Tiny ocean wave vibrations hold Alaska climate secrets
Rod Boyce
907-474-7185
April 22, 2025
Tiny ocean wave vibrations from the Gulf of Alaska — too subtle for humans to notice — can travel through land as far north as Alaska’s Arctic coastline. These and other low-frequency vibrations generated daily by ocean waves offer insights into climate change.
Research by doctoral student Sebin John at the 51 Geophysical Institute shows a correlation between ocean waves and seismic signals recorded in the ground in Alaska. The signals are also strongly affected by sea ice.
A mid-latitude system swirls in the Gulf of Alaska on Nov. 12, 2019. These systems tend to form within the Aleutian Low, which is a semi-permanent breeding ground for some of Earth’s strongest storms.
John’s work was published April 2 in . Michael West, director of the at the Geophysical Institute, is a co-author.
The seismic signals, called microseisms, appear as continual background noise for seismologists focusing on earthquake data.
John finds them useful.
“There is a revival of a field called the environment of seismology,” John said. “It is using seismology to learn about climate change.”
Microseisms provide a long‐term record of meteorological, seasonal and climate influences, John writes in the research paper.
While numerous methods exist for tracking the evolution of phenomena driven by climate — such as ocean storms and sea ice — seismic noise is among the few that has captured second-by-second changes around the globe continuously over decades.
Analyzing microseismic activity provides an additional method of researching current and past storm trends, intensity and trajectories, as well as the dynamics of sea ice.
This image shows an ocean storm and the vibrations (microseisms) it produced at seismic stations in Alaska at 5 a.m. Nov. 29, 2019. The arrow points toward the direction of strongest vibration.
Microseisms come in three types of signals, each tied to a different oceanic process: primary, secondary and short-period secondary. John focused on secondary and short-period secondary waves.
Secondary microseisms are the strongest of the three and arise from the interaction of opposing wave systems in deeper water. These waves, called standing waves, oscillate vertically in place.
“Energy from standing waves gets transmitted through Earth as secondary microseisms many thousands of miles without substantial weakening,” John said.
The amount of energy from a standing wave varies by storm but generally creates several decibels of additional power for each few feet of wave height.
Short-period secondary microseisms are typically generated by shorter wind-driven waves near shore and don’t travel as far.
“We have modern instruments now, and our coverage across the globe has improved significantly, so we have a significant amount of data,” John said. “We have long-term data, and that’s important for studying the climate, and that’s where Alaska comes in. Alaska has a lot of seismic stations.”
Using data from 155 seismic stations spanning Alaska and western Canada, John looked for a correlation between storm and sea ice behavior and microseismic signals in six regions across the state.
John found that the Gulf of Alaska, with its strong storms and lack of ice, is the primary source of far-reaching secondary microseisms, which were recorded by sensors in each of his six designated regions.
He also found that sea ice suppresses short-period secondary signals.
These results show how seismic noise acts as a record of wave and ice action.
“What we are trying to do with this research is better understand environmental change through the use of seismology,” John said. “The Arctic is quite important in terms of climate change.”
ADDITIONAL CONTACT: Sebin John, sjohn19@alaska.edu
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