For centuries, astronomers have been studying the Milky Way in order to get a better understanding of its size and structure. And while modern instruments have yielded invaluable observations of our galaxy and others (which have allowed astronomers to gain a general picture of what it looks like), a truly accurate model of our galaxy has been elusive.
For example, a recent study by a team of astronomers from National Astronomical Observatories of Chinese Academy of Sciences (NAOC) has shown that the Milky Way's disk is not flat (as previously thought). Based on their findings, it appears that the Milky Way is increasingly warped and twisted the farther away one core ventures.
The study which details their findings recently appeared in the scientific journal Nature, titled " An intuitive 3D map of the Galactic warp's precession traced by classical Cepheids. " .
To break it down, galaxies like the Milky Way consists of thin disks of stars that orbit around a central bulge once every few hundred million years. In this bulge, the gravitational force of hundreds of billions of stars and dark matter hold the galaxy's matter and gas together. However, in the far outer regions of the galaxy, the hydrogen atoms made up of the gas disk are no longer confined to a thin plane.
As Dr. Chen explained in a recent Kavli Institute press statement:
" It is notoriously difficult to determine distances from the Sun to parts of the Milky Way's outer gas disk without having a clear idea of what that disk actually looks like. However, we recently published new catalog of periodically variable stars known as classical Cepheids, for which distances as accurate as 3 to 5% can be determined . Classical Cephieds are a subclass of Cephied Variables, a type of star that is noted for the way it regularly pulses, varying in both diameter and temperature. This produces changes in brightness that are predictable in terms of period and amplitude and makes them highly useful for measuring galactic and cosmic distances.
Classical Cepheids are of particular type of young yellow bright giants and supergiants that are 4 to 20 times as massive as our Sun and up to 100,000 times as luminous. This means that they have short lifespans which sometimes last only a few million years before exhausting their fuel. They also experience pulsations that can last as long as one month long, which makes them very reliable for measuring the distances to other galaxies. Shu Wang, of the Kavli Institute for Astronomy and Astrophysics and authored the paper, stated:
" Much of our Milky Way is hidden by dust, which makes it difficult to measure the distances to stars. Fortunately, observations that long infrared wavelengths can circumvent this problem. For the sake of their study, the team established a 3D Galactic Disk model based on the positions of 1,339 Classical Cephieds. From this, they were able to provide strong evidence that the galactic disk is not in line with the galactic center. In fact, when viewed from above, the Milky Way's disk would appear S-shaped, with one side curving up and the other curving down.
Said Macquarie University's Professor Richard de Grijs, a senior co-author on the paper:
stars and the Milky Way's gas disk follow each other closely. This offers new insights into the formation of our home galaxy. Perhaps more importantly, in the Milky Way's outer regions, we found that the S-like stellar disk is warped in a progressively twisted spiral pattern. "
which showed progressively twisted spiral patterns. By combining their results with those observations, the researchers found that the Milky Way's spiral pattern is most likely caused by rotational forcing (aka "torques") or the inner disk.
This latest study has provided an updated map of our galaxies stellar motions, which would be light on the origins of the Milky Way. What's more, it could also inform our understanding of galaxy formation and the evolution of the cosmos.
Further Reading: Kavli Institute for Astronomy and Astrophysics, Nature