Mines as Source for Analysis of Deep Terrestrial Water

Understanding nutrient availability is critical to determining microbial ecosystem limits in the deep subsurface—ultimately linking our knowledge of the deep carbon cycle to our knowledge of the deep nitrogen cycle.

Understanding nutrient availability is critical to determining microbial ecosystem limits in the deep subsurface—ultimately linking our knowledge of the deep carbon cycle to our knowledge of the deep nitrogen cycle.Specifically, what is the origin and form of nitrogen available to the deep biosphere community? Nitrate (NO3-) is generally accepted to be an important source of energy and nutrients for microorganisms in shallow aquifers and marine sediments, but the extent of its role in deeper settings is still being determined. Mines provide all-important access to the deep subsurface but explosives used in mining are also a source of nitrate contamination.

A recent study [1] analyzed deep fracture water (> 0.8 km below surface)—with residence times estimated to be on the order of several million years—from the Witwatersrand Basin, South Africa to determine if its oxidized N species were introduced by mining contamination, paleometeoric recharge, or subsurface geochemical processes. The study yielded isotopic signatures suggesting that that the nitrate is related to subsurface geochemical processes rather than mining contamination or paleometeoric recharge.

Most of the nitrogen retained within the rock matrix as NH3 was either trapped in fluid inclusions or in exchangeable phyllosilicate sites with a minor fraction present as N2. High NO3 concentrations were detected in the fluid inclusions and the pore water. Irradation experiments revealed that NO3 can be produced by irradiation of NH3 and this represents the most likely source for this "deep" NO3. This NO3- provides a nitrogen nutrient source and an energy-rich electron acceptor for subsurface microbial communities as it leaks out of the inclusions into the pore space and eventually into the fracture water.  Although depleted nitrate concentrations were consistent with microbial nitrate reduction, further analysis is required to determine the relative importance of biological processes in the subsurface nitrogen cycle and whether or not a complete subsurface nitrogen cycle exists.

Figure:  Bianca Silver and Mark Davidson of Princeton University sample for deep life in fracture waters at 3.2km in the Kloof Mine, (Goldfields Inc. Ltd) South Africa. (Credit A. van Heerden).  The slight haze is a combination of vapor and rock dust.

Further Reading

DCO Research The Seafloor “Methane Filter” Takes Years to Regrow After Disruption

Disturbances to the seafloor, whether natural or unnatural, can upset the “microbial methane filter…

DCO Research How Microbes Survive When Buried Alive

A new model that probes the limits of microbial life finds that microorganisms in South Pacific…

DCO Highlights A Return to the Lost City: This Time it’s Microbial

A research group led by Susan Lang and William Brazelton embark on a new expedition to the Lost…

DCO Highlights A Behind-the-Scenes look at ‘The Most Unknown’

The Most Unknown, a new film that celebrates science, features nine scientists interviewing each…

Back to top