As part of the Earth MRI project “Geochemical reanalysis of NURE samples from the Colorado Plateau, New Mexico, Utah, Colorado, and Arizona” (G23AC00561), New Mexico is resampling geologic material, including stream sediments and rocks, in the Zuni Mountains, Cibola and McKinley Counties. The purpose of this sampling is to assess the critical minerals potential of this area, which was historically mined for fluorspar and base metals. An exploration geochemistry focused class was taught in the fall semester of 2023. Sampling in the Zuni Mountains was conducted primarily by this class which allowed 17 students with varying field experience to learn how to plan and execute a sampling program. The students were split into five groups to sample different areas within the Zuni Mountains.
The MINES Thermodynamic Database is an initiative to generate a revised internally consistent thermodynamic dataset for minerals, aqueous species and gases for simulating geochemical processes at hydrothermal conditions in the upper crust (≤5 kbar and ≤600 °C) with focus on ore forming processes.
At the forefront of cutting-edge research at New Mexico Tech, we have been utilizing Raman spectroscopy to unravel the mysteries locked within minerals. By harnessing the power of visible and ultraviolet lasers, we can unlock a plethora of information. So, you may be asking, what is Raman spectroscopy? In simple terms, it's a technique that uses laser light to interact with the atomic vibrations of a material, producing a unique "fingerprint" of its molecular composition. By analyzing the scattered light, we are able to identify and characterize minerals such as apatite, fluorite, and calcite.
The depositional age of the Gatuña Formation in the Pecos Valley of southeastern New Mexico is poorly constrained, with estimates that vary from as old ca. 13 Ma at its base to as young as ca. 100 ka at its highest levels. As part of geologic mapping program efforts, we are applying detrital sanidine Ar-Ar geochronology and detrital zircon U-Pb geochronology to more tighlty bound the depositional age and duration of these alluvial deposits and their context within the late Cenozoic paleo-landscape of the ancestral Pecos River.
It is surprising that New Mexico does not have a detailed map of all of the productive and accessible aquifers across the state. In a state with as little as 0.24% of our land surface covered with water (the least in the country!), having detailed maps of our groundwater resources and aquifers, is essential. Some of our neighboring states, like Texas and Colorado, have these maps already available, and are successfully being used to administer and conserve water. We have started a new multi-year project to develop 3D maps of aquifers.
The Aquifer Mapping Program at New Mexico Bureau of Geology and Mineral Resources (NMBGMR), with funding from Healy Foundation and the USGS, has created the statewide Healy Collaborative Groundwater Monitoring Network for New Mexico. This voluntary network began in 2016 and gathers new and existing data on groundwater levels to help us understand how our state's groundwater resources are changing through time, promote increased awareness of water issues around New Mexico, and provide an important foundation for making informed water-management decisions.
The Magdalena radial dike swarm (MRDS) is a large diameter (200- 250 km) radial array of basaltic-andesite dikes of Oligocene age broadly focused on the large volume (7000 km3) Socorro-Magdalena caldera cluster (SMCC) of the central Rio Grande rift. Five large overlapping calderas of the SMCC range in age from 32.5 to 24.7 Ma and show a pattern of migrating to the southwest over a distance of about 80 km during a period of about 8 million years.
