Characterization of Sediment Yield Variation, Little Colorado River Basin Near Saint Johns Arizona.

MacLeod, Andrew Harris

January 2001

Thesis (M. S. - Renewable Natural Resources)--University of Arizona, 2001. / Includes bibliographical references (leaves 155-156).

Evaluation of selected watershed assessment techniques.

Youbert, Ann,

January 1998

Thesis (M. S. - Renewable Natural Resources)--University of Arizona, 1998. / Includes bibliographical references (leaves 209-213).

Geology of the Chinle Formation in the Upper Little Colorado drainage area, Arizona and New Mexico

Cooley, M. E. (Maurice E.)

January 1957

No description available.

Chinle Formation.

maps

The archaeology of the Little Colorado drainage area

McGregor, John C. (John Charles), 1905-1992

January 1931

No description available.

Arizona -- Antiquities.

maps

The geochemistry of surface water and groundwater interactions for selected Black Mesa drainages, Little Colorado River basin, Arizona

Wickham, Matthew Prior,

January 1992

Thesis (M.S.- Hydrology and Water Resources)--University of Arizona. / Includes bibliographical references (leaves 245-249).

Groundwater Flow Across the Coyote Wash Fault and Cedar Mesa Anticline near St. Johns, Arizona

Latour, Stephanie Lynn

14 August 2023

As the demand for water increases across the southwestern United States, the region's utilization of and dependence on water stored in groundwater aquifers has risen in kind. The Coconino Aquifer (C-aquifer) underlies much of the southwestern Colorado Plateau and is a primary source of groundwater in northeastern Arizona. One of the largest commercial users of water from the C-aquifer in Apache County, Arizona, is Springerville Generating Station, a coal-fired power plant owned and operated by Tucson Electric Power. The area surrounding the power plant, located between the cities of Springerville and St. Johns, Arizona (the Springerville-St. Johns area), is geologically complex: it contains the Cedar Mesa anticline, an underlying CO2 reservoir, extensive travertine deposits, and several faults, including the Coyote Wash fault. The Coyote Wash fault and Cedar Mesa anticline play a significant role in the relationships between the St. Johns CO2 gas field, groundwater flow, and the travertine deposits. Yet, the interaction between the structures and the effect they have on groundwater flow is poorly constrained. By mapping the subsurface geology utilizing borehole records and by creating a groundwater model of the area, this study determined that the Cedar Mesa anticline acts as a partial horizontal barrier to groundwater flow, whereas the Coyote Wash fault does not act as such a barrier. Particle tracking for the model indicates that despite the reduced water volume in the aquifer after decades of groundwater extraction, flow still occurs across the hinge of the Cedar Mesa anticline, accelerated by active pumping wells located west of the anticline axis. The model indicates that prior to the activation of the pumping wells, outflow from the C-aquifer would have occurred with greater frequency to Lyman Lake and along the extent of the Little Colorado River located downstream from the lake. The study also identified a zone of high hydraulic conductivity located between the Cedar Mesa anticline and the Coyote Wash fault that continues west of the Coyote Wash fault and may align with the Buttes anticline. This model of groundwater flow conditions improves the understanding of the complex subsurface geology and groundwater flow dynamics in the area.

groundwater

model

MODFLOW

GMS

fault

Arizona

St. Johns

flow

anticline

particle tracking

Coconino aquifer

C-aquifer

Little Colorado River

water

Lyman Lake

Physical Sciences and Mathematics