Version
1.0
Mission Description
The Infrared Space Observatory (ISO) was the worlds first true orbiting infrared observatory. Equipped with four highly-sophisticated and versatile scientific instruments, it was launched by Ariane in November 1995 and provided astronomers world-wide with a facility of unprecedented sensitivity and capabilities for a detailed exploration of the Universe at infrared wavelengths.
European Space Agency, VAN HOOF et al., 1999, 'ACCURATE ABUNDANCE DETERMINATION OF CNO IN PN. AN INVESTIGATION INTO THE T^2 PROBLEM.', 1.0, European Space Agency, https://doi.org/10.5270/esa-3u2gycl
