25 Aug 2018
Northeast Atlantic bathymetry, with Porcupine Bank and the Porcupine Seabight labelled.
A research expedition to a huge underwater canyon off the Irish coast has shed light on a hidden process that sucks the greenhouse gas carbon dioxide (CO2) out of the atmosphere.
Researchers led by a team from the University College Cork (UCC) took an underwater research drone by boat out to Porcupine Bank Canyon — a massive, cliff-walled underwater trench where Ireland’s continental shelf ends — to build a detailed map of its boundaries and interior. Along the way, the researchers reported in a statement, they noted a process at the edge of the canyon that pulls CO2 from the atmosphere and buries it deep under the sea.
All around the rim of the canyon live cold-water corals, which thrive on dead plankton raining down from the ocean surface. Those tiny, surface-dwelling plankton build their bodies out of carbon extracted from CO2 in the air. Then, when they die, the coral on the seafloor consume them and build their bodies out of the same carbon. Over time, as the coral die and the cliff faces shift and crumble, which sends the coral falling deep into the canyon. There, the carbon pretty much stays put for long periods. [ In Photos: ROV Explores Deep-Sea Marianas Trench
There’s evidence that a lot of carbon is moving this way; the researchers said they found “significant” dead coral buildup at the canyon bottom.
This process doesn’t move nearly enough carbon dioxide to prevent climate change, the researchers said. But it does shed light on yet another mechanism that keeps the planet’s CO2 levels regulated when human industry doesn’t interfere.
“Increasing CO2 concentrations in our atmosphere are causing our extreme weather,” Andy Wheeler, a UCC geoscientist and one of the researchers on the expedition, said in the statement. “Oceans absorb this CO2 and canyons are a rapid route for pumping it into the deep ocean where it is safely stored away.”
The mapping expedition covered an area about the size of Chicago and revealed places where the canyon has moved and shifted significantly in the past.
“We took cores with the ROV, and the sediments reveal that although the canyon is quiet now, periodically it is a violent place where the seabed gets ripped up and eroded,” Wheeler said.
The expedition will return to shore today (Aug. 10).
From polyester shirts, plastic milk jugs and PVC pipes to the production of high-grade industrial ethanol, the contribution of the chemical feedstock ethylene can be found just about everywhere around the globe.
But ethylene’s ubiquity as a building block in plastics and chemicals masks an underlying environmental cost. The cheap hydrocarbon is made using petroleum and natural gas, and the way it is produced emits more carbon dioxide than any other chemical process. As concerns about levels of CO2 in the atmosphere have grown, some scientists have been experimenting with ways to make ethylene production more green. At the Department of Energy’s National Renewable Energy Laboratory (NREL), researchers are finding unexpected success with the help of cyanobacteria, or blue-green algae.
Jianping Yu, a research scientist with NREL’s Photobiology Group, is leading a team of researchers who are working with these organisms. In his lab, they have been able to make ethylene directly from genetically modified algae.
The researchers were able to accomplish this by introducing a gene that coded for an ethylene-producing enzyme—effectively altering the cyanobacteria’s metabolism. This allows the organisms to convert some of the carbon dioxide normally used to make sugars and starches during photosynthesis into ethylene. Because ethylene is a gas, it can easily be collected.
Making ethylene doesn’t require many inputs, either. The basic requirements for cyanobacteria are water, some minerals and light, and a carbon source. In a commercial setting, CO2 could come from a point source like a power plant, Yu said.
If this alternative production method becomes efficient enough, it could potentially replace steam cracking, the energy-intensive method currently used to break apart petrochemicals into ethylene and other compounds. Because the algae take in three times the CO2 to produce a single ton of ethylene, the process acts as a carbon sink. That would be a significant improvement over steam cracking, which generates between 1 ½ and 3 tons of carbon dioxide per ton of ethylene, according to the researchers’ own analysis. The captured ethylene gas can then be transformed for use in a wide range of fuels and products.
“I think it’s better to turn CO2 into something useful,” Yu said, comparing the approach to other methods of carbon capture. “You don’t have to pump CO2 into the ground, and [the products] will last for many years.”
Engineering genes to suck up carbon
Yu and his colleagues weren’t the first to come up with the idea of using cyanobacteria to make ethylene. The process was first attempted by researchers in Japan more than a decade ago. At the time, the researchers were not able to produce ethylene reliably. When Yu read the study years later, he thought that by genetically altering a different strain with which he had worked closely (Synechocystis sp. PCC6803), he might be able to make ethylene production more consistent.
The researchers are able to make ethylene from algae by altering a part of the organism’s metabolism called the tricarboxylic acid (TCA) cycle, which is involved in biosynthesis and energy production. In genetically unaltered blue-green algae, the cycle can only take in a relatively small fraction, or 13 percent, of the 2 to 3 percent of fixed CO2. But in Yu’s lab, the algae are able to send three times more carbon to the TCA cycle and emit 10 percent of the fixed carbon dioxide as ethylene—at a rate of 35 milligrams per liter per hour. That might not sound like very much, but it represents a thousandfold increase in productivity since he first began working with the cyanobacteria in 2010. By the end of this year, Yu is aiming to increase that productivity to 50 milligrams.
“This is by no means close to the upper limit,” he said, explaining that the ultimate goal will be to convert 90 percent of fixed carbon to ethylene. “I cannot see why it cannot go higher; I haven’t run into a brick wall yet. I don’t know what would prevent that from happening, but of course it could.”
Surprisingly, even though the cyanobacteria are producing more ethylene, the organisms are still growing at the same rate as non-ethylene-producing algae. The results demonstrate that the cyanobacteria’s metabolism was much more flexible than previously thought, according to Yu.
“It’s like a person that’s losing blood all the time but appears healthy,” he said.
Yu and his colleagues aren’t certain how this is happening, but the mutation that enabled ethylene production has also stimulated photosynthesis.
“This system gives us a new insight into photosynthesis and gives us hope that we can learn from this and increase photosynthetic activity,” he said.
That insight into cyanobacteria’s metabolism is as important a finding as the creation of organisms that can consistently produce ethylene, said Robert Burnap, a professor of microbiology and molecular genetics at Oklahoma State University. He was not involved with the study, but did provide a reference for Yu’s application to this year’s R&D 100 Awards. Yu is now a finalist in the Mechanical Devices/Material category.
“It’s surprising how adaptive the metabolism is. It’s producing something it’s not evolved to make. There was a lot of controversy over whether or not that was even possible to have consistent ethylene production. It shows it is flexible,” he said.
The research could help other scientists better understand metabolic pathways in other plants and even in humans. The TCA cycle is even active in our cells’ mitochondria, Burnap said.
“What makes this study really special is the depths of analysis that they went into,” he said, describing the research as a whole as a “seminal piece of work.”
Manufacturing centers … in ponds?
It’s still much too early to say when or even if these algae will produce ethylene at a commercial scale. Yu estimates that development to that stage could take more than 10 years.
“It will take a lot of work to improve carbon efficiency to 50 percent or higher,” Yu said.
Philip Pienkos, principal manager of the Bioprocess R&D Group at NREL’s National Bioenergy Center, said the project is beginning to focus more on the development side, even as Yu continues to work to achieve higher ethylene volumes.
“How do you recover ethylene? What do you do with the biomass? This project is poised to answer these important questions,” Pienkos said.
Sometime next year, the researchers plan to move their work outdoors to see how the algae behave in an environment that more closely resembles how they would be grown commercially.
“We have to get a real scalable ethylene process so we have a better sense of what this will look like,” Pienkos said.
Yu envisions the cyanobacteria growing either in ponds, or possibly vertically, on newspaper-like sheets. In either case, the solid or liquid cultures would have to be enclosed to capture the ethylene, he said.
There are also some safety concerns associated with producing large quantities of the gas. The hydrocarbon and oxygen that are also produced by the algae are flammable, and certain safety precautions would have to be put in place to safely collect ethylene.
Even if the cyanobacteria can create large volumes of ethylene, their success will depend on whether the product can become cost-competitive. That won’t be easy because petrochemical-based ethylene is cheap and widely available. According to the researchers’ economic analysis, ethylene made from petrochemicals cost $600 to $1,300 per ton, while the gas coming from the algae is estimated to be about $3,240 per ton.
Proving the system’s economic viability down the road will also help maintain research funding from the Department of Energy, Peinkos said.
“Algae is not the primary focus of DOE; they’ve spent decades supporting work in cellulosics. Algae is a much smaller portfolio, and most of the work is in conversion directly to liquid fuels,” he said. “Ethylene stands out a little bit because it’s not a fuel, but it can be a fuel feedstock.”