Date of Award


Degree Name

Master of Science




Diane I. Doser


A series of non-invasive geophysical investigations at the Rattlesnake Springs part of Carlsbad Caverns National Park, New Mexico, were performed in an effort to better delineate the watershed of the springs. The goal of this project is to determine possible locations of fractures and faults that may control the distribution of groundwater that feeds Rattlesnake Springs. Once the water flow paths are identified, the park will be able to better protect Rattlesnake Springs from environmental hazards, such as oil and gas drilling, as well as from upstream water development. As part of this effort I conducted a precision gravity survey of the area surrounding the springs. The survey used 200- to 300-m grid spacing with station positions and elevations determined using differential Global Positioning System (GPS) receiver. The survey was designed to map the depth to gypsum bedrock in the study area, and to pinpoint the locations of faults and fractures that could control groundwater movement toward the springs. I generated gravity maps from the gravity data, and also constructed two-dimensional (2D) gravity models in order to gain more complete understanding of the subsurface including the locations of the probable geological structures that are controlling the water flow towards the springs. From the models, the approximate maximum depth to the gypsum bedrock in the small basins was found to be anywhere between 800 to more than 2000 meters in the study area. Verification of the locations and orientation of these hypothetical geological structures (fractures) was done as a part of my effort.

The study is important to the National Park Service personnel from an environmental point of view due to the fact that it will assist them to protect the Rattlesnake Springs area from potential groundwater contamination due to oil and gas drilling performed at nearby sites. Once the Park Service knows the orientation of the possible fracture zones, they will be able to perform more accurate hydrologic modeling of the area in order to better define the ground water flow paths.




Received from ProQuest

File Size

63 pages

File Format


Rights Holder

Nikolay D. Boykov