Virtual Planetary Laboratory

Last updated

Virtual Planetary Laboratory
AbbreviationVPL
Formation2001
Legal statusActive
PurposeTo detect exoplanetary habitability and their potential biosignatures.
Parent organization
 NASA
Website depts.washington.edu/naivpl

The Virtual Planetary Laboratory (VPL) is a virtual institute based at the University of Washington that studies how to detect exoplanetary habitability and their potential biosignatures. First formed in 2001, the VPL is part of the NASA Astrobiology Institute (NAI) and connects more than fifty researchers at twenty institutions together in an interdisciplinary effort. VPL is also part of the Nexus for Exoplanet System Science (NExSS) network, with principal investigator Victoria Meadows leading the NExSS VPL team. [1] [2]

Contents

Research

Task A: Solar System Analogs for Extrasolar Planet Observations

The first task considers observations of the Solar System planets, moons, and the asteroid belt to explore processes necessary for habitable environments and for exoplanet model confirmation. Specifically, observations of Europa, [3] Venus, [4] Earth, [5] Mars, and the asteroid belt have helped researchers in Task A address their goals.

Task B: The Earth Through Time

Our only data point of a habitable planet today is Earth, although it has not always been habitable. The Early Earth serves as an example of an exoplanet. The VPL research has contributed to the understanding of our early planet. Task B combines geological and biological data [6] with ecosystem [7] and photo-chemical models [8] [9] to showcase how planet Earth has changed throughout its history.

Task C: The Habitable Planet

This task uses observational data, models and orbital dynamics to explore the distribution of habitable worlds in the universe. The VPL team studies the effects of galactic, [10] stellar, [11] and planetary environments [12] on planetary habitability.

Task D: The Living Planet

Task D incorporates VPL researchers from diverse and interdisciplinary fields who use laboratory work [13] [14] combined with chemical and climate models to study the impact of life on its environment. In addition, the interactions between the biosphere, planet, and host star are explored to determine how they can influence detectable biosignatures. [15]

Task E: The Observer

In the final task, the VPL scientists observe the Solar System and extrasolar planets. The goal of this task is to develop astronomical [16] and remote-sensing retrieval methods. In addition, VPL members use telescope and instrument simulators to study which measurements, observing strategies, and analysis techniques are necessary for the characterization of exoplanets. [17]

Models

1D Radiative Convective and Photochemical Models

Solar Flux Model

Habitable Zone Calculator

Education & Outreach

Students

Teachers

VPL in the News

February 2017 - Early Earth as a proxy for hazy exoplanets

August 2016 - Is Proxima Centauri b habitable? [18] [19]

See also

Related Research Articles

<span class="mw-page-title-main">Astrobiology</span> Science concerned with life in the universe

Astrobiology is a scientific field within the life and environmental sciences that studies the origins, early evolution, distribution, and future of life in the universe by investigating its deterministic conditions and contingent events. As a discipline, astrobiology is founded on the premise that life may exist beyond Earth.

<span class="mw-page-title-main">Exoplanet</span> Planet outside the Solar System

An exoplanet or extrasolar planet is a planet outside the Solar System. The first possible evidence of an exoplanet was noted in 1917 but was not then recognized as such. The first confirmation of the detection occurred in 1992. A different planet, first detected in 1988, was confirmed in 2003. As of 1 March 2024, there are 5,640 confirmed exoplanets in 4,155 planetary systems, with 895 systems having more than one planet. The James Webb Space Telescope (JWST) is expected to discover more exoplanets, and to give more insight into their traits, such as their composition, environmental conditions, and potential for life.

Groombridge 1618 is a star in the northern constellation Ursa Major. With an apparent visual magnitude of +6.6, it lies at or below the threshold of stars visible to the naked eye for an average observer. It is relatively close to Earth, at 15.89 light-years (4.87 pc). This is a main sequence star of spectral type K7.5 Ve, having just 67% of the Sun's mass.

<span class="mw-page-title-main">Habitable zone</span> Orbits where planets may have liquid surface water

In astronomy and astrobiology, the habitable zone (HZ), or more precisely the circumstellar habitable zone (CHZ), is the range of orbits around a star within which a planetary surface can support liquid water given sufficient atmospheric pressure. The bounds of the HZ are based on Earth's position in the Solar System and the amount of radiant energy it receives from the Sun. Due to the importance of liquid water to Earth's biosphere, the nature of the HZ and the objects within it may be instrumental in determining the scope and distribution of planets capable of supporting Earth-like extraterrestrial life and intelligence.

A biosignature is any substance – such as an element, isotope, molecule, or phenomenon – that provides scientific evidence of past or present life on a planet. Measurable attributes of life include its complex physical or chemical structures, its use of free energy, and the production of biomass and wastes.

<span class="mw-page-title-main">Planetary habitability</span> Known extent to which a planet is suitable for life

Planetary habitability is the measure of a planet's or a natural satellite's potential to develop and maintain environments hospitable to life. Life may be generated directly on a planet or satellite endogenously or be transferred to it from another body, through a hypothetical process known as panspermia. Environments do not need to contain life to be considered habitable nor are accepted habitable zones (HZ) the only areas in which life might arise.

The anti-greenhouse effect is a process that occurs when energy from a celestial object's sun is absorbed or scattered by the object's upper atmosphere, preventing that energy from reaching the surface, which results in surface cooling – the opposite of the greenhouse effect. In an ideal case where the upper atmosphere absorbs all sunlight and is nearly transparent to infrared (heat) energy from the surface, the surface temperature would be reduced by 16%, which is a significant amount of cooling.

<span class="mw-page-title-main">Ocean world</span> Planet containing a significant amount of water or other liquid

An ocean world, ocean planet, panthalassic planet, maritime world, water world or aquaplanet, is a type of planet that contains a substantial amount of water in the form of oceans, as part of its hydrosphere, either beneath the surface, as subsurface oceans, or on the surface, potentially submerging all dry land. The term ocean world is also used sometimes for astronomical bodies with an ocean composed of a different fluid or thalassogen, such as lava, ammonia or hydrocarbons. The study of extraterrestrial oceans is referred to as planetary oceanography.

<span class="mw-page-title-main">Habitability of natural satellites</span> Measure of the potential of natural satellites to have environments hospitable to life

The habitability of natural satellites is the potential of moons to provide habitats for life, though it is not an indicator that they harbor it. Natural satellites are expected to outnumber planets by a large margin and the study of their habitability is therefore important to astrobiology and the search for extraterrestrial life. There are, nevertheless, significant environmental variables specific to moons.

<span class="mw-page-title-main">Earth Similarity Index</span> Scale for how similar a planet is to earth

The Earth Similarity Index (ESI) is a proposed characterization of how similar a planetary-mass object or natural satellite is to Earth. It was designed to be a scale from zero to one, with Earth having a value of one; this is meant to simplify planet comparisons from large databases.

<span class="mw-page-title-main">Kepler-62f</span> Super-Earth orbiting Kepler-62

Kepler-62f is a super-Earth exoplanet orbiting within the habitable zone of the star Kepler-62, the outermost of five such planets discovered around the star by NASA's Kepler spacecraft. It is located about 980 light-years from Earth in the constellation of Lyra.

<span class="mw-page-title-main">Habitability of red dwarf systems</span> Possible factors for life around red dwarf stars

The theorized habitability of red dwarf systems is determined by a large number of factors. Modern evidence indicates that planets in red dwarf systems are unlikely to be habitable, due to their low stellar flux, high probability of tidal locking and thus likely lack of magnetospheres and atmospheres, small circumstellar habitable zones and the high stellar variation experienced by planets of red dwarf stars. However, the sheer numbers and longevity of red dwarfs could provide ample opportunity to realize any small possibility of habitability.

HD 219134 g, also known as HR 8832 g, is an unconfirmed exoplanet orbiting around the K-type star HD 219134 in the constellation of Cassiopeia. It has a minimum mass of 11 or 15 Earth masses, suggesting that it is likely a Neptune-like ice giant. Unlike HD 219134 b and HD 219134 c it is not observed to transit and thus its radius and density are unknown. If it has an Earth-like composition, it would have a radius 1.9 times that of Earth. However, since it is probably a Neptune-like planet, it is likely larger.

David C. Catling is a Professor in Earth and Space Sciences at the University of Washington. He is a planetary scientist and astrobiologist whose research focuses on understanding the differences between the evolution of planets, their atmospheres, and their potential for life. He has participated in NASA's Mars exploration program and contributed research to help find life elsewhere in the solar system and on planets orbiting other stars. He is also known for his work on the evolution of Earth's atmosphere and biosphere, including how Earth's atmosphere became rich in oxygen, allowing complex life to evolve, and conditions conducive to the origin of life.

<span class="mw-page-title-main">TRAPPIST-1</span> Ultra-cool red dwarf star in the constellation Aquarius

TRAPPIST-1 is a cool red dwarf star with seven known exoplanets. It lies in the constellation Aquarius about 40.66 light-years away from Earth, and has a surface temperature of about 2,566 K. Its radius is slightly larger than Jupiter and it has a mass of about 9% of the Sun. It is estimated to be 7.6 billion years old, making it older than the Solar System. The discovery of the star was first published in 2000.

<span class="mw-page-title-main">Shawn Domagal-Goldman</span>

Shawn D. Domagal-Goldman is a research space scientist at NASA Goddard Space Flight Center, who specializes in exoplanets, Archean geochemistry, planetary atmospheres, and astrobiology.

<span class="mw-page-title-main">Proxima Centauri b</span> Terrestrial planet orbiting Proxima Centauri

Proxima Centauri b, sometimes referred to as Alpha Centauri Cb, is an exoplanet orbiting within the habitable zone of the red dwarf star Proxima Centauri, which is the closest star to the Sun and part of the larger triple star system Alpha Centauri. It is about 4.2 light-years from Earth in the constellation Centaurus, making it and Proxima d, along with the currently disputed Proxima c, the closest known exoplanets to the Solar System.

<span class="mw-page-title-main">Habitable Exoplanets Observatory</span> Proposed space observatory to characterize exoplanets atmospheres

The Habitable Exoplanet Observatory (HabEx) is a space telescope concept that would be optimized to search for and image Earth-size habitable exoplanets in the habitable zones of their stars, where liquid water can exist. HabEx would aim to understand how common terrestrial worlds beyond the Solar System may be and determine the range of their characteristics. It would be an optical, UV and infrared telescope that would also use spectrographs to study planetary atmospheres and eclipse starlight with either an internal coronagraph or an external starshade.

<span class="mw-page-title-main">Detecting Earth from distant star-based systems</span> Detecting Earth as an exoplanet

There are several methods currently used by astronomers to detect distant exoplanets from Earth. Theoretically, some of these methods can be used to detect Earth as an exoplanet from distant star systems.

<span class="mw-page-title-main">Exoplanet interiors</span> Exoplanet internal structure

Over the years, our ability to detect, confirm, and characterize exoplanets and their atmospheres has improved, allowing researchers to begin constraining exoplanet interior composition and structure. While most exoplanet science is focused on exoplanetary atmospheric environments, the mass and radius of a planet can tell us about a planet's density, and hence, its internal processes. The internal processes of a planet are partly responsible for its atmosphere, and so they are also a determining factor in a planet's capacity to support life.

References

  1. Impey, Chris (2010). Talking about Life: Conversations on Astrobiology. Cambridge University Press. pp. 293-302. ISBN   9781139490634.
  2. Kelley, Peter (April 22, 2015). "UW key player in new NASA coalition to search for life on distant worlds." UW News. Retrieved May 4, 2015.
  3. Robinson, Tyler D. (January 1, 2011). "Modeling the Infrared Spectrum of the Earth-Moon System: Implications for the Detection and Characterization of Earthlike Extrasolar Planets and Their Moonlike Companions". The Astrophysical Journal. 741 (1): 51. arXiv: 1110.3744 . Bibcode:2011ApJ...741...51R. doi:10.1088/0004-637X/741/1/51. S2CID   119281936 via Institute of Physics.
  4. Arney, Giada; Meadows, Victoria; Crisp, David; Schmidt, Sarah J.; Bailey, Jeremy; Robinson, Tyler (August 1, 2014). "Spatially resolved measurements of H2O, HCl, CO, OCS, SO2, cloud opacity, and acid concentration in the Venus near-infrared spectral windows". Journal of Geophysical Research: Planets. 119 (8): 2014JE004662. Bibcode:2014JGRE..119.1860A. doi: 10.1002/2014JE004662 .
  5. Robinson, Tyler D.; Meadows, Victoria S.; Crisp, David; Deming, Drake; A'Hearn, Michael F.; Charbonneau, David; Livengood, Timothy A.; Seager, Sara; Barry, Richard K.; Hearty, Thomas; Hewagama, Tilak; Lisse, Carey M.; McFadden, Lucy A.; Wellnitz, Dennis D. (2011). "Earth as an Extrasolar Planet: Earth Model Validation Using EPOXI Earth Observations". Astrobiology. 11 (5): 393–408. Bibcode:2011AsBio..11..393R. doi:10.1089/ast.2011.0642. PMC   3133830 . PMID   21631250.
  6. Claire, M. W.; Catling, D. C.; Zahnle, K. J. (December 1, 2006). "Biogeochemical modelling of the rise in atmospheric oxygen". Geobiology. 4 (4): 239–269. Bibcode:2006Gbio....4..239C. doi:10.1111/j.1472-4669.2006.00084.x. S2CID   11575334.
  7. Roberson, A. L.; Roadt, J.; Halevy, I.; Kasting, J. F. (July 1, 2011). "Greenhouse warming by nitrous oxide and methane in the Proterozoic Eon". Geobiology. 9 (4): 313–320. Bibcode:2011Gbio....9..313R. doi:10.1111/j.1472-4669.2011.00286.x. PMID   21682839. S2CID   8426873.
  8. Zerkle, Aubrey L.; Claire, Mark W.; Domagal-Goldman, Shawn D.; Farquhar, James; Poulton, Simon W. (May 1, 2012). "A bistable organic-rich atmosphere on the Neoarchaean Earth". Nature Geoscience. 5 (5): 359–363. Bibcode:2012NatGe...5..359Z. doi:10.1038/ngeo1425.
  9. Claire, Mark W.; Kasting, James F.; Domagal-Goldman, Shawn D.; Stüeken, Eva E.; Buick, Roger; Meadows, Victoria S. (September 15, 2014). "Modeling the signature of sulfur mass-independent fractionation produced in the Archean atmosphere" (PDF). Geochimica et Cosmochimica Acta. 141: 365–380. Bibcode:2014GeCoA.141..365C. doi: 10.1016/j.gca.2014.06.032 .
  10. Kaib, Nathan A.; Raymond, Sean N.; Duncan, Martin (January 17, 2013). "Planetary system disruption by Galactic perturbations to wide binary stars". Nature. 493 (7432): 381–384. arXiv: 1301.3145 . Bibcode:2013Natur.493..381K. CiteSeerX   10.1.1.765.6816 . doi:10.1038/nature11780. PMID   23292514. S2CID   4303714.
  11. Segura, Antígona; Walkowicz, Lucianne M.; Meadows, Victoria; Kasting, James; Hawley, Suzanne (September 1, 2010). "The Effect of a Strong Stellar Flare on the Atmospheric Chemistry of an Earth-like Planet Orbiting an M Dwarf". Astrobiology. 10 (7): 751–771. arXiv: 1006.0022 . Bibcode:2010AsBio..10..751S. doi:10.1089/ast.2009.0376. PMC   3103837 . PMID   20879863.
  12. Kopparapu, R. K.; Raymond, S. N.; Barnes, R. (2009). "Stability of Additional Planets in and Around the Habitable Zone of the HD 47186 Planetary System". The Astrophysical Journal Letters. 695 (2): L181–L184. arXiv: 0903.3597 . Bibcode:2009ApJ...695L.181K. doi:10.1088/0004-637x/695/2/l181. S2CID   17136043.
  13. Anderson, Rika E.; Sogin, Mitchell L.; Baross, John A. (January 1, 2015). "Biogeography and ecology of the rare and abundant microbial lineages in deep-sea hydrothermal vents". FEMS Microbiology Ecology. 91 (1): 1–11. doi: 10.1093/femsec/fiu016 . hdl: 1912/7205 . PMID   25764538.
  14. Breitbart, Mya; Hoare, Ana; Nitti, Anthony; Siefert, Janet; Haynes, Matthew; Dinsdale, Elizabeth; Edwards, Robert; Souza, Valeria; Rohwer, Forest; Hollander, David (January 1, 2009). "Metagenomic and stable isotopic analyses of modern freshwater microbialites in Cuatro Ciénegas, Mexico". Environmental Microbiology. 11 (1): 16–34. Bibcode:2009EnvMi..11...16B. doi:10.1111/j.1462-2920.2008.01725.x. PMID   18764874.
  15. Domagal-Goldman, Shawn D.; Meadows, Victoria S.; Claire, Mark W.; Kasting, James F. (June 1, 2011). "Using biogenic sulfur gases as remotely detectable biosignatures on anoxic planets". Astrobiology. 11 (5): 419–441. Bibcode:2011AsBio..11..419D. doi:10.1089/ast.2010.0509. PMC   3133782 . PMID   21663401.
  16. Schwieterman, Edward W.; Meadows, Victoria S.; Domagal-Goldman, Shawn D.; Deming, Drake; Arney, Giada N.; Luger, Rodrigo; Harman, Chester E.; Misra, Amit; Barnes, Rory (January 1, 2016). "Identifying Planetary Biosignature Impostors: Spectral Features of CO and O4 Resulting from Abiotic O2/O3 Production". The Astrophysical Journal Letters. 819 (1): L13. arXiv: 1602.05584 . Bibcode:2016ApJ...819L..13S. doi: 10.3847/2041-8205/819/1/L13 . PMC   6108182 . PMID   30147857.
  17. Luger, Rodrigo; et al. (March 12, 2017). "A terrestrial-sized exoplanet at the snow line of TRAPPIST-1". Nature Astronomy. 1 (6): 0129. arXiv: 1703.04166 . Bibcode:2017NatAs...1E.129L. doi:10.1038/s41550-017-0129. S2CID   54770728.
  18. Meadows, V. S.; Arney, G. N.; Schwieterman, E. W.; Lustig-Yaeger, J.; Lincowski, A. P.; Robinson, T.; Domagal-Goldman, S. D.; Deitrick, R.; Barnes, R. K.; Fleming, D. P.; Luger, R.; Driscoll, P. E.; Quinn, T. R.; Crisp, D.; et al. (August 30, 2016). "The Habitability of Proxima Centauri b: II: Environmental States and Observational Discriminants". Astrobiology. 18 (2): 133–189. arXiv: 1608.08620 . Bibcode:2018AsBio..18..133M. doi:10.1089/ast.2016.1589. PMC   5820795 . PMID   29431479.
  19. Barnes, Rory; et al. (August 24, 2016). "The Habitability of Proxima Centauri b I: Evolutionary Scenarios". arXiv: 1608.06919 [astro-ph.EP].
This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.