Sandia LabNews

Finding fire and ice: Modeling the probability of methane hydrate deposits on the seafloor


Sandia scientists use machine learning to find fuel source, climate-change driver

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FIRE AND ICE — Sandia researchers used advanced computer models to predict the like­lihood of finding methane hydrate, an ice-like material made of compressed natural gas that burns when lit. (Photo courtesy of U.S. Geological Survey)

Methane hydrate, an icelike mate­rial made of compressed natural gas, burns when lit and can be found in some regions of the seafloor and in Arctic permafrost.

Thought to be the world’s largest source of natural gas, methane hydrate is a potential fuel source. If it “melts” and releases meth­ane gas into the atmosphere, it is a potent greenhouse gas. For these reasons, knowing where methane hydrate might be located, and how much is likely there, is important.

A team of researchers from Sandia and the U.S. Naval Research Laboratory have developed a new system to model the likelihood of finding methane hydrate and methane gas that was tested in a region of seafloor off the coast of North Carolina.

While methane hydrate deposits have been found in a variety of locations, there are significant unknowns in terms of how much methane hydrate exists on the seafloor and where. It is challeng­ing to collect samples from the seafloor to find methane hydrate deposits. This is where Sandia’s computer modeling expertise comes in.

“This is the first time someone has been able to approach methane hydrate distribu­tion in the same way we approach weather forecasting,” said Jennifer Frederick, a computational geoscientist and lead researcher on the project.

“When you hear a weather forecast for a 60% chance of two inches of rain, you don’t necessarily expect exactly two inches. You understand that there is uncertainty in that forecast, but it is still quite useful,” she said. “In most places on the seafloor we don’t have enough information to produce an exact answer, but we still need to know something about methane and its distribu­tion. By using a probabilistic approach, sim­ilar to modern weather forecasting, we can provide useful answers.”

The new system combines Sandia’s longstanding expertise in probabilistic modeling with machine learning algo­rithms from the Navy. The system was tested and refined by modeling the area around Blake Ridge, a hill on the sea­floor 90 to 230 miles southeast of North Carolina’s Outer Banks with known depos­its of methane hydrate and methane gas.

The team shared its model for Blake Ridge and compared it with previous empirical data in a paper soon to be published in Geochemistry, Geophysics, Geosystems.

‘Forecasting’ methane with machine learning

The Naval Research Laboratory’s Global Predictive Seafloor Model pro­vides site-specific details on seafloor prop­erties, such as temperature, overall car­bon concentration and pressure. If data is missing for a certain region, the Naval Research Laboratory’s model uses advanced machine-learning algorithms to estimate the missing value based on information about another area that may be geographically dis­tant but similar geologically.

The research team imported the data from the Naval Research Laboratory’s model into Sandia software that specializes in statistical sampling and analysis, called Dakota. Using Dakota, they determined the most likely value for influential seafloor properties, as well as the natural variation for the values.

Then, in a statistical manner, they inserted a value from this expected range for each property into PFLOTRAN. PFLOTRAN is another software main­tained and developed at Sandia, which mod­els how chemicals react and materials move underground or under the seafloor. The team conducted thousands of methane production simulations of the Blake Ridge region. All the software involved in the system is open source and will be available for other ocean­ographic researchers to use.

“One of the biggest things we found is that there is almost no formation of meth­ane hydrates shallower than 500 meters, which is to be expected given the tem­perature and pressure needed to form methane hydrate,” said William Eymold, a postdoctoral fellow at Sandia and pri­mary author of the paper. Solid methane hydrate is known to form in low-tempera­ture, high-pressure environments where molecules of methane are trapped within well-organized water molecules.

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CLOUDY WITH A CHANCE OF METHANE — Using Sandia’s longstanding expertise in probabi­listic modeling and machine learning algorithms from the Navy, the researchers determined the probabil­ity of finding methane hydrate off the coast of North Carolina’s Outer Banks where methane hydrate has been found. (Image courtesy of William Eymold)

The team also found methane gas formed closer to shore. They were able to compare their model to methane hydrate values calcu­lated by past studies and samples collected a few decades ago by the National Science Foundation’s Ocean Drilling Program, he said. For example, methane hydrate was detected in a seafloor sample collected from a hole drilled on Blake Ridge called Site 997.

“The fact that we predicted meth­ane hydrate formation in similar amounts to past studies and observations really showed that the system appears to be working pretty well and we will be able to apply it to other geographic locations that may have less data,” William said.

Importance of methane to the Navy

The location of methane hydrate deposits and methane gas near the seafloor is import­ant to the Navy.

“Understanding how sound interacts with the seafloor is really important for any kind of naval operation,” said Jennifer. “Methane gas affects the acoustics dramatically.

“Even if only 1% or 2% of the pore space in the seafloor sediment is filled with a gas bubble, the speed of sound decreases a hundredfold, or more,” she said. “This is a very large effect and if you don’t account for it properly, then you’re not going to get precise acoustics.”

Jennifer compared a submarine using sonar to the early arcade game Breakout, where a player moves a paddle horizontally in order to keep a ball bouncing to destroy a wall of bricks. In this analogy, the seafloor serves as the “paddle” to reflect or refract sound waves, or the “ball,” in order to get a complete view of obstacles in the ocean. If the paddle started to bounce the ball differ­ently — or held on to the ball for varying lengths of times — depending on where the paddle was located, the game would become far more challenging.

Future modeling projects

So far, the team has used their system to create models of a region of the Norwegian Sea between Greenland and Norway and the shallow waters of the Arctic Ocean offshore of the North Slope of Alaska, two areas of interest to the Navy.

Jennifer has also worked with a large team of international experts to assess the amount of methane and carbon dioxide stored in the shallow Arctic seafloor, and how sensitive those deposits would be to rising temperatures.

The team has also created a much coarser model of the whole globe and has started looking at the mid-Atlantic, where methane gas was spotted bubbling out of the seafloor a few years ago.

“It will be interesting to see if our model is able to predict these regions of methane seeps on the seafloor,” Jennifer said. “We’d like to see if we can predict the distribution of these methane seeps and whether they are consistent with the thermodynamic properties of methane-hydrate stability. When you see a seep, that means that there is a lot of gas beneath the seafloor. That will significantly impact how sound travels through the seafloor, and thus sonar. Also, these deposits could be a source of natu­ral gas for energy production, will impact the ocean ecology and nutrient cycles, and if that gas reaches the atmosphere, it will have climate change implications.”

This research was funded by Sandia’s Laboratory Directed Research and Development program. Jennifer is seek­ing funding to continue the project with her collaborators at the Naval Research Laboratory.