Exoplanets tally is now confirmed 6000

 NASA’s announced 6,000 exoplanets are now confirmed

It’s been 30 years since the discovery of the first planet around another star like our Sun. With every new discovery, scientists move closer to answering whether there are other planets like Earth which could host life as we know it. The milestone highlights the accelerating rate of discoveries, just over three decades since the first exoplanets were found. NASA announced recently that its tally of planets outside our solar system has reached 6,000. Confirmed planets are added to the count on a rolling basis by scientists from around the world. So no single planet is the 6,000th entry. The number is monitored by NASA’s Exoplanet Science Institute (NExScI), based at Caltech’s IPAC in Pasadena, California. There are more than 8,000 additional candidate planets awaiting confirmation, with NASA leading the world in searching for life in the universe. Scientists have found more than 6,000 exoplanets (planets outside our solar system) throughout the galaxy. However, they can only study most of them indirectly. But scientists know they vary widely, from small, rocky worlds and gas giants to water-rich planets and those as hot as stars. 

“This milestone represents decades of cosmic exploration driven by NASA space telescopes, exploration that has completely changed the way humanity views the night sky,” said Shawn Domagal-Goldman, acting director, Astrophysics Division, NASA Headquarters in Washington. “Step by step, from discovery to characterization, NASA missions have built the foundation to answering a fundamental question: Are we alone? Now, with our upcoming Nancy Grace Roman Space Telescope and Habitable Worlds Observatory, America will lead the next giant leap, studying worlds like our own around stars like our Sun. This is American ingenuity, and a promise of discovery that unites us all.” The milestone comes 30 years after the first exoplanet was discovered around a star similar to our sun, in 1995. (Before that, a few planets had been identified around stars that had burned all their fuel and collapsed.) In fact, researchers think there are billions of planets in the Milky Way galaxy. But finding them remains a challenge. Scientists have discovered many individual planets with fascinating characteristics. In addition, as the total number of known exoplanets climbs, scientists can see how the general planet population compares to the planets of our own solar system.

Fewer than 100 exoplanets have been directly imaged. In fact, most planets are so faint they get lost in the light from their parent star. The other four methods of planet detection are indirect. For instance, with the transit method, astronomers look for a star to dim for a short period as an orbiting planet passes in front of it. While our solar system hosts an equal number of rocky and giant planets, rocky planets appear to be more common in the universe. Researchers have also found a range of planets entirely different from those in our solar system. There are Jupiter-size planets that orbit closer to their parent star than Mercury orbits the Sun; planets that orbit two stars, no stars, and dead stars; planets covered in lava; some with the density of Styrofoam; and others with clouds made of gemstones. “Each of the different types of planets we discover gives us information about the conditions under which planets can form and, ultimately, how common planets like Earth might be, and where we should be looking for them,” said Dawn Gelino, head of NASA’s Exoplanet Exploration Program (ExEP), located at the agency’s Jet Propulsion Laboratory in Southern California. “If we want to find out if we’re alone in the universe, all of this knowledge is essential.” 

The rate of exoplanet discoveries has accelerated in recent years. The database reached 5,000 confirmed exoplanets just three years ago. Moreover, this trend seems likely to continue. Kesseli and her colleagues anticipate receiving thousands of additional exoplanet candidates from the ESA (European Space Agency) Gaia mission. Gaia finds planets through a technique called astrometry. In addition, NASA’s upcoming Nancy Grace Roman Space Telescope will discover thousands of new exoplanets primarily through a technique called gravitational microlensing. At NASA, the future of exoplanet science will emphasize finding rocky planets similar to Earth and studying their atmospheres for biosignatures, any characteristic, element, molecule, substance, or feature that can be used as evidence of past or present life. NASA’s James Webb Space Telescope has already analysed the chemistry of over 100 exoplanet atmospheres. To account for the possibility that something other than an exoplanet is responsible for a particular signal, most exoplanet candidates must be confirmed by follow-up observations, often using an additional telescope, and that takes time. That’s why there is a long list of candidates in the NASA Exoplanet Archive (hosted by NExScI) waiting to be confirmed.

 

      

But studying the atmospheres of planets the size and temperature of Earth will require new technology. Specifically, scientists need better tools to block the glare of the star a planet orbits. And in the case of an Earth-like planet, the glare would be significant: The Sun is about 10 billion times brighter than Earth, which would be more than enough to drown out our home planet’s light if viewed by a distant observer. “We really need the whole community working together if we want to maximize our investments in these missions that are churning out exoplanets candidates,” said Aurora Kesseli, the deputy science lead for the NASA Exoplanet Archive at IPAC. “A big part of what we do at NExScI is build tools that help the community go out and turn candidate planets into confirmed planets.” Additional advances in coronagraph technology will be needed to build a coronagraph which can detect a planet like Earth. NASA is working on a concept for such a mission, currently named the Habitable Worlds Observatory.

NASA’s Exoplanet Exploration Program is responsible for implementing the agency’s plans for the discovery and understanding of planetary systems around nearby stars. It acts as a focal point for exoplanet science and technology and integrates cohesive strategies for future discoveries. NASA has two main initiatives to try overcoming the hurdles. The Roman telescope will carry a technology demonstration instrument called the Roman Coronagraph which will test new technologies for blocking starlight and making faint planets visible. At its peak performance, the coronagraph should be able to directly image a planet the size and temperature of Jupiter orbiting a star like our Sun, and at a similar distance from that star. With its microlensing survey and coronagraphic observations, Roman will reveal new details about the diversity of planetary systems, showing how common solar systems like our own may be across the galaxy. The science operations and analysis centre for ExEP is NExScI, based at IPAC, a science and data centre for astrophysics and planetary science at Caltech. JPL is managed by Caltech for NASA.