A new generation of detectors let scientists identify a dozen large episodes of bioluminescence, one a hundred times larger than Manhattan — and that’s the smallest.

The ocean has always glowed.

The Greeks and Romans knew of luminous sea creatures as well as the more general phenomenon of seawater that can light up in bluish-green colors.

Charles Darwin, as he sailed near South America on a dark night aboard the H.M.S. Beagle, encountered luminescent waves. He called it “a wonderful and most beautiful spectacle.” As far as the eye could see, he added, “the crest of every wave was bright” — so much so that the “livid flames” lit the sky.

Now, scientists report that ocean bioluminescence can be so intense and massive in scale that satellites orbiting five hundred miles high can see glowing mats of microorganisms as they materialize in the seas. Last month in the journal Scientific Reports, eight investigators told of finding a luminous patch south of Java in 2019 that grew to be larger than the combined areas of Vermont, New Hampshire, Massachusetts, Rhode Island and Connecticut.

“It was an epiphany,” said Steven D. Miller, lead author on the bioluminescence study and a specialist in satellite observations at Colorado State University. When a hidden wonder of nature comes to light, he added, “it captures your imagination.”

The scientists said the close examination of images gathered between December 2012 and March 2021 from a pair of satellites let them identify a dozen extremely large events — approximately one every eight months. Even the smallest was a hundred times larger than Manhattan.

The imagery is opening a new window on the world’s oceans, scientists say, and promises to aid the tracking and study of the glowing seas, whose origins are poorly understood.

Kenneth H. Nealson, a pioneer of bioluminescence research at the University of Southern California, called the discovery “a big step toward being able to understand” how an enduring mystery of the sea “actually comes to be.”

Bioluminescent plankton lighting up the shoreline of Dockweiler State Beach in Los Angeles in 2020. The glowing seas observed by the satellites appear to be the work of trillions of microscopic bacteria.

The new paper noted that the large concentrations of living lights have long “eluded rigorous scientific inquiry, and thus little is known about their composition, formation mechanism, and role within the marine ecosystem.”

Sea bioluminescence is often associated with gruesome creatures of the inky deep. One iconic illuminator is the anglerfish, which dangles bright lures in front of needlelike teeth. In contrast, the luminous seas appear to originate when many trillions of tiny bacteria light up in unison.

Dr. Nealson, who was not involved in the satellite research, and colleagues reported in 1970 that dilute suspensions of a particular type of bacteria emit no gleam. If allowed to multiply, however, the microbes can suddenly light up as if a switch were thrown. Scientists now theorize that the glittering masses of bacteria lure fish, whose guts provide nourishing habitats.

Dr. Miller’s trail of discovery began nearly two decades ago when a lunchtime chat raised the question of whether sea bioluminescence might be visible from space. While working at the U.S. Naval Research Laboratory in Monterey, Calif., in 2004, he began examining imagery from a weather satellite. Soon, he spotted in the northwestern Indian Ocean what turned out to be a glowing patch that was nearly the size of Connecticut.

The blurry area was barely visible, but Dr. Miller and his colleagues grew quite excited because they knew that a new generation of satellite sensors would soon provide much greater sensitivity and sharpness. The improved sensors debuted on a pair of satellites launched by the National Oceanic and Atmospheric Administration in 2011 and 2017.

A surprise, Dr. Miller said, is that the events turn out to persist for long periods. For instance, the large patch off Java in 2019 lasted for at least 45 nights. That raises the possibility that a rapid response team of oceanographers might have enough time to reach the patches and take samples for detailed studies.

To date, Dr. Miller said, no team has succeeded. He added that television companies that make nature documentaries have shown interest in using the satellite detections to track down and film the gleaming seas.

Peter Herring, a British marine biologist known for his work on deep bioluminescence, called the satellite work important because, after ages of uncertainty, it raised the prospect of finally coming up with hard evidence of what powers the luminous whorls.

The discovery, he added, “is a large splash and will have significant ripples.”

Source New York times

By Arsalan Ahmad

Arsalan Ahmad is a Research Engineer working on 2-D Materials, graduated from the Institute of Advanced Materials, Bahaudin Zakariya University Multan, Pakistan.LinkedIn: https://www.linkedin.com/in/arsalanahmad-materialsresearchengr/