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Home » Ontdekking van lachgas in de ruimte kan buitenaards leven betekenen

Ontdekking van lachgas in de ruimte kan buitenaards leven betekenen

    Ontdekking van lachgas in de ruimte kan buitenaards leven betekenen
    TRAPPIST-1 systeem

    Het TRAPPIST-1-systeem, waar we binnenkort misschien meer informatie zullen hebben over de atmosferen van rotsachtige, aardachtige planeten van de James Webb Space Telescope. Het is mogelijk dat de atmosfeer lachgas bevat, wat op leven kan duiden. Krediet: NASA en JPL/Caltech

    Exoplaneetjagers moeten controleren op lachgas – een mogelijke biosignatuur.

    Volgens wetenschappers van de University of California, Riverside (UCR) ontbreekt er iets in de typische lijst van chemicaliën die astrobiologen gebruiken om te zoeken naar leven op planeten rond andere sterren. Namelijk lachgas, ook wel bekend als[{” attribute=””>nitrous oxide (N2O).

    Called chemical biosignatures, compounds in a planet’s atmosphere that could indicate life typically include gases found in abundance in Earth’s atmosphere today.

    Nitrous Oxide Laughing Gas Dentist

    The same nitrous oxide gas used for general anesthesia, sedation, and pain treatment could make a viable biosignature gas.

    “There’s been a lot of thought put into oxygen and methane as biosignatures. Fewer researchers have seriously considered nitrous oxide, but we think that may be a mistake,” said Eddie Schwieterman, an astrobiologist in UCR’s Department of Earth and Planetary Sciences.

    This conclusion, and the modeling work that led to it, are detailed in an article published in the Astrophysical Journal on October 4, 2022.

    A biosignature is any characteristic, element, molecule, substance, or feature that can be used as evidence for past or present life. It can be something like a leaf or a feather, but could also be fossils stored away in the rocks, organic molecules made by life, and even differences in the chemistry of an atmosphere or a body of water. Chemical biosignatures include a huge range of possible ways that life can leave its mark within the chemistry of rocks, bodies of water, and even atmospheres.

    To reach this conclusion, Schwieterman led a team of scientists that calculated how much nitrous oxide living things on a planet similar to Earth could possibly produce. After that, they constructed models simulating that planet around different kinds of stars and calculated the quantities of N2O that could be detected by an observatory like the James Webb Space Telescope.

    “In a star system like TRAPPIST-1, the nearest and best system to observe the atmospheres of rocky planets, you could potentially detect nitrous oxide at levels comparable to CO2 or methane,” Schwieterman said.

    There are multiple ways that living things can produce nitrous oxide. For example, microorganisms are constantly transforming other nitrogen compounds into N2O, a metabolic process that can yield useful cellular energy.

    “Life generates nitrogen waste products that are converted by some microorganisms into nitrates. In a fish tank, these nitrates build-up, which is why you have to change the water,” Schwieterman said.

    “However, under the right conditions in the ocean, certain bacteria can convert those nitrates into N2O,” Schwieterman said. “The gas then leaks into the atmosphere.”

    Earthrise From Moon NASA Lunar Reconnaissance Orbiter

    Nitrous oxide is a constituent of Earth’s atmosphere that provides evidence of life. This image is a view of Earth from the moon that was captured by NASA’s Lunar Reconnaissance Orbiter (LRO). Credit: NASA/Goddard/Arizona State University

    Under certain circumstances, nitrous oxide could be detected in an atmosphere and still not indicate life. This was accounted for by Schwieterman’s team in their modeling. For example, a small amount of nitrous oxide is created by lightning. But alongside N2O, lightning also creates nitrogen dioxide, which would offer astrobiologists a clue that non-living weather or geological processes created the N2O.

    Other astrobiologists who have considered nitrous oxide as a biosignature gas often conclude it would be difficult to detect from so far away. Schwieterman explained that this conclusion is based on N2O concentrations in Earth’s atmosphere today. Because there isn’t very much of it on this planet, which is teeming with life, some people believe it would also be hard to detect elsewhere.

    “This conclusion doesn’t account for periods in Earth’s history where ocean conditions would have allowed for much greater biological release of N2O. Conditions in those periods might mirror where an exoplanet is today,” Schwieterman said.

    The James Webb Space Telescope

    The James Webb Space Telescope could soon send information about the atmospheres of planets in the TRAPPIST-1 system. Credit: Northrup Grumman

    Schwieterman added that common stars like K and M dwarfs produce a light spectrum that is less effective at breaking up the N2O molecule than our sun is. These two effects combined could greatly increase the predicted amount of this biosignature gas on an inhabited world, which would make it much easier to detect.

    According to the team of researchers, now is the time for astrobiologists to consider alternative biosignature gases like nitrous oxide because the James Webb telescope may soon be sending information about the atmospheres of rocky, Earth-like planets in the TRAPPIST-1 system.

    “We wanted to put this idea forward to show it’s not out of the question we’d find this biosignature gas, if we look for it,” Schwieterman said.

    Reference: “Evaluating the Plausible Range of N2O Biosignatures on Exo-Earths: An Integrated Biogeochemical, Photochemical, and Spectral Modeling Approach” by Edward W. Schwieterman, Stephanie L. Olson, Daria Pidhorodetska, Christopher T. Reinhard, Ainsley Ganti, Thomas J. Fauchez, Sandra T. Bastelberger, Jaime S. Crouse, Andy Ridgwell and Timothy W. Lyons, 4 October 2022, The Astrophysical Journal.
    DOI: 10.3847/1538-4357/ac8cfb

    The research team included UCR astrobiologists Daria Pidhorodetska, Andy Ridgwell, and Timothy Lyons, as well as scientists from Purdue University, the Georgia Institute of Technology, American University, and the NASA Goddard Space Flight Center.