No evidence of phosphine in the atmosphere of Venus by independent   analyses

Geronimo Villanueva; Martin Cordiner; Patrick Irwin; Imke de Pater,; Bryan Butler; Mark Gurwell; Stefanie Milam; Conor Nixon; Statia Luszcz-Cook,; Colin Wilson; Vincent Kofman; Giuliano Liuzzi; Sara Faggi; Thomas Fauchez,; Manuela Lippi; Richard Cosentino; Alexander Thelen; Arielle Moullet; Paul; Hartogh; Edward Molter; Steve Charnley; Giada Arney; Avi Mandell; Nicolas; Biver; Ann Vandaele; Katherine de Kleer; Ravi Kopparapu

arXiv:2010.14305·astro-ph.EP·July 22, 2021

No evidence of phosphine in the atmosphere of Venus by independent analyses

Geronimo Villanueva, Martin Cordiner, Patrick Irwin, Imke de Pater,, Bryan Butler, Mark Gurwell, Stefanie Milam, Conor Nixon, Statia Luszcz-Cook,, Colin Wilson, Vincent Kofman, Giuliano Liuzzi, Sara Faggi, Thomas Fauchez,, Manuela Lippi, Richard Cosentino, Alexander Thelen

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TL;DR

This study independently reanalyzed spectroscopic data to search for phosphine in Venus's atmosphere, finding no evidence and setting upper limits that contradict earlier reports of its detection.

Contribution

It provides an independent reanalysis of existing data, identifying issues with previous interpretations and establishing more stringent upper limits for phosphine presence.

Findings

01

No detectable phosphine in Venus's atmosphere above 75 km

02

Spectroscopic data do not support previous phosphine detections

03

Established sensitive upper limits for phosphine abundance

Abstract

The detection of phosphine (PH3) in the atmosphere of Venus has been recently reported based on millimeter-wave radio observations (Greaves et al. 2020), and its re-analyses (Greaves et al. 2021a/b). In this Matters Arising we perform an independent reanalysis, identifying several issues in the interpretation of the spectroscopic data. As a result, we determine sensitive upper-limits for PH3 in Venus' atmosphere (>75 km, above the cloud decks) that are discrepant with the findings in G2020 and G2021a/b. The measurements target the fundamental first rotational transition of PH3 (J=1-0) at 266.944513 GHz, which was observed with the James Clerk Maxwell Telescope (JCMT) in June 2017 and with the Atacama Large Millimeter/submillimeter Array (ALMA) in March 2019. This line's center is near the SO2 (J=309,21-318,24) transition at 266.943329 GHz (only 1.3 km/s away from the PH3 line) which…

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