Venus

Venus Cloud Catcher As A Proof Of Concept Aerosol Collection Instrument

By Keith Cowing

Status Report

Science Reports via PubMed

December 8, 2024

Filed under aerosols, atmosphere, exoplanet, Sample Return, Science Reports via PubMed, Spectroscopy, Venus, Venus Cloud Catcher

Venus Cloud Catcher As A Proof Of Concept Aerosol Collection Instrument — The night side of Venus in thermal infrared. This false-color image uses data from the Japanese Akatsuki’s IR2 camera in two wavelengths, 1.74 and 2.26 microns. Darker regions denote thicker clouds. Changes in color can denote differences in cloud particle size or composition from place to place. Image credit: JAXA / ISAS / DARTS / Damia Bouic.

We report on the proof-of-concept of a low-mass, low-power method for collecting micron-sized sulfuric acid aerosols in bulk from the atmosphere of Venus. The collection method uses four wired meshes in a sandwich structure with a deposition area of 225 cm². It operates in two modes: passive and electrostatic.

During passive operation, aerosols are gathered on the deposition surface by aerodynamic force. During electrostatic operation, a tungsten needle discharges a high voltage of − 10 kV at the front of the grounded mesh structure. The discharge ionizes aerosols and attracts them to the mesh by Coulomb forces, resulting in improved efficiency and tentative attraction of submicron aerosols.

We describe the instrument construction and testing in the laboratory under controlled conditions with aerosols composed of 25%, 50%, 70%, 80%, 90% and 98%* concentration by volume of sulfuric acid, the rest water.

We demonstrated the following: (i) both modes of operation can collect the entire range of sulfuric acid solutions; (ii) the collection efficiency increases steadily (from a few percent for water to over 40% for concentrated sulfuric acid) with the increased concentration of sulfuric acid solution in water in both modes; (iii) the relative improvement in the collection of the electrostatic mode decreases as the sulfuric acid concentration increases.

We also demonstrated the operation of the instrument in the field, cloud particle collection on Mt. Washington, NH, and crater-rim fumaroles’ particle collection on Kīlauea volcano, HI. The collection rate in the field is wind-speed dependent, and we observed collection rates around 0.1 mlInline graphic in low wind environments (1–2 mInline graphic), and around 1 mlInline graphic in stronger wind (7–9 mInline graphic).

The VCC cloud collection setup. The setup is fully hand portable and designed for self-sufficient field operation. — Science Reports via PubMed

Venus cloud catcher as a proof of concept aerosol collection instrument, Science Reports via PubMed

Astrobiology

Keith Cowing

Explorers Club Fellow, ex-NASA Space Station Payload manager/space biologist, Away Teams, Journalist, Lapsed climber, Synaesthete, Na’Vi-Jedi-Freman-Buddhist-mix, ASL, Devon Island and Everest Base Camp veteran, (he/him) 🖖🏻

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