That said, microorganism research in the upper atmosphere has been active since the 1930s at least. One of the earliest flights involved Charles Lindbergh, a pilot best known for piloting the Atlantic solo in 1927. Accompanied with his wife, Lindbergh periodically passed the monoplane controls over to her to take samples from the atmosphere around them. The research team found spores of fungi and pollen grains, among other specimens.
Planes still require a substantial amount of atmosphere to fly, so it’s with high-altitude balloons and rockets that we can get even higher — to the stratosphere and the mesosphere. According to NASA microbial researcher David Smith, some of the pioneering work in this field was done in the 1970s, particularly in Europe and the Soviet Union. “Everything they did was fascinating, but there hasn’t been a lot of follow-up work to validate the results of those collections,” he told Seeker.
There are open questions about how valid these early results are, given that contamination protocols may not have been strict. So Smith and other researchers are trying to figure out what kind of microbes live above Earth, and for how long. In May and June, Smith’s team will fly with the team from NASA ABoVE (Arctic-Boreal Vulnerability Experiment), which uses a Gulfstream III jet to monitor how climate change affects animals, plants, the environment and infrastructure. In the spring, a vast airstream on the Pacific Ocean moves millions of tons of dust across the ocean, mostly from Asia.
“We want to know what kind of microorganisms are making that leap across the ocean, co-transported with aerosol species,” Smith said. “Alaska will allow us an opportunity to test the atmospheric bridge hypothesis, which simply speaking, is continents sneezing on each other.”
Smith’s team will use a cascade sampler for collection, which passes air through progressively finer impact plates with holes in them, he said. As the air moves through, dust and any microorganisms impact the surface of those plates. A portion of them stick to the surface, allowing researchers to analyze what is there afterwards.
In ultraviolet light (as seen here by the Venus Express mission), Venus has mysterious dark streaks that absorb UV radiation. Some researchers have suggested this could be life in the upper atmosphere, but more research is needed.
Smith is skeptical that microorganisms are growing or dividing at such high altitudes, because it’s so cold and dry up there. But he says that microorganisms may be “persisting”, or lingering and not being killed. “Nobody’s been able to measure how long microorganisms can stay in the stratosphere. There’s works that still needs to be done.”
“Virtually all terrestrial and marine surfaces have microorganisms associated with them that can get disattached from the surfaces by wind or other physical disturbances,” wrote Aarhus University assistant professor Tina Santl-Temkiv, who has studied
microorganisms in hailstones, in an e-mail to Seeker.
“[They] can reach higher levels of troposphere, above around one kilometer, can stay suspended in air for around a week and can travel thousands of kilometers, riding on wind currents. Eventually, they get deposited back to the ground wither through the formation of rain or simply due to gravity.”
If Earth’s atmosphere is shown to be a great spot for life to divide, however, it could have implications for locations such as Venus. Back in the 1960s, astronomer and science popularizer Carl Sagan suggested that the upper atmosphere of Venus could harbor the descendants of organisms that could have evolved on the surface of the planet when it was cooler.
Even though today the surface can crush and cook unprotected spacecraft, 50 kilometers (31 miles) above is more temperate. Moreover, researchers have found an intriguing substance that blocks ultraviolet light in Venus’ clouds. Life hasn’t yet been ruled out as a possibility.
“Venus and Earth were similar for 3 billion years [of their evolution] and perhaps as recently as up to about half a billion years ago,” said Dr. Lynn Rothschild, a NASA astrobiologist and synthetic biologist that is on Smith’s research team. She said this includes liquid oceans, similar atmosphere, and probably the same sorts of minerals and organic compounds as well.
But Venus would be a difficult prospect if the life returns to the surface. The sun got more luminous as the solar system aged, evaporating the water from Venus’ oceans. The water vapor, now in the atmosphere, contributed to giving Venus a hellish greenhouse effect on its surface.
It seems that life is hardy, but we don’t know if it’s tough enough to survive living high above a planetary surface. If it does, however, that could mean that even missions that sample a planet’s atmosphere could have to worry about protections against hurting possible life. We’ll have to see what these new experiments yield, though, before reaching any conclusions.