Broad Implications – Harvard Scientists Have Discovered the First Ever Sea Level Fingerprint

The work validates almost a century of sea level science.

Sea levels experience a bizarre and counterintuitive phenomenon as ice sheets melt.

It functions much like a seesaw. Ocean levels drop in the vicinity of where these glacial ice masses melt. They do, however, rise thousands of miles away. This is primarily caused by the lack of a gravitational pull toward the ice sheet, which causes the water to disperse. Since each glacier or ice sheet that is melting has a different effect on sea level, the patterns have come to be known as “sea level fingerprints.” Modern sea level science has been built around elements of the notion, which is at the heart of the understanding that global sea levels don’t increase uniformly. It has been around for more than a century. But the commonly accepted concept has long had a problem. Researchers have never definitely found a sea level fingerprint.

A team of scientists, including Harvard University geophysicist Jerry X. Mitrovica and Harvard alumna Sophie Coulson, think they have found the first. A new study that was recently published in the journal Science describes their findings. The findings validate over a century of sea level research and assist to strengthen confidence in models that anticipate future sea level rise.

“Ocean level projections, urban and coastal planning — all of it — has been built on the idea of fingerprints,” said Mitrovica, the Frank B. Baird Jr. Professor of Science in the Department of Earth and Planetary Sciences. “That’s why fingerprints are so important. They allow you to estimate what the geometry of the sea level changes is going to be like… so we now have much more confidence in how sea level changes are going to evolve…. If fingerprint physics wasn’t correct, then we’d have to rethink all modern sea level research.”

Sea level fingerprints have been notoriously difficult to detect because of the major fluctuations in ocean levels brought on by changing tides, currents, and winds. What makes it such a conundrum is that researchers are trying to detect millimeter-level motions of the water and link them to melting glaciers thousands of miles away.

Mitrovica compared the search to the one for the subatomic particle the Higgs Boson.

“Almost all physicists thought that the Higgs existed, but it was nevertheless a transformative accomplishment when it was firmly detected,” Mitrovica said. “In sea level physics, almost everyone assumed that the fingerprints existed, but they had never been detected at a comparable level of confidence.”

The new study uses newly released satellite data from a European marine monitoring agency that captures over 30 years of observations in the vicinity of the Greenland Ice Sheet and much of the ocean close to the middle of Greenland to capture the seesaw in ocean levels from the fingerprint.

The satellite data caught the eye of Mitrovica and colleague David Sandwell of the Scripps Institute of Oceanography. Typically, satellite records from this region had only extended up to the southern tip of Greenland, but in this new release, the data reached ten degrees higher in latitude, allowing them to eyeball a potential hint of the seesaw caused by the fingerprint.

Mitrovica quickly turned to Coulson, a former Ph.D. student in Mitrovica’s lab and now a postdoctoral fellow at Los Alamos National Laboratory, to verify if this was truly the fingerprint signal sea level scientists had been chasing for decades.