Mystery of the Grand Canyon’s Water Supply

Karst aquifers, which have a pipe-like flow network of caves and conduits, directly supply up to 25 percent of the world population with water for drinking, agriculture and other needs and they are uniquely vulnerable to contamination. Two such aquifers, the Redwall and Coconino aquifers, supply water to Roaring Springs and many other Grand Canyon springs. The two aquifers are stacked on top of each other. While there are many types of vulnerability models, most ignore the complication of layered karst aquifer systems; this results in oversimplified, less accurate modeling.

“Vulnerability models identify regions of high, moderate and low vulnerability on the land surface, which directly relates to how quickly and efficiently water or contaminants would sink and enter the aquifer,” Jones said. “However, existing well-regarded vulnerability modeling methods for karst aquifers did not produce realistic results for our region.”

Jones modified the well-known concentration-overburden-precipitation method (COP). This method is effective, the researchers say, but it oversimplifies some details, which limits the model. She presented two new models that better address the factors that help scientists predict vulnerability.

The modifications more accurately account for recharge patterns in the Grand Canyon region, which has many karst features and a deep, complex aquifer system. Jones and the research team automated a process to identify sinkholes from high-resolution topography data, converted those data into sinkhole densities, and combined those data with a map of fault locations in the region. Jones then incorporated these features into the existing model using a geographic information system to produce the final vulnerability model.

It meant significant data processing, but the result was a model that produced greater resolution of vulnerability regions and fit well with previous groundwater flow path analyses. In addition to creating a better model on which future research can build, Jones found similar patterns in vulnerability between the two karst aquifers in the Grand Canyon region, despite them being separated by more than 600 meters of impermeable rock.

Jones also learned that about a fifth of the Kaibab Plateau has high vulnerability to contamination of the Redwall-Muav aquifer, which is about 1,000 meters deep, and almost half of the plateau surface (45.6 percent) has high to very high vulnerability for the Coconino aquifer, which is much closer to the surface.

If you’ve stopped to fill your water bottle while you’re hiking the Grand Canyon or admiring the views on the canyon rim, this matters to you. Since the Roaring Springs is the only source of water in the park, its quality has significant value. This research provides better information to water managers to protect the Grand Canyon’s water resources, including creeks on the north side, which researchers think are recharged by the Kaibab Plateau.

“These springs and streams support diverse ecosystems, and many hikers and wildlife rely on them for survival,” Jones said. “This research helps narrow down where these water sources are coming from and could help us better protect them in the future.”

Contacts and sources:
Heidi Toth
Northern Arizona UniversityPublication: Modeling intrinsic vulnerability of complex karst aquifers: modifying the COP method to account for sinkhole density and fault location. Natalie A. Jones, Jered Hansen, Abraham E. Springer, Cynthia Valle, Benjamin W. Tobin. Hydrogeology Journal, 2019; 27 (8): 2857 DOI: 10.1007/s10040-019-02056-2