The Hubble telescope captured the galaxy NGC 685, made up of more than 100 million stars, appearing to orbit in the depths of space The average galaxy NGC 685 contains at least 100 million stars. About 58 million light-years from Earth, galaxy NGC 685 appears to be orbiting in the depths of space. The Hubble Space Telescope image, the last of six released as part of Hubble's Galaxy Week, shows the galaxy with its spiral arms dotted with countless pockets of bright blue regions called star clusters. Closer to the center of the galaxy, there are also many twisted red wisps, representing bands of gas and dust where new generations of stars form over eons. [caption id="attachment_69171" align="aligncenter" width="598"] galaxy[/caption] NGC 685: a galaxy home to millions of stars surprised Hubble NASA's accompanying description of the photo of the galaxy NGC 685 says it is located in the constellation Eridanus, measures about 60,000 light-years, and may contain at least 100 million stars. In comparison, the Milky Way is estimated to consist of approximately 100 billion stars. Despite the difference in size and number of stars, both galaxies have an interesting feature: they have a central bar that crosses the cores of the galaxies. In this image of the galaxy NGC 685, this red-flecked bar can be seen stretching horizontally within a small circle of gas and dust. Its intense brilliance is due to the many stars concentrated in a relatively small area. Previous studies have shown that such bars are observed in about two-thirds of spiral galaxies. Gas and other material flows into the galactic cores through these bridges, indicating that the galaxy's "formative period" is over, astronomers say. Although little time has been devoted to studying NGC 685, studying bar galaxies like this one helps astronomers understand how galaxies evolve and whether the process is different for our galaxy.

2020 February 23

Illustris Simulation of the Universe Video Credit: Illustris Collaboration, NASA, PRACE, XSEDE, MIT, Harvard CfA; Music: The Poisoned Princess (Media Right Productions)

Explanation: How did we get here? Click play, sit back, and watch. A computer simulation of the evolution of the universe provides insight into how galaxies formed and perspectives into humanity's place in the universe. The Illustris project exhausted 20 million CPU hours in 2014 following 12 billion resolution elements spanning a cube 35 million light years on a side as it evolved over 13 billion years. The simulation tracks matter into the formation of a wide variety of galaxy types. As the virtual universe evolves, some of the matter expanding with the universe soon gravitationally condenses to form filaments, galaxies, and clusters of galaxies. The featured video takes the perspective of a virtual camera circling part of this changing universe, first showing the evolution of dark matter, then hydrogen gas coded by temperature (0:45), then heavy elements such as helium and carbon (1:30), and then back to dark matter (2:07). On the lower left the time since the Big Bang is listed, while on the lower right the type of matter being shown is listed. Explosions (0:50) depict galaxy-center supermassive black holes expelling bubbles of hot gas. Interesting discrepancies between Illustris and the real universe have been studied, including why the simulation produced an overabundance of old stars.

∞ Source: apod.nasa.gov/apod/ap200223.html

IllustrisTNG - Most perfect model of the universe

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Astronomers have discovered a galaxy that already had a high concentration of metals a billion years after the Big Bang. Early galaxies contain mostly hydrogen and helium, but this distant galaxy is anomalously rich in metals The universe is becoming more metallic over time: in its younger days, it was composed mostly of hydrogen and helium. But recently, researchers discovered a galaxy that was well ahead of this trend and, a billion years after the Big Bang, had accumulated a high content of metals. Almost all atoms heavier than helium originate in stars, the “forges of the cosmos,” which transform primordial materials into the many different elements we see today. These "forges" process the finite amount of hydrogen and helium in the Universe. As a result, the total supply of hydrogen decreases over time, while the proportion of heavier elements (which astronomers call "metals" regardless of their actual metallic properties) increases. When astronomers look back and observe the early stages of the universe, they expect to see mostly pure hydrogen and helium. [caption id="attachment_68900" align="aligncenter" width="780"] galaxy[/caption] This prediction is generally supported by observations, and when looking at galaxies created in the first 1.5 billion years after the Big Bang, researchers most often observe clouds of gas that contain almost no metals. However, a collaboration led by Jianhao Huyang of the University of South Carolina recently discovered a contradiction to this convention: their observations of a hazy galaxy created a billion years ago showed a metal fraction higher than predicted for such a young source by more than two orders of magnitude. Astronomers have discovered a galaxy that set the trend for a high proportion of metals before anyone else Huyang and his colleagues made this discovery by observing a distant quasar called SDSS J002526.84-014532.5, which has a redshift of 5.07. Between the Earth and this source, there is a galaxy with a redshift of 4.74. As light from a quasar passes through the diffuse gas of a galaxy on its way to our telescopes, certain wavelengths of radiation are preferentially absorbed by the molecules and atoms they encounter along the way. By measuring the relative amount of this absorption, the researchers were able to determine which elements were trying to block the path of light and how dense they were. They discovered that the galaxy contains significant amounts of carbon, oxygen, magnesium, and other heavy elements. Just 1.2 billion years after the Big Bang, this galaxy already had a greater relative amount of carbon and oxygen than our own Sun, which was born many billions of years later. Models of early galaxy formation predict a significantly lower proportion of metals, even taking into account the large uncertainties of described but not yet seen first-generation stars. Like many unexpected discoveries, the authors of the present study cannot yet explain what could lead to such a significant content of heavy elements. They acknowledge that this may be because looking at this particular direction may have passed through a patch of "developed" gas, and the galaxy as a whole may be as metal-poor as expected. However, in this case, they will not be able to explain how the light passed through such a small area with exactly the composition data obtained. It may be time to reconsider models of the chemical evolution of early galaxies, or there may be something special about this particular galaxy that remains hidden.