First thick-disk exoplanet and the Milky Way






    TESS discovers its first thick-disk exoplanet. Astronomers using NASA’s transit exoplanet study satellite (TESS) have seen an Earth-sized planet orbiting LHS 1815, our galaxy’s thick disk, the Milky Way, and the artist of exoplanets the size of Land LHS 1815b and Has the impression. Artist’s impression of the Earth-sized exoplanet LHS 1815B and its host star. Current theories suggest that the Milky Way is made up of several components, a thin disk, a thick disk, a crown, and a protrusion.

    first thick-disk exoplanet

    The stars in the solar neighborhood are mostly members of the galactic disk, which contains a small fraction of the halo. To date, more than 4,000 exoplanets have been detected. However, it has been claimed that some of the known exoplanets show thick disk characteristics. The difference in the formation and evolution of the planet between the thick and first thick-disk exoplanet of the Milky Way remains a mystery. The newly discovered exoplanet, named LHS 1815b, is the first thick-disc planet found by Tess.

    We confirm the nature of the LHS 1815 first thick-disk exoplanet primarily based on its kinetic information, the Tsinghua University astronomer Tianjun Gan and colleagues note in their article. Generally speaking, thick disk stars are kinematically warmer than thin disk wires. This image, taken with the 4.1m Southern Astrophysical Research Telescope (SOAR), shows the M1-type dwarf star LHS 1815. LHS 1815 is a dull, luminous dwarf star type M1, located 97 light-years away. Also known as MASS J06042035-5518468, TIC 260004324, and TOI 704.

    TESS discovers its first thick-disk exoplanet

    This star is about half the size and half the mass of the Sun. LHS 1815b only orbits the original star once every 3.2 days at a distance of 0.04 AU (astronomical units). The alien world is approximately 1.1 times larger than Earth and 4.2 times more massive. Dr. Gan and his co-authors estimate that the planet’s temperature is around 344 ° C (651 ° F). We validate the planet by combining spatial, terrestrial photometry, spectroscopy and imaging, he said. Future Science of the internal structure and atmospheric properties of planets in such systems, for example.

    The upcoming James Webb Space Telescope (JWST), may examine differences in the efficiency of the formation and evolution of planetary systems. Different galactic. Discs (thick and thin) and crown) between components. The TESS spacecraft finds its first Earth-shaped planet around a nearby star. The next generation of exoplanet dams has arrived as NASA’s inspection and exoplanet-in-transit satellite. Tess sees stars closer and brighter than Kepler, the spacecraft that turned the motion of first thick-disk exoplanet discoveries into a holocaust.

    satellite (TESS)

    While satellite (TESS), which launched last year, has just begun its search for heaven, it is already beginning to discover new planets. Astronomers say they have discovered an Earth-sized planet called HD-21749C that is only 52 light-years from Earth and orbits its star every 8 days. This is TESS’s first discovery of an Earth-sized planet. Scientists also say they have confirmed HD 21749B. Which is slightly smaller than Neptune in a nearly 35-day orbit around the same star. Both excerpts from TESS exoplanets were teased earlier this year.

    From Earth’s point of view, Kepler discovered planets in the same basic way that he did, for the transit of planets, or passing in front of their stars but TESS will eventually study an area 400 times larger than Kepler’s corner of the sky and will focus on nearby, bright stars that will make it easier to track powerful observatories like the upcoming James Webb Space Telescope. One of TESS’s primary goals for its initial two-year mission is to discover 50 planets that are no more than four times larger than Earth and are measured on a larger scale.

    NASA’s transit exoplanet

    This is a strange goal, because TESS cannot really measure the mass of any planet, it can only determine how wide a planet is and how far it orbits. Instead, TESS was designed to work with other observatories, such as two telescopes in Chile that provide radial velocity measurements to fix the mass of HD 21749B. Radial velocity is a way for astronomers to observe the small gravitational pull that a planet has on its star. Unlike transit, radial velocity tells astronomers about the mass of the planets.

    With both measurements, telescopes can confirm each other’s findings and complement every piece of information about the distant world. In this case, radial velocity still cannot fix a mass on a small Earth-sized planet in the system, as it probably weighs only a few times more than our world. The largest NASA’s transit exoplanet has 23 heaviest land masses, and is most clearly shown in the data. In fact, it is rare to find such a large and dense planet.

    Astrophysical Journal Letters

    It is also far from its star, most of the planets in the TET will have orbits of less than 10 days. HD 21749B, orbiting every 35 days, is far enough away to be hot instead of hot. This makes it a fairly unique specimen that can tell astronomers a lot about planets. The discovery of the two planets has been announced Monday in Astrophysical Journal Letters by teams from the Massachusetts Institute of Technology and the Carnegie Institute for Science.

    Co-author Johanna Teske on the research paper did much of the work on the radial velocity side of the research. In an interview, he said the system was already part of a long-term survey and that as data accumulates. They get better odds on a smaller planet if they don’t have accurate measurements. We will continue to monitor it, perhaps for many years to come, she says. He also points out that as TESS moves north with its gaze from the stars in the southern hemisphere.

    TESS’ satellite

    There will be more ground-based radial velocity characteristics, which will help TESS not only achieve its goal of finding planets but its mass. can also be measured. The data will only come faster and, with it, possibly an even richer and planetary journey. Now we are far from the race, says Teske, NASA launched the ‘TESS’ satellite in search of exoplanets. Previous generations saw stars in the night sky and wondered if they, too, were orbiting the planets. Our generation first looks for the answer.

    We now know that there are planets around almost all the stars, and as our technology improves, we continue to explore more. NASA’s newest satellite, TESS (Transiting Exoplanet Survey Satellite), launched on April 16, 2018, will expand the search for bright stars around tiny rocky planets. We want to know how big those planets are, how they are orbiting, and how they have formed and developed. Do they have an atmosphere, are they clear or cloudy, and what are they made of? In the coming decades.

    host stars

    We will find planets like Earth at the correct distance from their stars as aqueous liquids. It is predictable that one has an atmosphere that contains molecules like free oxygen that indicate biological activity. TESS is an important step towards this long-term goal. Planets are so faint and small compared to their host stars that it is remarkable that we can detect them, let alone study their atmosphere. However, planets can, in our view, travel or “transit” through the face of first thick-disk exoplanet because they block a small fraction of the light from orbit. 

    TESS will monitor 200,000 luminous stars in the solar neighborhood, looking for small dips in its glow that reveal a planet in transition. To understand the exoplanet’s atmosphere, we must examine how they interact with stars. When a planet crosses a star, the thin stain on its atmosphere is illuminated by starlight. Some wavelengths of stars will be absorbed by molecules in the atmosphere, while other wavelengths will shine directly. Therefore, given what wavelength reaches us and what atmosphere is formed, it is not known.

    exoplanet atmospheres

    The starlight spectrum that traverses a planet’s atmosphere can tell us that the atmosphere is made up of © Christine Daniloff / MIT, Julian de Wit. Such comments are correct about the current range of capabilities required by the James Webb Space Telescope (JWST). Hubble needs a successor of $ 8 billion to launch in 2020. With a 6.5 meter wide mirror, Hubble can store every time More light and with specially designed instruments, the JWST is designed to study exoplanet atmospheres.

    To use JWST more effectively, we first need to know which stars host the best transiting first thick-disk exoplanet to study, and therefore we need TESS. Its predecessor spacecraft, Kepler, surveyed 150,000 stars in a patch of sky near the Cygnus constellation, and found over a thousand planets, such as rocky planets like Jupiter, to first thick-disk exoplanet as small as Mercury but Kepler covered only a small patch of sky in which some stars that studied our planets shone. A million stars in one night.

    camera lenses

    In contrast, ground-based telescopes have discovered wide swaths of the sky, looking at many more bright stars to move exoplanets. The most successful has been the UK-led wide-angle planet search project (WASP) of which I am a member. Using a variety of camera lenses, WASP has spent the past decade monitoring a million stars, looking for clear transit every night, and has found around 200 exoplanets, some of which are now for JWST. It is selected as the target but land traffic surveys have an important limitation.

    They look at the Earth’s atmosphere and this severely limits the quality of the data. They can detect luminous dives by 1%. Which is enough to find giant gas planets that are like our own Jupiter and Saturn but small, rocky planets avoid very little light. If our Earth is projected against our sun, it will produce only a 0.01% drop. JWST is currently being read for release. JWST is currently being read for release. TESS will combine the best of these two approaches, observing bright stars across the sky, with the benefit of doing so from space.

    You must find small rocky planets that Kepler proved to be abundant but orbiting with stars bright enough for us to study their atmosphere. TESS will generally inspect each area of the sky for 30 days. This means that it will detect planets that do not take long to orbit their stars, and therefore will produce many transits while TESS watches them. Planets with short orbits are close to their stars, meaning that most planets will be too hot for liquid TESS water.


    But cooler, planetary red dwarf stars that orbit darker may be at the right temperature for life, no matter how close they are. The dwarf star TRAPPIST-1 is 1,000 times dimmer than our Sun, and is known to harbor seven nearby planets. While TESS searches for planets orbiting dwarf stars from space, the SpecULOOS study will search for smaller, more diffuse stars from the ground. The planets they see will be the main targets of JWST. An article on the discovery was published in the Astronomical Journal.

    The thick disk of the Milky Way is 10 billion years old, astronomers say. The thick disk of the Milky Way is 10 billion years old, astronomers say. Our Milky Way has two disk-shaped structures, known as ‘thick’ and ‘thin’ disks. Thick disks comprise about 20% of all stars in the galaxy and, based on their structure and vertical suction, the pair is believed to be old. Using data from NASA’s Kepler Space Telescope, astronomers have calculated that the thick disk is about 10 billion years old.

    Milky Way

    From a great distance, our galaxy, the Milky Way, looks like a thin disk of stars that orbits its central region every hundred million years, where hundreds of billions of stars gravitate to ‘hit’ it but this stretch of gravity is very weak in the galaxy’s distant outer discs. There, the hydrogen atoms that make up the gas disk of most of the Milky Way are no longer confined to a thin plane, but instead give the disk an S or distorted appearance.

    From a great distance, our galaxy, the Milky Way, looks like a thin disk of stars that orbits its central region every hundred million years, where hundreds of billions of stars gravitate to ‘hit’ it. Provide. But this stretch of gravity is very weak in the galaxy’s distant outer discs. There, the hydrogen atoms that make up the gas disk of most of the Milky Way are no longer limited to a thin plane, but instead give the disk an S or distorted appearance.


    “Clear a Mystery,” lead author Dr. Said Sanjib Sharma, ARC Center of Excellence for All-Sky Astrophysics in Three Dimensions (ASTRO-3D) and astronomer at the University of Sydney. Previously, the data on the age distribution of stars on the disk did not agree with the models created to describe it but no one knew where the error was: the data or the model. Now we are very sure that we have succeeded. Dr. Sharma and colleagues.

    A method of identifying the internal structures of stars by measuring their asterisk-like oscillations, is known as asterosismology. Dr. Denise Stello has ASRRO-Three D and Dr. from the University of New South Wales. Earthquakes create sound waves within stars or vibrate, said Dennis Stello. The frequency of production tells us things about the intrinsic properties of stars, including their age. It’s like identifying a violin as a stradivarius that makes it sound.

    An artist’s impression of the Milky Way shows thick and thin discs. This allows researchers dating back to age to essentially look back in time and understand this period in the history of the universe when the Milky Way was formed, a practice known as galactic archeology. Not that they really hear the sound generated by Star-Quake. Instead, they look for how internal movement is reflected in changes in brightness. Dr. Sharma said: Stars are gas-filled spherical devices but their vibrations are small.


    So we must watch very carefully. Kepler’s best brightness measurements were ideal for him. The telescope was so sensitive that it could detect the shape of a car’s headlight, as fleas move over it. Data provided over the four years since Kepler’s launch in 2009 presented a problem for astronomers. The information that was provided speculated that the thick disk had more small stars than the model. The question the scientists faced was stark: were the models wrong or the data incomplete!

    A recent spectroscopic analysis revealed that the chemical structure included in the current model for cables in thick discs was incorrect, which affected their age prediction. With this in mind, the researchers found that the asteroseismic data being viewed now falls into “excellent agreement” with the model’s prediction. The results provide strong indirect validation of the analytical power of asterosismology to estimate age, said Dr. Stello. The results have been published in the monthly notices of the Royal Astronomical Society.

    First thick-disk exoplanet
    TESS discovers its first thick-disk exoplanet
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