Shedding Light on Fracking Process

Friday, July 11, 2014 @ 04:07 PM gHale


A new type of pressure cell makes it possible to simulate chemical reactions deep in the Earth’s crust, which could allow for nuclear magnetic resonance (NMR) measurements on as little as 10 microliters of liquid at pressures up to 20 kiloBar.

The high-pressure measurements could shed light on chemical processes involved in hydraulic fracturing, or “fracking,” and the behavior of buried nuclear waste over long periods of time. Fracking is the process of extracting oil and gas by injecting liquids under high pressure into rocks.

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“NMR is our window into the chemical world,” said Brent Pautler, a postdoctoral researcher in chemistry at the University of California-Davis and first author on the paper published this month. “It lets us see chemical reactions as they are happening.”

The new device allows researchers for the first time to study chemical reactions in liquid water under pressure, without it freezing into a solid.

“We were able to get to the point where we could no longer ignore the compressibility of the water molecules,” Pautler said. “This is the first time this has ever been reported.”

Geochemists want to know what kind of chemistry is happening deep in the Earth’s crust, beyond the reach of boreholes. These chemical reactions could affect water and minerals that eventually migrate to the surface, or the behavior of carbon cycling between the Earth’s depths and the surface.

“Aqueous fluids deep in the Earth are the great unknown for geochemists,” said Chris Colla, a graduate student in Earth & Physical Sciences at UC Davis and co-author on the paper. “By doing NMR we can get an inside view of what is occurring deep in the Earth’s crust.”

Pautler and Colla are already looking at calcium ions in solution. Dissolved calcium ions can end up surrounded by four, six or eight water molecules. High pressure forces dissolved calcium into an eight-water state, they found.

The researchers were able to build the high-pressure NMR cell in the machine shop at the Crocker Nuclear Laboratory with the help of Peter Klavins, research specialist in the Department of Physics, and Steve Harley, a former UC Davis graduate student now at the Lawrence Livermore National Laboratory.



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