Apr 13
NASA – Blame it on the Rain (from Saturn’s Rings)
This artist’s concept illustrates how charged water particles flow into the Saturnian atmosphere from the planet’s rings, causing a reduction in atmospheric brightness. Image credit: NASA/JPL-Caltech/Space Science Institute/University of Leicester
A new study tracks the “rain” of charged water particles into the atmosphere of Saturn and finds there is more of it and it falls across larger areas of the planet than previously thought. The study, whose observations were funded by NASA and whose analysis was led by the University of Leicester, England, reveals that the rain influences the composition and temperature structure of parts of Saturn’s upper atmosphere. The paper appears in this week’s issue of the journal Nature.
“Saturn is the first planet to show significant interaction between its atmosphere and ring system,” said James O’Donoghue, the paper’s lead author and a postgraduate researcher at Leicester. “The main effect of ring rain is that it acts to ‘quench’ the ionosphere of Saturn. In other words, this rain severely reduces the electron densities in regions in which it falls.”
O’Donoghue explains that the ring’s effect on electron densities is important because it explains why, for many decades, observations have shown those densities to be unusually low at certain latitudes on Saturn. The study also helps scientists better understand the origin and evolution of Saturn’s ring system and changes in the planet’s atmosphere.
Apr 10
NASA – Suzaku ‘Post-mortem’ Yields Insight into Kepler’s Supernova
This composite of images from NASA’s Chandra X-ray Observatory shows the remnant of Kepler’s supernova in low (red), intermediate (green) and high-energy (blue) X-rays. The background is an optical star field taken from the Digitized Sky Survey. The distance to the object is uncertain, with estimates ranging from 13,000 to 23,000 light-years, but recent studies favor the maximum range. This image spans 12 arcminutes or about 80 light-years at the greatest distance.Credit: X-ray: NASA/CXC/NCSU/M.Burkey et al.; optical: DSS
An exploding star observed in 1604 by the German astronomer Johannes Kepler held a greater fraction of heavy elements than the sun, according to an analysis of X-ray observations from the Japan-led Suzaku satellite. The findings will help astronomers better understand the diversity of type Ia supernovae, an important class of stellar explosion used in probing the distant universe.
“The composition of the star, its environment, and the mechanism of the explosion may vary considerably among type Ia supernovae,” said Sangwook Park, an assistant professor of physics at the University of Texas at Arlington. “By better understanding them, we can fine-tune our knowledge of the universe beyond our galaxy and improve cosmological models that depend on those measurements.”
The best way to explore the star’s makeup is to perform a kind of post-mortem examination on the shell of hot, rapidly expanding gas produced by the explosion. By identifying specific chemical signatures in the supernova remnant, astronomers can obtain a clearer picture of the composition of the star before it blew up.
via NASA – Suzaku ‘Post-mortem’ Yields Insight into Kepler’s Supernova.
