Groundwater Geology of Fort Valley, Coconino County, Arizona

DeWitt, Ronald H.

05 May 1973

From the Proceedings of the 1973 Meetings of the Arizona Section - American Water Resources Assn. and the Hydrology Section - Arizona Academy of Science - May 4-5, 1973, Tucson, Arizona / All groundwater in fort valley is presently found in perched aquifers. The regional water table in the area is estimated to lie at a depth of approximately 1750 feet. Groundwater reservoirs are perched on impermeable clay zones located at the base of alluvial units. Groundwater is also found in highly fractured volcanic zones overlaying impermeable clay zones. Perched aquifers also occur in interflow zones above either impermeable clays or unfractured volcanics. Groundwater in fort valley is the result of infiltration or runoff and from precipitation. This recharge water infiltrates the alluvium or fractured volcanic rocks until an impermeable zone is reached where it becomes perched groundwater. Greatest well yields come from these recharge aquifers; their reliability is largely dependent on precipitation and runoff. Most wells in the fort valley area supply adequate amounts of water for domestic use.

Hydrology -- Arizona.

Water resources development -- Arizona.

Hydrology -- Southwestern states.

Perched water

Clays

Groundwater

Geohydrologic units

Fractures (geologic)

Arizona

Geology

Sandstones

Sedimentary rocks

Faults

Alluvium

Igneous rocks

Conglomerate rocks

Aquifers

Water table

Infiltration

Runoff

Recharge

Watersheds (basins)

Surface drainage

Limestones

Reservoirs

Impervious soils

Water wells

Water yield

Interflow

Preliminary Investigations of the Hydrologic Properties of Diatremes in the Hopi Buttes, Arizona

Scott, Kenneth C., Edmonds, R. J., Montgomery, E. L.

20 April 1974

From the Proceedings of the 1974 Meetings of the Arizona Section - American Water Resources Assn. and the Hydrology Section - Arizona Academy of Science - April 19-20, 1974, Flagstaff, Arizona / Diatremes of Late Pliocene age in the Hopi Buttes area of Arizona are becoming increasingly important sources of groundwater to the Indian nations. These volcanic vent structures are prime sources of groundwater because sedimentary formations in the Hopi Buttes area yield only limited amounts of water or yield poor quality water. Diatremes act as traps for groundwater and some have yielded moderate amounts of good quality water to wells. Surface geologic investigations and analysis of drillers' logs indicate that structural relationships and diatreme lithology provide a means to project the hydrologic properties of the vent. Diatremes most suitable for groundwater development should have a diameter greater than one half mile, should contain volcanic tuff and breccia at its center, and should be fractured from collapse. Lava flows covering diatremes reduce recharge from sheet wash or from ephemeral stream flow. Data from geomagnetic and gravity surveys will be analyzed to determine its suitability for predicting subsurface size, shape, and lithology of the diatreme. The integration of geophysical and surface geologic data will reveal the total geometry of the structure enabling the most accurate appraisal of the hydrologic properties of the diatreme.

Hydrology -- Arizona.

Water resources development -- Arizona.

Hydrology -- Southwestern states.

Water supply

Groundwater basins

Water wells

Hydrologic properties

Groundwater availability

Arizona

Petrology

Permeability

Soil properties

Water properties

Water resources

Recharge

Water quality

Groundwater mining

Aquifers

Groundwater

Aquifer characteristics

Water sources

Water yield

Hydrogeology

Water storage

Igneous rocks

Diatremes

Hopi buttes (ariz)

Distribution of iron-titanium oxides in the vanadiferous main magnetite seam of the upper zone : Northern limb, Bushveld complex

Gwatinetsa, Demand

January 2014

The main magnetite seam of the Upper Zone of the Rustenburg Layered Suite (SACS, 1980) on the Bushveld Complex is known to host the world‘s largest vanadium bearing titaniferous iron ores. The vanadiferous titanomagnetites, contain vanadium in sufficient concentrations (1.2 - 2.2 per cent V₂O₅) to be considered as resources and vanadium has been mined historically by a number of companies among them Anglo-American, Highveld Steel and Vanadium and VanMag Resources as well as currently by Evraz Highveld Steel and Vanadium Limited of South Africa. The titanomagnetites contain iron ore in the form of magnetite and titanium with concentrations averaging 50-75 per cent FeO and 12-21 per cent TiO₂. The titaniferous iron ores have been historically dismissed as a source of iron and titanium, due to the known difficulties of using iron ore with high titania content in blast furnaces. The economic potential for the extractability of the titaniferous magnetites lies in the capacity of the ores to be separated into iron rich and titanium rich concentrates usually through, crushing, grinding and magnetic separation. The separatability of iron oxides and titanium oxides, is dependent on the nature in which the titanium oxide occurs, with granular ilmenite being the most favourable since it can be separated from magnetite via magnetic separation. Titanium that occurs as finely exsolved lamellae or as iron-titanium oxides with low titania content such as ulvospinel render the potential recoverability of titanium poor. The Upper Zone vanadiferous titanomagnetites contain titanium in various forms varying from discrete granular ilmenite to finely exsolved lamellae as well as occurring as part of the minerals ulvospinel (Fe₂TiO₄) and titanomagnetite (a solid solution series between ulvospinel and magnetite) . Discrete ilmenite constitutes between 3-5 per cent by volume of the massive titanomagnetite ores, and between 5-10 per cent by volume of the magnetite-plagioclase cumulates with more than 50 per cent opaque oxide minerals. The purpose of this research was to investigate the mineralogical setting and distribution of the iron and titanium oxides within the magnetitite layers from top to bottom as well as spatially along a strike length of 2 000m to determine the potential for the titanium to be extracted from the titanomagnetite ores. The titanomagnetites of the Upper Zone of the Bushveld Complex with particular reference to the Northern Limb where this research was conducted contains titanium oxides as discrete ilmenite grains but in low concentrations whose potential for separate economic extraction will be challenging. The highest concentration of titanium in the magnetite ores is not contained in the granular ilmenite, but rather in ulvospinel and titanomagnetite as illustrated by the marked higher concentration of TiO₂ in the massive ores which contain less granular ilmenite in comparison to the disseminated ores which contain 3 to 8 percentage points higher granular ilmenite than the massive ores. On the scale of the main magnetite seam, the TiO₂ content increases with increasing stratigraphic height from being completely absent in the footwall anorthosite. The V₂2O₅ content also increases with stratigraphic height except for in one of the 3 boreholes where it drops with increasing height. The decrease or increase patterns are repeated in every seam. The titanomagnetites of the main magnetite seam display a variety of textures from coarse granular magnetite and ilmenite, to trellis ilmenite lamellae, intergranular ilmenite and magnesian spinels and fine exsolution lamellae of ulvospinel and ferro-magnesian spinels parallel to the magnetite cleavage. The bottom contact of the main magnetite seam is very sharp and there is no titanium or vanadium in the footwall barely 10cm below the contact. Chromium is present in the bottom of the 4 layers that constitute the main magnetite seam and it upwards decreases rapidly. In boreholes P21 and P55, there are slight reversals in the TiO₂ and V₂O₅ content towards the top of the magnetite seams.

Geology of the Palo Verde Ranch Area, Owl Head Mining District, Pinal County, Arizona

Applebaum, Steven

January 1975

A quartz diorite intrusion of probable early Tertiary age that crops out over at least 6 square miles in the Palo Verde Ranch area in Pinal County, Arizona was mapped as a distinct intrusion. The quartz diorite intrudes an area comprising Pinal Schist, Oracle granite, andesitic flows, granoaplite, and dike rocks including both pegmatite and diabase. Two major physical features, the Owl Head Buttes and Chief Buttes volcanic areas, both remnants of an extensive early Tertiary series of flows of intermediate composition that covered the area, now remain as lava-capped buttes above the pediment. Weak but persistent fracture-controlled copper mineralization is found in the quartz diorite and the Pinal Schist at or near their mutual contacts in the form of chrysocolla, malachite, black copper oxides, chalcocite, chalcopyrite, and bornite, in decreasing order. Pyrite is rare. Alteration related to northeast and northwest-trending fractures increases in intensity from the common propylitic to argillic to the northeast toward the San Juan claims area. A barely discernible increase in copper sulfides mirrors the alteration zoning, although geochemical sampling showed background copper in the quartz diorite to be more uniform away from fractures.

alteration

andesites

Arizona

bornite

carbonates

Cenozoic

chalcocite

chalcopyrite

chemical composition

Chief Buttes

chrysocolla

clay minerals

composition

copper

diabase

diorites

distribution

granites

granoaplite

igneous rocks

intrusions

lava flows

malachite

metals

mineral composition

mineralization

occurrence

Owl Head Buttes

Owl Head District

Palo Verde Ranch

petrology

Pinal County Arizona

Pinal Schist

plutonic rocks

quartz diorites

sheet silicates

silicates

sulfides

Tertiary

United States

volcanic

volcanic rocks

Geology -- Arizona -- Pinal County

A Re-Os Study of Sulfides from the Bagdad Porphyry Cu-Mo Deposit, Northern Arizona, USA

Barra-Pantoja, Luis Fernando

January 2001

Use of Re-Os systematics in sulfides from the Bagdad porphyry Cu-Mo deposit provide information on the timing of mineralization and the source of the ore -forming elements. Analyzed samples of pyrite, chalcopyrite and molybdenite mainly from the quartz monzonite and porphyritic quartz monzonite units are characterized by a moderate to strong potassic alteration (secondary biotite and K- feldspar). Rhenium concentrations in molybdenite are between 330 and 730 ppm. Two molybdenite samples from the quartz monzonite and porphyritic quartz monzonite provide a Re-Os isotope age of 71.7 ± 0.3 Ma. A third sample from a molybdenite vein in Precambrian rocks yields an age of 75.8 ± 0.4 Ma. These molybdenite ages support previous suggestions of two mineralization episodes in the Bagdad deposit. An early event at 76 Ma and a later episode at 72 Ma. Pyrite Os and Re concentrations range between 0.008-0.016 and 3.9-6.8 ppb, respectively. Chalcopyrite contains a wide range of Os (6 to 91 ppt) and Re (1.7 to 69 ppb) concentrations and variable ¹⁸⁷Os/¹⁸⁸Os ratios that range between 0.13 to 22.27. This variability in the chalcopyrite data may be attributed to different copper sources, one of them the Proterozoic volcanic massive sulfides in the district, or to alteration and remobilization of Re and Os. Analyses from two pyrite samples yield an eight point isochron with an age of 77 ± 15 Ma and an initial ¹⁸⁷Os/¹⁸⁸Os ratio of 2.12. This pyrite Re-Os isochron age is in good agreement with the molybdenite ages. We interpret the highly radiogenic initial 1870s/188Os as an indication that the source of Os and, by inference, the ore-forming elements for the Bagdad deposit, was mainly the crust. This conclusion agrees with previous Pb and Nd isotope studies and supports the notion that a significant part of the metals and magmas have a crustal source.

absolute age

Arizona

Bagdad deposit

Cenozoic

chemical composition

copper ores

Cretaceous

dates

deformation

geochemistry

hydrothermal alteration

igneous rocks

intrusions

isotope ratios

isotopes

Laramide Orogeny

lithostratigraphy

magmatism

Mesozoic

metal ores

metallogeny

metals

metamorphic rocks

metasomatism

mineral composition

mineral deposits, genesis

mineral exploration

mineralization

molybdenum ores

northern Arizona

Os-188 / Os-187

osmium

Paleogene

paragenesis

platinum group

plutonic rocks

porphyry copper

quartz monzonite

radioactive isotopes

Re-187 / Os-188

Re / Os

rhenium

stable isotopes

sulfides

tectonics

Tertiary

United States

Upper Cretaceous

veins

La suite complexe des mégacristaux des kimberlites de Mbuji-Mayi en République Démocratique du Congo: témoins du métasomatisme dans le manteau lithosphérique sous-continental archéen du craton du Congo-Kasaï / Complex megacryst suite of the Mbuji-Mayi kimberlites in Democratic Republic of Congo: evidence for metasomatism in the archean subcontinental lithospheric mantle of the Congo-Kasai craton

Pivin, Marjorie

24 May 2012

L’origine des suites de mégacristaux des kimberlites est sujette à d’intenses débats depuis de nombreuses années. La suite complexe de mégacristaux (grenat, clinopyroxène, zircon, baddeleyite, ilménite, rutile et nodules d’intercroissances rutile-silicates) des kimberlites diamantifères de Mbuji-Mayi (Kasaï Oriental), mises en place au Crétacé dans le craton archéen du Congo-Kasaï, a été étudiée en détails dans le but d’établir les relations entre les différents minéraux de la suite, leur relation au magma kimberlitique-hôte et au manteau lithosphérique cratonique archéen. L’étude des mégacristaux de grenat des kimberlites pauvres en diamants du Kundelungu (Katanga) a permis en outre d’établir la comparaison entre les mégacristaux de deux provinces kimberlitiques en République Démocratique du Congo, qui diffèrent notamment par leur âge de mise en place et par la composition et l’âge du socle traversé. <p>L’ensemble des données minéralogiques et géochimiques acquises (éléments majeurs et en traces, géochimie isotopique de l’oxygène, du Nd et de l’Hf) est intégré dans le but de déterminer la nature du (ou des) processus qui a (ont) donné naissance à ces suites de mégacristaux. <p>En parallèle, l’origine d’un xénolite rare de clinopyroxénite à kyanite exceptionnellement riche en Cr des kimberlites de Mbuji-Mayi a été explorée.<p>Bien qu’ils partagent de nombreuses caractéristiques avec d’autres suites de mégacristaux kimberlitiques, les mégacristaux de RDC sont généralement enrichis en Cr et appauvris en Fe et Ti, et ne présentent pas de preuve d’une origine par cristallisation fractionnée à partir d’un magma, ce qui permet de suggérer une origine différente, en l’occurrence une liaison plus directe avec le manteau lithosphérique réfractaire local lors de leur formation. Une origine métasomatique par interaction entre un liquide/fluide précurseur de la kimberlite et les péridotites du manteau lithosphérique est donc favorisée. L’ensemble des espèces minérales qui forme la suite de mégacristaux peut en effet trouver un équivalent compositionnel dans les lithologies métasomatisées de la lithosphère mantélique. <p>Les mégacristaux de grenat des deux provinces partagent des similarités frappantes qui sont interprétées en termes de processus de formation similaires. En revanche, ils ont systématiquement montré un comportement géochimique singulier, suggérant un processus de formation différent des autres mégacristaux. Ils semblent en effet avoir retenu l’héritage des compositions variables d’anciens protolites de grenat affectés récemment par un métasomatisme de type kimberlitique. Ces grenats résultent de la recristallisation de grenats initialement présents dans les péridotites cratoniques de la lithosphère archéenne. Par contre, les mégacristaux de clinopyroxène, zircon, baddeleyite, ilménite, rutile et les nodules d’intercroissances rutile-silicates se sont effectivement formés récemment par l’interaction métasomatique entre le liquide/fluide proto-kimberlitique et les péridotites cratoniques. Des variations locales du rapport (fluide et/ou liquide)/roche et de l’activité en SiO2 lors de la percolation du magma proto-kimberlitique asthénosphérique dans le manteau lithosphérique cratonique, couplées à la nature propre à la kimberlite de la région, permettent d’intégrer l’ensemble des mégacristaux dans un modèle pétrogénétique commun, avec des processus de formation parfois contrastés. <p> / Doctorat en Sciences / info:eu-repo/semantics/nonPublished

Sciences de la terre et du cosmos

Sciences exactes et naturelles

Metasomatism (Mineralogy)

Cratons -- Congo (Democratic Republic)

Métasomatose (Minéralogie)

xénolites mantéliques/mantle xenoliths

Afrique Centrale/ Cental Africa

Géochimie/Geochemistry

Minéralogie/Mineralogy

Pétrologie/Petrology

racines cratoniques/cratonic roots