On a triple-digit summer day in Davis, community members found shade and science within the walls of G Street WunderBar at the latest . Standing at the front of the pub, marine geochemist and oceanographer Tessa Hill showed the audience a picture of a fog-shrouded Tomales Bay and asked them to reflect on their connections to the ocean.
鈥淢aybe it鈥檚 a recent visit or maybe it鈥檚 a family memory,鈥 she said. 鈥淢aybe it鈥檚 a food that you love to eat that comes from the ocean.鈥
As the audience at considered their connections, Hill discussed the rapid changes occurring in the oceans due to human-induced climate change: swings in ocean temperatures, unprecedented sea level rise and tectonic shifts in ocean chemistry. The regular events provide an avenue for the community to learn about the current state of science across its many disciplines.
鈥淲e contribute carbon dioxide to the atmosphere through a variety of things that we do. Through our energy systems, our transportation systems, obviously the use of fossil fuels, industrial processes like cement production, but also, I have to acknowledge that the decisions we make about food and agriculture and land use also contribute to carbon dioxide going into the atmosphere.鈥 鈥 Hill
And what goes into the atmosphere goes into our oceans. The classical elements of air and water are in constant conversation.
鈥淭he ocean is a tremendous sponge for carbon dioxide,鈥 Hill said. 鈥淎bout 30% of what we put in the atmosphere goes straight into the ocean.鈥
Hill recalled that during her early days as a scientist, many framed this statistic as the ocean doing us a favor. If the ocean didn鈥檛 play this role in the carbon cycle, there would be more atmospheric heating.
But the ocean isn鈥檛 immune to the effects of carbon dioxide either.
鈥淚n very simple terms, CO2 combines with water very readily to form a weak acid, which is called carbonic acid, and it changes the acidity of the ocean,鈥 Hill said. 鈥淚t鈥檚 called ocean acidification.鈥
Ocean acidification is a major problem for shell-building organisms, like oysters, mussels, clams and coral reefs. These creatures rely on specific pH conditions to produce calcium carbonate, the main ingredient of shells. As the ocean absorbs more CO2, it becomes increasingly difficult for these organisms to build their shells and survive.
A potential solution to mitigate these effects may reside in the disappearing seagrass beds hugging the California coastline.
Hill discussed the rapid changes occurring in oceans around the world due to human-induced climate change: swings in ocean temperatures, unprecedented sea level rise and tectonic shifts in ocean chemistry. (Greg Watry/澳门六合彩资料库 Davis)
An intellectual partnership around seagrass
For about two decades, Hill and her colleagues have partnered with Marin County-based Hog Island Oyster Company to explore ways to mitigate the effects of ocean acidification on shellfish. Sustainable shellfish is the company鈥檚 livelihood.
鈥淭hey鈥檙e thinking about the long-term success of what it means to raise sustainable shellfish in California, so they were alarmed to hear these results that we were finding, particularly about oysters and mussels,鈥 Hill said.
One day, Hill and colleagues were overlooking Hog Island鈥檚 property in Tomales Bay when the company鈥檚 co-founder Terry Sawyer asked if the marine-flowering seagrass meadows in the bay could potentially remove enough carbon dioxide through photosynthesis to improve the water conditions for their oysters.
A cluster of bottom-cultured oysters grows in seagrass. (NOAA)
鈥淢y colleagues and I said, 鈥榊ou know, that is a really great research idea. Let鈥檚 do it; let鈥檚 figure it out,鈥欌 Hill said.
Partnering with scientists Aurora Ricart and Melissa Ward, who led the research projects, Hill and her colleagues monitored seven seagrass meadows in six different estuaries in California for about six years, tracking the chemical shifts that occurred in the water.
鈥淲e found that seagrass meadows improved the water chemistry for the surrounding waters over 65% of the time, so the owners of the oyster company were spot on in their intuition. Additionally, we found that sediment inside seagrass beds can have up to twice as much stored carbon as the sediment and estuary around it. This rate is a rate three times higher than terrestrial forests.鈥 鈥 Hill
The research was supported by various funding agencies, including Sea Grant California, the State of California Ocean Protection Council and .
鈥淭he seagrass meadows are creating sort of a halo effect, where they buffer the CO2 out of the water, and so presumably anything that鈥檚 living near those seagrass meadows is getting the benefit of a lower CO2 environment,鈥 Hill said.
Ricart and Ward conducted follow-up research in the lab confirming that the presence of seagrass beneficially affected oysters鈥 ability to grow shells.
Protecting a disappearing resource
Seagrass meadows are vital ecosystems. Not only do they help filter pollutants and provide a barrier for erosion but they are also habitats for juvenile fish and shellfish. Alarmingly, it鈥檚 estimated that about since the industrialization of California.
Restoration projects are underway to mitigate this loss.
Funded by 澳门六合彩资料库 Davis Venture Catalyst, , an earth and planetary science Ph.D. student in Hill鈥檚 lab, is conducting a years-long project to quantify seagrass meadow restoration.
Just how long does it take to see the benefits these coastal habitats bestow upon the water? And how much carbon is actually stored in the sediments beneath the beds? These are all questions Sellinger seeks to answer.
Specifically, Sellinger is monitoring restoration sites in Tomales Bay and Monterey Bay, which are part of the Greater Farallones National Marine Sanctuary and the Monterey Bay National Marine Sanctuary, respectively.
鈥淭here are different types of restorations going on. In Tomales Bay, there鈥檚 passive restoration where they鈥檙e removing these derelict boat moorings that are kind of scarring the whole area. As you remove them, you鈥檙e giving space for the seagrass to grow. And then in Monterey Bay 鈥 in Elkhorn Slough 鈥 they鈥檙e doing active restoration, which means they鈥檙e actively seeding or planting seagrass in the areas where there are not permanent meadows.鈥 鈥 Sellinger
Sellinger is monitoring the sediment accumulation of carbon within these meadows before, during and after these acts of restoration. She plans to monitor the sites for about two to three years, collecting data on carbon storage.
Hill chats with an attendee following her presentation at the latest .. (Greg Watry/澳门六合彩资料库 Davis)
Finding hope
While seagrasses are only present in about 0.2% of the world鈥檚 oceans, it鈥檚 estimated that they store about 10% of the carbon in ocean sediment, according to . Though not enough to bolster against the effects of ocean acidification alone, protecting and restoring seagrass beds is a viable local solution against climate change.
鈥淲e need to be addressing our reliance on fossil fuels and our treatment of land and the way we鈥檙e making choices about food and agriculture,鈥 Hill said. 鈥淏ut will this help us in terms of the ways that we can store carbon that we鈥檙e missing out on? For sure, and the one thing I always remind people of is if we鈥檝e lost 90% of these habitats in the state of California, we鈥檝e lost all that natural storage that we could be using.鈥
For Hill, restoring seagrass beds is just one beacon in the lighting fixture of combating climate change. There is no single solution. Rather, a confluence of efforts is required to address the problem. Such actions are based on people coming together and Hill is hopeful.
鈥淗ope is something that we work on. It鈥檚 a muscle. It鈥檚 not something we wake up in the morning with, but it鈥檚 something we鈥檙e committed to.鈥 鈥 Hill
Media Resources
To learn more about the actions people across the world are taking to protect our oceans, check out Tessa Hill鈥檚 and Eric Simon鈥檚 new book .