posted on 2024-08-29, 10:05authored byMartin Cordiner, Alexander Thelen, Thibault Cavalie, Richard Cosentino, Leigh FletcherLeigh Fletcher, Mark Gurwell, Katherine de Kleer, Yi-Jehng Kuan, Emmanuel Lellouch, Arielle Moullet, Conor Nixon, Imke de Pater, Nicholas Teanby, Bryan Butler, Steven Charnley, Stefanie Milam, Raphael Moreno, Mark Booth, Pamela Klaassen, Claudia Cicone, Tony Mroczkowski, Luca Di Mascolo, Doug Johnstone, Eelco van Kampen, Minju Lee, Daizhong Liu, Thomas Maccarone, Amelie Saintonge, Matthew Smith, Sven Wedemeyer
The study of planets and small bodies within our Solar System is fundamental for understanding the formation and evolution of the Earth and other planets. Compositional and meteorological studies of the giant planets provide a foundation for understanding the nature of the most commonly observed exoplanets, while spectroscopic observations of the atmospheres of terrestrial planets, moons, and comets provide insights into the past and present-day habitability of planetary environments, and the availability of the chemical ingredients for life. While prior and existing (sub)millimeter observations have led to major advances in these areas, progress is hindered by limitations in the dynamic range, spatial and temporal coverage, as well as sensitivity of existing telescopes and interferometers. Here, we summarize some of the key planetary science use cases that factor into the design of the Atacama Large Aperture Submillimeter Telescope (AtLAST), a proposed 50-m class single dish facility: (1) to more fully characterize planetary wind fields and atmospheric thermal structures, (2) to measure the compositions of icy moon atmospheres and plumes, (3) to obtain detections of new, astrobiologically relevant gases and perform isotopic surveys of comets, and (4) to perform synergistic, temporally-resolved measurements in support of dedicated interplanetary space missions. The improved spatial coverage (several arcminutes), resolution (~ 1.2′′ − 12′′), bandwidth (several tens of GHz), dynamic range (~ 105) and sensitivity (~ 1 mK km s−1) required by these science cases would enable new insights into the chemistry and physics of planetary environments, the origins of prebiotic molecules and the habitability of planetary systems in general.
Funding
This project has received funding from the European Union’s Horizon 2020 research and innovation programme under grant agreement No [951815](Towards an Atacama Large Aperture Submillimeter Telescope [AtLAST]).This work received support from NASA’s Solar System Obervations (SSO) Program, National Science Foundation (NSF) grant \#AST-2009253, NASA's Planetary Science Division Internal Scientist Funding Program through the Fundamental Laboratory Research work package (FLaRe), the UK Science and Technology Facilities Council grant ST/Y000676/1. LDM acknowledges support by the French government, through the UCA (J.E.D.I.) Investments in the Future project managed by the National Research Agency (ANR) with the reference number ANR-15-IDEX-01. ML acknowledges support from the European Union’s Horizon Europe research and innovation programme under the Marie Sklodowska-Curie grant agreement No 101107795. SW acknowledges support by the Research Council of Norway through the EMISSA project (project number 286853) and the Centres of Excellence scheme, project number 262622 ("Rosseland Centre for Solar Physics'').
History
Author affiliation
College of Science & Engineering
Physics & Astronomy