Tiny Dust Could Yield: Dust is mostly considere the stuff that goes airborne when your house’s window gets a little squeaky. But according to a new NASA Hubble Space Telescope study, the dust universe that we see in our everyday lives is just one tiny part of a much grander picture. In this article, learn how the dust might be an important clue into what’s happening deep in space!
Minuscule Residue Could Yield Large Responses Under Webb Telescope’s Look
The James Webb Space Telescope, set to launch in 2018, will have the ability to see tiny bits of dust and other debris. That are too small to be seen by current telescopes. The telescope’s powerful optics will be able to gather data about these objects in unprecedente detail. This information could help astronomers learn more about the origins and evolution of our universe.
What do we know about the dust?
Dust under the Webb Telescope’s gaze could yield more answers about the early universe than any other telescope. The Webb Telescope is the largest space telescope ever create and its primary mission is to study the first galaxies that form after the Big Bang. Dust is a major component of these early galaxies and can reveal important information about their formation and evolution.
The dust in these galaxies is made up of smaller particles. Which are much harder to see than stars or planets. However, because dust emits light when it is illuminate by starlight, it can be use to identify stars and determine their distances from Earth. By studying the distribution of dust in different parts of the universe. Scientists will be able to learn more about. How the universe evolve and what kinds of objects were present during its earliest days.
Webb Telescope observations should provide crucial information about how these small particles are distribute throughout space and how they interact with one another. This data will also help scientists better understand how galaxies form and grow over time. By understanding the makeup of dust in early galaxies, we can better understand why some celestial objects look different than others and gain a deeper understanding of our own origins.
What might the data mean?
The Webb Telescope, set to launch in 2019. Will be one of the most powerful telescopes ever built. One potential area of research is dark matter. Dark matter is a mysterious substance that makes up roughly 25% of all the matter in the universe. It’s hard to see and impossible to measure. But its influence is felt everywhere.
By studying how galaxies behave, scientists can learn more about dark matter. This information could help them better understand. How it behaves and identify potential places where it might be found. The Webb Telescope may also be able to observe planets outside of our solar system. By understanding their atmospheres and surface features. We could learn a lot about these worlds, including whether or not they could support life.
What else can NASA learn with the Hubble Space Telescope?
NASA is using the Hubble Space Telescope to study a mysterious planet size object call W49B. This tiny dust could yield big answers under Webb telescope’s gaze. The goal of the study is to learn more about how planets form, and the dust may provide valuable clues.
W49B measures just over one-hundred th of a mile (160 kilometers) across, and it orbits an unknown star in the constellation Camelopardalis. Astronomers believe that W49B might be a protoplanet, which is a small chunk of ice and dust that forms before a planet does. Protoplanets can become planets if they grow large enough, but they often end up breaking apart because their gravity is not strong enough.
To learn more about W49B, astronomers use Hubble to take pictures of it from different angles. They also analyz data from the space probe Kepler, which has been studying thousands of stars for signs of alien life. By analyzing these pictures and data. They were able to identify features on W49B that suggest it might be a protoplanet.
The findings have raise some interesting questions about how planets form. For example, if W49B did not break apart as it grew larger. Then what cause its little pieces to come together in the first place? And why didn’t its gravity keep it together? These are all questions that scientists will need to answer in order to better understand protoplanetary evolution.