NASA Mars Ice Life Study: 50M Year Survival | AcademicJobs

A groundbreaking collaboration between NASA scientists and researchers at Penn State University has revealed that traces of ancient microbial life could endure in Martian ice for up to 50 million years, defying the harsh cosmic radiation on the Red Planet's surface. This discovery, detailed in a recent study published in the journal Astrobiology, suggests that future Mars missions should prioritize sampling pure water ice deposits rather than soil or rock, potentially unlocking evidence of past or even extant life. 52 51

The research simulates the relentless bombardment of galactic cosmic rays and solar radiation on organic molecules embedded in ice, mimicking conditions in Mars' polar caps and permafrost regions. Led by space scientist Alexander Pavlov from NASA Goddard Space Flight Center—who earned his PhD in geosciences from Penn State—and co-authored by Penn State Geosciences Professor Christopher H. House, the team exposed amino acids from Escherichia coli bacteria to gamma radiation in lab conditions replicating Mars' frigid temperatures of around -60°F (-51°C). Their findings challenge previous assumptions and open new avenues for astrobiology research at US universities collaborating with NASA. 105

This breakthrough not only heightens excitement for upcoming rover missions but also underscores the pivotal role of higher education institutions like Penn State in advancing planetary science. House, director of Penn State's Consortium for Planetary and Exoplanetary Science and Technology (CPEST), emphasizes that 'fifty million years is far greater than the expected age for some current surface ice deposits on Mars,' making these sites prime targets for biosignature detection. 52

To test biomolecule durability, the researchers created test tubes with pure water ice containing amino acids—the building blocks of proteins—from dead E. coli bacteria, as well as mixtures with Mars-like silicate sediments. These samples were frozen and irradiated using a gamma ray source at Penn State's Radiation Science and Engineering Center, equivalent to 20 million years of cosmic ray exposure on Mars' surface. An additional 30 million years was modeled computationally, totaling a staggering 50 million years. 51

The methodology involved:

• Suspending E. coli extracts or pure amino acids in ultra-pure water or sediment mixtures.
• Freezing samples to Martian permafrost temperatures (-60°F).
• Exposing to controlled gamma radiation doses simulating cosmic rays.
• Vacuum-sealing and transporting to NASA Goddard for high-precision analysis of surviving amino acids using liquid chromatography-mass spectrometry.

This rigorous approach revealed that pure ice acts as a superior shield, trapping destructive radiation products in place and preventing them from reaching organics—a phenomenon Pavlov attributes to the absence of a 'slippery film' formed at ice-mineral interfaces in dirty samples.Penn State News 52

Such experiments highlight the advanced facilities at US universities like Penn State, where interdisciplinary teams push the boundaries of astrobiology research essential for NASA's Mars Exploration Program.

The study's results were striking: in pure water ice, over 10% of amino acids remained intact after the simulated 50-million-year exposure, far exceeding the age of many Martian surface ice layers (often under 2 million years old). In contrast, sediment-mixed ice saw degradation 10 times faster, with virtually no survival. 105

This disparity arises because minerals in soil catalyze radiolytic breakdown, while pure ice immobilizes secondary radiation particles. Colder conditions, akin to those on Europa or Enceladus, further enhance preservation. House notes, 'That means if there are bacteria near the surface of Mars, future missions can find it.' 52

These findings validate targeting ice-dominated permafrost for missions, informing rover designs with drills like those on Phoenix (2008), which confirmed shallow ice at Mars' northern latitudes.

Penn State University stands at the forefront of US higher education in planetary science, thanks to leaders like Christopher H. House. As professor of geosciences and director of CPEST, House oversees an intercollege initiative uniting Earth sciences, engineering, and astronomy to tackle questions of planetary habitability. 104

CPEST integrates the Astrobiology Research Center (ARC), Center for Exoplanets and Habitable Worlds (CEHW), and Planetary Systems Science Center (PSSC), fostering research on Mars biosignatures, marsquakes revealing subsurface water, and carbon isotopes hinting at ancient life. Penn State's Radiation Science and Engineering Center provided critical irradiation facilities, exemplifying how university infrastructure supports NASA partnerships.CPEST Penn State

For students and faculty eyeing astrobiology, Penn State's programs offer hands-on opportunities in NASA's missions, from Perseverance to future ice-sampling rovers.

Photo by NASA on Unsplash

The study exemplifies seamless NASA-university synergy, with Pavlov (NASA Goddard, Penn State alum) bridging lab simulations and mission planning. Goddard's Astrobiology Analytical Laboratory analyzed samples, leveraging expertise in organic detection from OSIRIS-REx and Perseverance. 51

Funded by NASA's Planetary Science Division, this work informs sample return missions like Mars Sample Return (MSR), emphasizing ice as a 'frozen time capsule' for biosignatures. US universities like Penn State train the next generation for such endeavors, with postdocs and faculty securing NASA grants.

This research shifts mission strategies: prioritize polar ice caps and permafrost over sedimentary rocks. Rovers need enhanced drilling/scooping capabilities to access subsurface ice (centimeters to meters deep), avoiding contaminated layers. Pavlov recommends 'pure ice or ice-dominated regions' for extant life searches. 105

• Target Sites: Mid-latitudes permafrost, polar layered deposits.
• Instruments: Mass spectrometers for amino acid detection, drills like Phoenix's 0.5m reach.
• Missions: Enhanced Dragonfly (Titan analog), MSR follow-ons.

Success could confirm past habitability, revolutionizing astrobiology curricula at US colleges.

Beyond Penn State, US institutions drive astrobiology: Arizona State University's BS in Astrobiology, Cornell's minor, NASA's postdoc program. These programs equip students for NASA roles, with jobs in planetary protection, biosignature analysis.Explore research jobs in this field thrive amid Artemis and Mars pushes.

Penn State's CPEST exemplifies interdisciplinary training, preparing grads for postdoc positions at NASA centers or universities like Caltech, emphasizing lab-to-mission translation.

The study spotlights booming demand for astrobiologists. NASA Postdoctoral Program offers fellowships; universities seek geoscientists for ice core analysis analogs. Key paths:

• PhD in geosciences/astrobiology (e.g., Penn State).
• Postdocs at NASA Goddard/Ames.
• Faculty roles in planetary consortia.

Check career advice and university jobs for openings. STEM grads can pivot via certifications in remote sensing, radiation physics. 73

Photo by NASA on Unsplash

While promising, challenges persist: distinguishing biotic from abiotic organics, drilling tech limits, contamination risks. Future work: Europa/Enceladus analogs at colder temps, advanced spectrometers. US universities lead with grants like NASA's Astrobiology Institute.

Stakeholders: NASA, NSF, private firms like SpaceX seek talent trained at places like Penn State.

This NASA-Penn State study redefines Mars habitability searches, proving ice as life's vault. For aspiring researchers, it signals exciting careers bridging academia and NASA. Explore rate professors in astrobiology, higher ed jobs, career advice, and post jobs to join this quest. As House urges, pure ice holds Mars' secrets—US universities are unlocking them.NASA on Mars Ice Life