Bringing the Bubbles Home

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As our cruise ends, lead scientist Amanda Demopoulos brings it all together and charts the path forward

As the R/V Falkor passes Cape Disappointment back into the mouth of the Columbia River, with Astoria rising in the background, I reflect back on our 21 days at sea. And what comes back to me the most is I never knew there was so much that can be studied about bubbles.

Image shows a woman unloading equipment from an ROV

USGS scientist Amanda Demopoulos, lead scientist for this expedition, unloads several push cores taken from the sediment at the ocean floor by ROV SuBastian.

(Credit: Shelton Du Preez, Schmidt Ocean Institute. Courtesy of Schmidt Ocean Institute)

I’ve studied animals at seeps on most of the United States continental margins and looked at meiofauna to the megafauna. It had never occurred to me that there were scientists out there doing the same for bubbles. But thanks to the work of USGS, Schmidt Ocean Institute, and our partners at the British Geological Survey, GEOMAR, and the University of North Carolina-Chapel Hill, I’m getting to see just how much can be done with these bubbles.

Seep Science to Scale

We have really done something impressive here with these seeps. It is pretty rare that a group of scientists can combine so many disciplines to study this specific type of environment in so many ways.

Image shows a line of women in a lab holding equipment

Just a sampling of the scientists and equipment of this expedition into methane seeps on the Cascadia Margin

From Left to Right: USGS biologist Jennie McClain-Counts, USGS benthic ecologist Amanda Demopoulos, British Geological Survey geologist Diana Sahy, OSU/NOAA marine geochemist Tamara Baumberger, CCU graduate student Charlotte Kollman, USGS/NAGT intern Penny McCowen, and USGS research oceanographer Nancy Prouty.

(Credit: Shelton Du Preez, Schmidt Ocean Institute. Courtesy of Schmidt Ocean Institute)

We’ve got Bill and the Falkor mapping all of these bubble plumes from the seeps. Diana and Nancy are looking at what made the seeps and how the seeps then make the rocks that surround them. Jens and Tim are quantifying how much methane is coming out and where it’s going. Tamara is looking at the methane itself, what’s in it and how it formed. Howard and Adam are looking at what’s eating the methane and how fast they’re doing it. And Jennie and I are looking at what depends on the seeps for habitat and food, either directly or indirectly.

And the best part of this is that we’re creating this incredible dataset that will be able to be scaled from an individual seep to entire regions. We’ll be able to use our work to predict habitats based on profiles of plumes and associated seafloor characteristics and then apply that all across the U.S. Pacific margin, and maybe even in the Atlantic too.

Image shows a multibeam map of the seafloor

A multibeam map of Astoria Canyon 500, created by USGS scientist Bill Danforth from data collected by R/V Falkor.

(Public domain.)

Personal Focus

This has been a truly rewarding experience for me. I’ve never had the opportunity to focus on a habitat system so intricately. Our Astoria Canyon 500 site is the perfect example. We’ve mapped the heck out of it; I don’t think there’s a square inch that Bill and the Falkor haven’t scanned and rescanned with the multibeam sonar.

Plus we’ve been able to spend 12 hours here, then revisit the site to see what’s changed a few days later and investigate how the seeps behave at different times of day, thanks to the Gas Quant, Bubble Box and UNC Landers.

Last but not least, we’ve been able to observe the animals that live here too, throughout the day and across multiple days, to see who is here, where they’re living, and what they’re eating.

Image shows a woman walking by an ROV onboard a ship

USGS scientist Amanda Demopoulos, lead scientist on this cruise, helps unload the collections from a Grays Canyon dive by ROV SuBastian.

(Credit: Shelton Du Preez, Schmidt Ocean Institute. Courtesy of Schmidt Ocean Institute)

Next Steps

So what’s next? Well, quite a lot of lab work, that’s for sure. Thanks to Schmidt’s facilities and wonderful ROV team, we’ve been able to collect a tremendous array of samples, from gas to clams to rocks. Now we’ll be taking that back to our various labs and analyzing the samples to answer critical questions.

For example---What created the system that fuels these seeps? How does the methane migrate through the sediments to be emitted at the ocean floor in the first place? Nancy and Diana’s work will tell us the history of these rocks and sediments. If Tamara finds more helium, that might indicate that some of these seeps include gas from deep in the zone where two tectonic plates interact on this margin.

Another question is whether chemical and biological processes work differently at the seafloor than when the samples are in the lab? Howard and Adam’s experiment at the seafloor is the first time we’ve been able to measure the rate of a bacterial process important for methane dynamics at the actual pressure, temperature, and environmental conditions at which they actually occur.   

Image shows a man and a woman standing next to an ROV

Howard Mendlovitz, Research Engineer in the Department of Marine Sciences at the University of North Carolina  and Amanda Demopoulos, Research Benthic Ecologist for the U.S. Geological Survey (USGS) collecting clam samples from the dive at Heceta, one of the areas of focus for seepage.

(Credit: Shelton Du Preez, Schmidt Ocean Institute. Courtesy of Schmidt Ocean Institute)

Finally, how are seeps connected to the broader ocean ecosystems? We’ve seen in the Atlantic and Gulf of Mexico that seeps create extensive ecosystems, composed of a diversity of habitat types, including bacterial mats, tubeworms, clams, and authigenic carbonate, and by expanding on previous research in the region, we’ve confirmed that in a big way here in the Pacific. However, the degree to which these benthic habitats interact with the water column in terms of transferring carbon, or energy, to mid-water organisms, such as pelagic fishes and invertebrates, is unclear.

For instance, do creatures living in the mid-water column descend to feed on the communities around the seeps, then swim up to the feed on the surface communities? If so, then that means the nutrients created at these deep seeps may well end up playing an important role near the surface too. This would have significant implications for overall ocean health.

Image shows a woman sitting at the bow of a ship

USGS scientist Amanda Demopoulos, lead scientist for this expedition, sits at the bow of the R/V Falkor.

(Credit: Shelton Du Preez, Schmidt Ocean Institute. Courtesy of Schmidt Ocean Institute)

Going Forward

It’s important to remember that not that long ago the seafloor was thought to be an empty abyssal plain, devoid of life and features. If you’ve followed along during Schmidt’s livecasts, you’ve seen how wrong that perspective is. The more we map and study the seafloor, the more we find out just how full of life and activity it is.

In fact, in just the last five years, we’ve discovered hundreds of these methane seeps on the U.S. Atlantic, Pacific, and Gulf of Mexico margins. How important are these seeps in the overall biological activity of the ocean? How do the seeps tie into the geologic forces that move our planet? These are the questions that we’ve sought to address on this cruise with Schmidt and on past cruises with other partners.

I hope you’ve enjoyed following along as we’ve discovered new seeps, rediscovered old seeps, and gathered staggering amounts of new data. We’ve got years of work ahead of us, but thanks to the support of Schmidt and all of our collaborators here, we’ve had a great start. Thank you to the wonderful crew of the R/V Falkor and ROV SuBastian, and thank you to Schmidt Ocean Institute for enabling this incredible research opportunity.

Image shows a group of people standing on the bow of a ship

The research and ship crew of the R/V Falkor stand on her bow as we return to port in Astoria, Oregon.

(Credit: Shelton Du Preez, Schmidt Ocean Institute. Courtesy of Schmidt Ocean Institute)