What are the responsibilities and job description for the Exploring the Astrobiology and Organic Chemistry Potential of Enceladus, Europa, Titan and/or Mars position at Zintellect?
About the NASA Postdoctoral Program
The NASA Postdoctoral Program (NPP) offers unique research opportunities to highly-talented scientists to engage in ongoing NASA research projects at a NASA Center, NASA Headquarters, or at a NASA-affiliated research institute. These one- to three-year fellowships are competitive and are designed to advance NASA’s missions in space science, Earth science, aeronautics, space operations, exploration systems, and astrobiology.
Description:
The search for biosignatures and interesting organic chemistry throughout the solar system has accelerated with recent advancements in laboratory techniques, and the current and future discoveries by missions such as Cassini and Europa Clipper. Our group's research in the Planetary Science Section at JPL focuses on groundbreaking, largely laboratory-based work to help interpret measurements made by these and other missions, as well as deepen our understanding of the organic chemistry and potential biochemistry occurring on these planetary bodies.
Current funded research focuses on hypervelocity impacts of ice grains for Enceladus and/or Europa. Ocean worlds such as Enceladus and Europa represent high-priority targets for astrobiology-focused missions. Cassini demonstrated the detection of salts and organics in hypervelocity plume flythroughs using impact ionization mass spectrometry with its Cosmic Dust Analyzer (CDA) instrument, and current and future payloads under development could search for biosignatures in plume and ejected particles with the same technique. However, until recently no equivalent laboratory measurements have reproduced the physics of an ice grain impact onto a spaceborne dust detector such as CDA or Europa Clipper’s Surface DUst Analyzer (SUDA) instrument using relevant compositions. At JPL/Caltech we have a new experimental system called the Hypervelocity Ice grain Impact Validation Experiment (HIIVE) that more closely replicates the hypervelocity sampling process, and will set the standard for SUDA data interpretation by establishing a direct link between the observed mass spectra and ice grain composition. Current HIIVE experiments involve generating a mass spectral library of various salt and organic mixtures in ice grains for the SUDA instrument, and generating hypervelocity ice grain impacts of microbes for the first time to test whether organisms from different habitats in Ocean World analogue environments will generate chemically distinct fatty acid fingerprints when analyzed via impact ionization mass spectrometry. Project proposals are invited that might explore novel ways that our HIIVE ice grain accelerator instrument could be utilized, not only to trace back impact mass spectra to the composition of ice grains, but also whether impacts can generate new compounds if the impacted surface has a contamination layer or coating to replicate a planetary surface. Proposals may also investigate how the presence of mineral dust affects impact ionization, or how biological signals are expressed in the impact mass spectra and how they are affected by the impact velocity.
Field of Science: Astrobiology
Advisor:
Bryana Henderson
Bryana.L.Henderson@jpl.nasa.gov
(818) 354-2416
This opportunity may require the following: 1- Mandatory drug testing; 2-Random drug testing; 3- Testing prior to initiation of fellowship appointment.
Questions about this opportunity? Please email npp@orau.org