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The object shown in this NASA/ESA Hubble Space Telescope image is a remarkable example of a star going through death throes just as it dramatically transforms itself from a normal red giant star into a planetary nebula. This process happens so quickly that such objects are quite rare, even though astronomers believe that most stars like the Sun will eventually go through such a phase.

This star, with the prosaic name of OH231.8+4.2, is seen in this infrared picture blowing out gas and dust in two opposite directions. So much dust has been cast off and now surrounds the star that it cannot be seen directly, only its starlight that is reflected off the dust. The flow of gas is very fast, with a velocity up to 450,000 mph (700,000 km/h). With extreme clarity, this Hubble Near Infrared Camera and Multi-Object Spectrometer (NICMOS) image reveals that the fast-movinggas and dust are being collimated into several thin streamers (on theright) and a jet-like structure (on the left), which can be seen extending away from the centers. On the right, wisps of material in jet-like streamers appear to strike some dense blobs of gas. This interaction must produce strong shock waves in the gas.

The image is a composite of four images taken with different NICMOS infrared filters on March 28, 1998. It shows that the physical properties of the material, both composition and temperature, vary significantly throughout the outflowing material.

Observations by radio astronomers have found many unusual molecules inthe gas around this star, including many containing sulfur, such as hydrogen sulfide and sulfur dioxide. These sulfur compounds are believed to be produced in the shock waves passing through the gas. Because of the large amount of sulfur compounds, this object has earned the nickname "The Rotten Egg" Nebula. It resides in the constellation Puppis.

These NICMOS data pose a serious challenge to astrophysical theorists: How can a star generate such tightly collimated streams of gas and dust and accelerate them to such very high velocities? William B. Latter from the California Institute of Technology and his group are using these data to obtain a better understanding of the detailed structure in the outflowing material, look for evidence for the origin of the thin streamers and jets, and learn more about the star itself. Thisi nformation will give astronomers a more complete understanding of the final stages in the lives of stars like our Sun.