Manganese minerals and associated fine particulates in the streambed of Pinal Creek,Arizona, U.S.A.: a mining-related acid drainage problem

The Pinal creek drainage basin in Arizona is a good example of the principal non-coal source of mining-related acid drainage in the U.S.A., namely copper mining. Infiltration of drainage waters from mining and ore refining has created an acid groundwater plume that has reacted with calcite during passage through the alluvium, thereby becoming less acid. Where O₂ is present and the water is partially neutralized, iron oxides have precipitated and, farther downstream where the pH of the stream water is near neutral, high-Mn crusts have developed.Trace metal composition of several phases in the Pinal Creek drainage basin illustrates the changes caused by mining activities and the significant control Mn-crusts and iron oxide deposits exert on the distribution and concentration of trace metals. The phases and locales considered are the dissolved phase of Webster Lake, a former acid waste disposal pond; selected sections of cores drilled in the alluvium within the intermittent reach of Pinal Creek; and the dissolved phase, suspended sediments, and streambed deposits at specified locales along the perennial reach of Pinal creek.In the perennial reach of Pinal Creek, manganese oxides precipitate from the streamflow as non-cemented particulates and coatings of streambed material and as cemented black crusts. Chemical and X-ray diffraction analyses indicate that the non-cemented manganese oxides precipitate in the reaction sequence observed in previous laboratory experiments using simpler solution composition, Mn₃O₄ to MnOOH to an oxide of higher oxidation number usually <4.0, i.e. Na-birnessite, and that the black cemented crusts contain (Ca,Mn,Mg)CO₃ and a 7-Åphyllomanganate mixture of rancieite ((Ca,Mn)Mn₄O₉ · (3H₂O)) and takanelite ((Mn,Ca)Mn₄O₉ · (3H₂O)). In the laboratory, aerating and increasing the pH of Pinal Creek water to 9.00 precipitated (Ca,Mn,Mg)CO₃ from an anoxic groundwater that contained CO₂ HCO₃, and precipitated Mn₃O₄ and subsequently MnOOH from an oxic surface water from which most of the dissolved CO₂ had been removed.It is suggested that the black cemented crusts form by precipitation of Fe on the Mn-enriched carbonates, creating a site for the MnFe oxidation cycle and thus encouraging the conversion of the carbonates to 7-Åphysllomanganates. The non-magnetic <63-μm size-fractions of the black cemented crusts consisted mostly of the manganese-calcium oxides but also contained about 20% (Ca,Mn,Mg)CO₃, 5% Fe (calculated as FeOOH), 2–4% exchangeable cations, and trace amounts of several silicates.     

Paleontological analysis of a lacustrine carbonaceous uranium deposit at the Anderson mine, Date Creek basin, west-central Arizona (U.S.A.)

The Tertiary sedimentary sequence of the Date Creek basin area of Arizona is composed principally of intertonguing alluvial-fan and lacustrine deposits. The lacustrine rocks contain large intermediate- to, locally, high-grade uranium deposits that form one of the largest uranium resources in the United States (an estimated 670,000 tons of U₃O₈ at an average grade of 0.023% is indicated by drilling to date). At the Anderson mine, about 50,000 tons of U₃O₈ occurs in lacustrine carbonaceous siltstones and mudstones (using a cutoff grade of 0.01%). The Anderson mine constitutes a new class of ore deposit, a lacustrine carbonaceous uranium deposit.Floral and faunal remains at the Anderson mine played a critical role in creating and documenting conditions necessary for uranium mineralization. Organic-rich, uraniferous rocks at the Anderson mine contain plant remains and ostracodes having remarkably detailed preservation of internal features because of infilling by opaline silica. This preservation suggests that the alkaline lake waters in the mine area contained high concentrations of dissolved silica and that silicification occurred rapidly, before compaction or cementation of the enclosing sediment. Uranium coprecipitated with the silica. Thinly laminated, dark-colored, siliceous beds contain centric diatoms preserved with carbonaceous material suggesting that lake waters at the mine were locally deep and anoxic. These alkaline, silica-charged waters and a stagnant, anoxic environment in parts of the lake were necessary conditions for the precipitation of large amounts of uranium in the lake-bottom sediments.Sediments at the Anderson mine contain plant remains and pollen that were derived from diverse vegetative zones suggesting about 1500 m of relief in the area at the time of deposition. The pollen suggests that the valley floor was semiarid and subtropical, whereas nearby mountains supported temperate deciduous forests.     

Geochemical models of the impact of acidic groundwater and evaporative sulfate salts on Boulder Creek at Iron Mountain,California

During dry season baseflow conditions approximately 20% of the flow in Boulder Creek is comprised of acidic metals-bearing groundwater. Significant amounts of efflorescent salts accumulate around intermittent seeps and surface streams as a result of evaporation of acid rock drainage. Those salts include the Fe-sulfates — rhomboclase ((H₃O)Fe³⁺(SO₄)₂·3H₂O), ferricopiapite (Fe³⁺₅(SO₄)₆O(OH)·20H₂O), and bilinite (Fe²⁺Fe₂³⁺(SO₄)₄·22H₂O); Al-sulfates — alunogen (Al₂(SO₄)₃·17H₂O) and kalinite (KAl(SO₄)₂·11H₂O); and Ca- and Mg-sulfates — gypsum (CaSO₄·2H₂O), and hexahydrite (MgSO₄·6H₂O). The dissolution of evaporative sulfate salt accumulations during the first major storm of the wet season at Iron Mountain produces a characteristic hydrogeochemical response (so-called “rinse-out”) in surface waters that is subdued in later storms. Geochemical modeling shows that the solutes from relatively minor amounts of dissolved sulfate salts will maintain the pH of surface streams near 3.0 during a rainstorm. On a weight basis, Fe-sulfate salts are capable of producing more acidity than Al- or Mg-sulfate salts. The primary mechanism for the production of acidity from salts involves the hydrolysis of the dissolved dissolved metals, especially Fe³⁺. In addition to the lowering of pH values and providing dissolved Fe and Al to surface streams, the soluble salts appear to be a significant source of dissolved Cu, Zn, and other metals during the first significant storm of the season.     

Geochemical exploration for mineralized breccia pipes in northern Arizona,U.S.A.

Thousands of solution-collapse breccia pipe crop out in the canyons and on the plateaus of northern Arizona. Over 80 of these are known to contain U or Cu mineralized rock. The high-grade U ore associated with potentially economic concentrations of Ag, Pb, Zn, Cu, Co and Ni in some of these pipes has continued to stimulate mining and exploration activity in northern Arizona, despite periods of depressed U prices. Large expanses of northern Arizona are comprised of undissected high plateaus; recognition of pipes in these areas is particularly important because mining access to the plateaus is far better than to the canyons. The small size of the pipes, generally less than 600 ft (200 m) in diameter, and limited rock outcrop on the plateaus, compounds the recognition problem. Although the breccia pipes, which bottom in the Mississippian Redwall Limestone, are occasionally exposed on the plateaus as circular features, so are unmineralized near-surface collapse features that bottom in the Permian Kaibab and Toroweap Formations. The distinction between these two classes of circular features is critical during exploration for this unique type of U deposit.Various geochemical and geophysical exploration methods have been tested over these classes of collapse features. Because of the small size of the deposits, and the low-level geochemical signatures in the overlying rock that are rarely dispersed for distances in excess of several hundred feet, most reconnaissance geochemical surveys, such as hydrogeochemistry or stream sediment, will not delineete mineralized pipes.Several types of detailed geochemical surveys made over collapse features, located through examination of aerial photographs and later field mapping, have been successful at delineating collapse features from the surrounding host rock: (1) Rock geochemistry commonly shows low level Ag, As, Ba, Co, Cu, Ni, Pb, Se and Zn anomalies over mineralized breccia pipes; (2) Soil surveys appear to have the greatest potential for distinguishing mineralized breccia pipes from the surrounding terrane. Although the soil anomalies are only twice the background concentrations for most anomalous elements, traverses made over collapse features show consistent enrichment inside of the feature as compared to outside; (3) B. Cereus surveys over a known mineralized pipe show significantly more anomalous samples collected from within the ring fracture than from outside of the breccia pipe; (4) Helium soil-gas surveys were made over 7 collapse features with discouraging results from 5 of the 7 features.Geophysical surveys indicate that scaler audio-magnetotelluric (AMT) and E-field telluric profile data show diagnostic conductivity differences over mineralized pipes as compared to the surrounding terrane. These surveys, coupled with the geochemical surveys conducted as detailed studies over features mapped by field and aerial photograph examination, can be a significant asset in the selection of potential breccia pipes for drilling.     

Platform and off-platform carbonates of the Upper Cambrian of western Maryland, U.S.A.

Upper Cambrian carbonates in western Maryland are comprised of platform facies (Conococheague Limestone) west of South Mountain and basin facies (Frederick Limestone) east of South Mountain. Conocheague platform carbonates contain interbedded non-cyclic and cyclic facies. Non-cyclic facies consist of cross-stratified grainstones, thrombolitic bioherms, and graded, thin-bedded dolostones. These were deposited in shallow, subtidal shelf lagoons. Cyclic facies are composed of repeated sequences of cross-stratified grainstone; ribbon-rock; wavy, prism-cracked laminite; and planar laminated dolostone. The cyclic facies are shallowing-upward cycles produced by lateral progradation of tidal flats over shallow, nearshore subtidal environments. Cyclic and non-cyclic facies are interbedded in the Conococheague in a layer cake fashion, but no higher-order cyclicity can be found. The Frederick Limestone is dominated by monotonously thick sequences of graded, thin-bedded limestones, interbedded with massive peloidal grainstones and beds of breccia up to 10 m thick in the lower Frederick. The breccias contain transported megaclasts of Epiphyton-Girvanella boundstones. The basal Frederick was deposited in a slope-to-basinal setting east of a rimmed shelf. An Epiphyton-Girvanella marginal reef along the shelf edge was the source of the blocks in the breccias. The upper Frederick Limestone formed on a carbonate ramp.     

Photonic dating of prehistoric irrigation canals at Phoenix,Arizona, U.S.A.*

A number of archeological features, including in‐filled irrigation canals of uncertain prehistoric age, occur within the Holocene floodplain of the Salt River at Phoenix, Arizona. In the first attempt to date irrigation‐canal sediments using luminescence methods, we obtained age estimates of 1640 ± 190 yr B.P. (1σ) (multi‐aliquot or MA) and 1621 ± 95 yr B.P. (post‐IR single‐aliquot‐regenerative‐dose or SAR) for a single sample from the base of the oldest canal‐infilling deposits (all IR‐PSL ages reported in this article are in calendar years before A.D. 2001). For the remaining canal samples, weighted mean luminescence ages of 819 ± 45 yr (MA) and 826 ± 32 yr (post‐IR SAR) were obtained. Thus from photonic dating we can resolve the first and last phases of canal use at this Phoenix site: initiation at ca. 1600 years ago and final use at ca. 800 years ago. These results demonstrate the power of SAR luminescence sediment dating to enhance our understanding of prehistoric irrigation‐canal development and usage here and elsewhere in the world. © 2004 Wiley Periodicals, Inc.     

Burial of reefs by shallow-water carbonates,Silurian Gower formation,Iowa, U.S.A.

The Gower Formation was deposited in two main stages. In the first, crinoid-coelenterate reef complexes, consisting of numerous closely spaced mounds, developed to maximum relief in water about 30 metres deep initially. Complexes are asymmetrical: the well defined windward Marginal Zone has pronounced local relief; the flatter, more extensive Leeward Zone fans out behind a high central area. Equivalent off-reef beds, where correlation is clear, consist of relatively fine skeletal dolomite.The second-stage deposits record a fall in sea level and the filling of first-stage topographic lows by progressively shallower-water sediments. These were mainly laminated carbonate muds and fine sands (Brady/Anamosa facies group). In the Marginal Zone these were deposited at first as steep wedge-beds on earlier mound flanks, together with a distinctive fauna and scattered stromatolites (Brady facies). Mounds expanded laterally while developing a platform on top. Poorly fossiliferous, flatter-lying beds (Laminate-Anamosa) subsequently filled remaining inter-mound hollows. Equivalent deposits in the Leeward Zone consist almost entirely of Laminate-Anamosa. Off-reef equivalents are probably generally similar.The second stage of Gower deposition ended with the accumulation across inter-complex basins of extensive uniform sheets of stromatolites and subordinate laminated muds (Crenulate-Anamosa). Near the reefs Crenulate-Anamosa overlies Laminate-Anamosa; in basin centres it lies directly on beds of the first depositional stage. The stromatolites are believed to have originated in very shallow, perhaps tideless, water with restricted circulation and high salinity.The shallow-water origin of these sediments suggests that reef tops were exposed during second-stage deposition, and consequently accumulated little or no sediment. Filled caves and a slightly earlier erosion surface tend to support this interpretation.

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Zusammenfassung Die Sedimente der silurischen Gower-Formation im Staate Iowa wurden in zwei Phasen abgelagert. Während der ersten entwickelte sich in Krinoiden-Coelenteraten Riffkomplexe aus vielen nah benachbarten Kuppen ein Relief in ursprünglich 30 m Wassertiefe. Die Riffkomplexe sind asymmetrisch: die gut definierte Randzone in Windrichtung hat ein ausgeprägtes Detailrelief; hinter einer zentralen Erhebung erstrecken sich die weniger steilen und ausgedehnteren Fächer der Lee-Zone. Soweit korrelierbar, bestehen die riffernen Sedimente aus relativ feinem skeletalem Dolomit.Die Ablagerungen der zweiten Phase repräsentieren eine Senkung des Meeresspiegels; die topographisch tieferen Teile des vorhandenen Reliefs werden mit Sedimenten aus immer geringerer Wassertiefe gefüllt, hauptsächlich mit laminierten Karbonatschlammen und Feinsanden (Brady/Anamosa-Fazies-Gruppe). In der Randzone wurden sie zunächst als steile keilförmige Schichten auf Kuppenhängen abgelagert (Brady/Fazies); diese enthalten eine charakteristische Fauna und einzelne Stromatolithe. Die Kuppen verbreiterten sich entsprechen zu Plateaus. Fossilarme, flacher liegende Schichten (laminierte Anamosa-Fazies) füllten dann die Restsenken zwischen den Kuppen. Die entsprechenden Ablagerungen der Lee-Zone gehören fast ausschließlich zur letzteren Fazies, und rifferne Sedimente sind wahrscheinlich im allgemeinen ähnlich.Am Ende der zweiten Phase der Gower-Formation wurden ausgedehnte einförmige Schichten von Stromatolithen und — untergeordnet — laminierten Schlammen (gewellte Anamosa-Fazies) in den Becken zwischen den Riffkomplexen abgelagert. In Riffnähe wird die laminierte von der gewellten Anamosa-Fazies überdeckt, im Beckenzentrum folgt die letztere direkt auf die Ablagerungen der ersten Phase. Für die Stromatolith-Bildung wird sehr flaches, vielleicht gezeiten-loses Wasser mit beschränkter Zirkulation und hoher Salinität angenommen.Bei Ablagerung dieser Sedimente im Flachwasser müssen die Riffoberflächen während der zweiten Phase trocken gelegen haben, weshalb sie mit wenig oder keinem Sediment überdeckt wurden. Hohlraumfüllungen und eine wenig ältere Erosionsfläche scheinen diese Interpretation zu unterstützen.

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Résumé Les sédiments de la formation silurienne Gower dans l'état Iowa furent déposés en deux phases. Pendant la première phase, il se forma un relief, à partier de nombreux pitons sous-marins voisins, dans les complexes de récifs de crinoïdes-coelentérés à l'intérieur d'une profondeur d'eau originelle de 30 m. Les complexes de récifs sont asymétriques. La zone de bordure, bien définie dans la direction du vent, possède un relief de détails marqué; derrière une élévation centrale s'étendent les surfaces moins escarpées et allongées de la zone »Lee«. S'il est possible de les comparer, les sédiments des récifs se composent de dolomites relativement fines.Les dépôts de la deuxième phase représentent un affaissement du niveau de la mer. Les parties topographiques profondes du relief présent seront comblées par des sédiments provenant de profondeurs d'eau toujours plus petites, principalement avec des vases de carbonates en lamelles et des sables fins (groupe de faciès »Brady/Anamosa«). Dans la zone de bordure, ces sédiments furent d'abord déposés sous forme de strates abruptes et cunéiformes sur les versants des coupoles (faciès Brady); ils contiennent une faune caractéristique et des »Stromatolites« particulières. Les coupoles s'étendirent pour se transformer en plateau. Puis, les couches plus basses, pauvres en fossiles (faciès en lamelles Anamosa), remplirent les depressions restantes entre les coupoles. Les dépôts correspondants de la zone »Lee« appartiennent, d'une manière presque exclusive, au dernier faciès et les sédiments loins des récifs sont en général, vraisemblablement, similaires.A la fin de la deuxième phase de la formation Gower, des couches de »Stromatolites« étendués et uniformes ainsi que des vases en lamelles subordonnées (faciès ondulés Anamosa) furent déposées dans les bassins entre les complexes de récifs. A proximité des récifs, le faciès en lamelles sera recouvert par le faciés ondulé Anamosa; dans le centre du bassin, le dernier faciès suit immédiatement les dépôts de la première phase. Pour la formation de »Stromatolites« on présume l'action d'eau à bas niveau, peut être sans marées, mais avec des courants limités et de la salinités élevée.Pendant la sédimentation de ces couches dans l'eau basse, les surfaces des récifs doivent avoir été à sec durant la deuxième phase. C'est pourquoi elles ne sont couvertes que de peu de sédiment ou pas du tout. Le remplisage de cavernes et une surface d'érosion un peu plus ancienne semblent supporter cette interprétation.

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Impact of agricultural development on regional drainage in the lower Santa Cruz valley,Arizona, U.S.A.

The development of irrigation agriculture on valley floors in the southwestern United States has substantially altered natural drainage systems. This study discusses five anthropogenic factors that have altered the hydrologic function of a dryland basin floor in south-central Arizona. These factors are: (1) upstream urbanization and channel entrenchment, (2) dam construction, (3) artificial diversion of drainage, (4) obstruction of flow by transportation routes, and (5) stream channelization. The first two factors have altered hydrologic inputs to the basin floor, the third and fourth factors have changed regional and local patterns of flooding, and the fifth factor has resulted in channel instability and reduced flood attenuation. These five factors, along with a recent increase in the frequency of incursions of tropical moisture into southern Arizona, have enhanced flow variability and the potential for devastating flooding on the basin floor. This research demonstrates the need for basin-wide approaches to stream management in drylands and illustrates the importance of basing management decisions on geomorphic information concerning fluvial forms and processes.     

Interaction of Continental Lithosphere and Asthenospheric Melts below the Geronimo Volcanic Field, Arizona, U.S.A

Spinel lherzolite and pyroxenite inclusions from the Geronimovolcanic field, Arizona (and Dish Hill, California) record,in their constituent minerals, a chronology of diverse mantledepletion and enrichment events. Certain portions of the lithosphericmantle have remained relatively isolated for considerable periodsof time(1–4 b.y.) while wall rock adjacent to conduitsof basanite has been recently (< 0-2 b.y.) modified. Evidenceexists for a widespread ancient (1–4 b.y.) partial meltingresidue, now recognizable as MORB-like mantle below the southwesternU.S.A. Trace element enrichment (0?9 b.y.) has increased thelight rare earth element (LREE) and Sr content of many refractoryperidotites without any mineralogical changes to the host rock.The fluids/melt responsible for this enrichment have a complexhistory involving heterogeneous mantle sources. In contrast,modal metasomatism of the mantle (< 0.2 b.y.) in aureolesaround evolved derivatives of basanite has petrographicallyand chemically transformed this ancient partial melting residue.The metasomatic fluids responsible for such metasomatism havean asthenospheric mantle source identical to the host magma.It is proposed that modal metasomatism occurs in contact metamorphicaureoles that surround apophyses of basanitic silicate meltin the lithospheric mantle. The gradient in CO₂/(CO₂ ? H₂O)ratio that must surround such veins in the upper mantle (<20 kb) may encourage the development of enrichment fronts. Immediatelyadjacent to the vein, a wet zone with a relatively low CO₂/(CO₂? H₂O) ratio would allow a precipitation of mica ? amphibole.Beyond this a dry zone with a higher CO₂/(CO₂ ? H₂O) ratio wouldhasten chemical but not petrographic transformation of the wallrock.     

Geoarchaeology and Paleoenvironmental Context of the Burntwood Creek Rockshelter,High Plains of Northwestern Kansas,U.S.A

The first systematic geoarchaeological study of a rockshelter in Kansas yielded information about rockshelter formation, Holocene paleoenvironments, archaeological site formation processes, and prehistoric human habitation and site use. The rockshelter was carved by groundwater sapping; colluvium, alluvium, and roof‐fall debris subsequently accumulated on its floor. An assemblage of Late Archaic (∼2000–4000 ¹⁴C years before present [yr B.P.]) cultural deposits (lithic material, bone, and charcoal) is preserved in a 2‐m thick package of colluvium and alluvium in front of the shelter. Chipped stone analysis indicates that Late Archaic occupants of the shelter were using mostly local materials and resharpening their stone tools at the shelter. Stable carbon isotope and phytolith analyses indicate that a mixed C₃ and C₄ plant community existed in the study area and that it changed in composition through the late Holocene. Based on the phytolith assemblage from an unlined fire pit at the front of the shelter, Late Archaic people used local hackberry trees for fuel and/or food.     

Geochemical and isotopic characteristics of lower crustal xenoliths, San Francisco Volcanic Field, Arizona, U.S.A

A wide variety of xenoliths has been entrained in Miocene-to-Recent alkali olivine and hypersthene-normative basalts in the San Francisco Volcanic Field (SFVF), northern Arizona, U.S.A. Based on petrography, mineralogy, bulk rock chemistry and Sr-Nd isotopic characteristics, SFVF xenoliths can be divided into two major groups: cumulates and granulites. The cumulates are genetically related to the Cenozoic volcanic rocks and represent under- and/or intraplated additions to the crust of the Colorado Plateau. Assemblages are mafic to ultramafic and are dominated by clinopyroxene-orthopyroxene-plagioclase-spinel-amphibole-olivine. The granulites are probably Proterozoic in age, mafic-to-intermediate/felsic in bulk composition, either two pyroxene-plagioclase-spinel or plagioclase-alkali feldspar-quartz-magnetite-amphibole-biotite assemblages. Many of the granulites show evidence of partial melting. Some high SiO₂, very high Rb/Sr glasses are close in composition to erupted rhyolites, and probably represent end-member melts that have interacted with basalt to produce a variety of hybrid intermediate lavas. The major element, trace element and Sr-Nd isotope geochemistry is highly variable in the SFVF xenoliths. Extremely high Ba contents and Ba/Nb of a number of the granulites are equivalent to values characteristics of modern supra-subduction zone magmas. The considerable variation of chemical and isotopic composition depends upon mineral proportions, assemblages and chemistry. Isotopically, three end-members can be identified within the granulites: (i) lowest ⁸⁷Sr/⁸⁶Sr (0.702870) with low ¹⁴³Nd/¹⁴⁴Nd (0.511541, εNd-21.4); (ii) high ⁸⁷Sr/⁸⁶Sr (0.711069) with the lowest ¹⁴³Nd/¹⁴⁴Nd (0.511434, εNd-23.5); (iii) highest ⁸⁷Sr/{86}Sr (0.715306) with low ¹⁴³Nd/¹⁴⁴Nd (0.511793, εNd-16.5). Two important age ranges deduced from the isotopic data probably relate to episodes of crustal-growth beneath the SFVF (1.88 ± 0.33 Ga and Cenozoic). Thermobarometric calculations assuming equilibrium show that the xenoliths are derived from the lower crust (0.6–1.3 GPa, 850–1050 °C). The average SFVF lower crust is mafic in composition. In the absence of partial lithospheric delamination, the lower crust may become mafic with time due to under- and intraplating of continental crust by mafic magmas derived from the mantle.     

Challenges of governing groundwater in U.S. western states

Over the last several decades, water users in the western United States have increasingly turned to groundwater resources to support economic development, but few institutional arrangements were in place to govern groundwater use. Over time, numerous groundwater problems have emerged. Two closely related explanations for this are explored. Surface water sources were the first to be developed, and institutional arrangements to allocate surface water were the first to be devised. These arrangements are not particularly well suited for governing groundwater. Furthermore, the physical differences between rivers and aquifers lead to differences in the development of each type of water, and in production and organization costs. Groundwater development involves low upfront production costs, which individual water users can cover. Once groundwater users have individually invested in productive activities problems emerge, such as declining water tables. Thus, unlike surface water users, groundwater users are faced with devising institutional arrangements to coordinate their water uses after they have invested in and developed productive economic activities. Most western states regulate pumping, although groundwater users, in general, resist pumping limits. The discussion concludes with proposals for modifying the prior appropriation doctrine to better accommodate the active management of groundwater basins for long-term sustainability.

The hydrologic effects of intense groundwater pumpage in east-central Hillsborough County,Florida, U.S.A.

Well problems, water shortages, local flooding, and induced sinkholes have been periodic problems for residents in east-central Hillsborough County, Florida. This agricultural area has experienced dramatic short-term water-level declines in the Floridan aquifer from seasonal groundwater withdrawals. The sudden declines in the potentiometric surface have been caused from intense irrigation pumpage, primarily for frost and freeze protection and fruit setting. Citrus and strawberry crops are protected from occasional freezes by the application of warm groundwater to maintain minimum soil temperatures of 32°F(0°C). Local residents with inadequately constructed wells lose their source of water when the potentiometric surface is lowered to depths where their wells do not function. Some residents have lost their water supply for a week or more, and many have incurred damage to their pumps. The drawdown of the potentiometric surface in some areas has induced sinkholes causing property damage for some residents and concern for others. In addition, the high application rates for frost and freeze irrigation have created run-off problems resulting in local flooding to some residents. Fortunately, there has been no damage to resident homes from the flooding or sinkholes. This report summarizes the area's hydrogeology, and the consequences of heavy freeze irrigation. A finite-difference, numerical model is used to quantify the regional impacts to the potentiometric surface of the Floridan aquifer from estimated irrigation pumpage. Management recommendations for alleviating the problems are also discussed in the report.     

Partitioning of copper and zinc in the sediments and porewaters of a high-elevation alkaline lake,east-central Arizona,U.S.A.

In Pacheta Lake, a high-elevation alkaline lake proximal to the smelting region of southern Arizona-New Mexico, concentrations of transition metal ions in pore waters and co-existing sediments were compared. Copper, Fe, Mn and Zn have been partitioned among operationally defined sediment solid phases (exchangeable sites, organic complexes, amorphous oxides, crystalline oxides, sulfides and residual silicates) and their concentrations in interstitial waters were measured. Concentrations are reported as a function of depth in the sediment column. The diagenetic environment is described and cycling mechanisms postulated for the above metals.Selective, sequential extraction of metals from lake sediments showed different binding mechanisms for Cu and Zn, the former most strongly associated with organic complexes, and the latter with iron oxyhydroxides. This difference has strong implications for selective metal remobilization under variable environmental conditions, both naturally and anthropogenically induced. Copper and zinc in porewaters were estimated to diffuse to overlying waters at 12.8 and 21.9 μg/cm²/a, respectively. These fluxes are large enough to account for observed concentrations of Cu and Zn in overlying waters. No sediment metal contamination was directly attributable to smelting activity. However, this study does document a flux from sediments, which have accumulated Cu and Zn, to overlying waters no longer receiving trace metal deposition from now inactive smelters.     

Geochemical signatures of possible deep-seated ore deposits in Tertiary volcanic centers, Arizona and New Mexico, U.S.A.

A reconnaissance geochemical survey of stream drainages within 21,000 km² of southeastern Arizona and southwestern New Mexico shows broad zones of low-level to moderate contrast anomalies, many associated with mid-Tertiary eruptive centers and Tertiary fault zones. Of these eruptive centers, few are known to contain metallic deposits, and most of those known are minor. This, however, may be more a function of shallow erosion level than an indication of the absence of mineralization, since hydrothermal alteration and Fe-Mn-oxide staining are widespread, and geochemical anomalies are pervasive over a larger part of the region than outcrop observations would predict. Accordingly, interpretations of the geochemical data use considerations of relative erosion levels, and inferred element zonalities, to focus on possible undiscovered deposits in the subsurface of base-, precious-, and rare-metal deposits of plutonic-volcanic association. In order to enhance the identification of specific deep targets, we use the empirically determined ratio: This ratio is based on reported metal contents of nonmagnetic heavy-mineral samples from the drainage sediment, determined by emission spectrographic analysis. Before the ratio was computed for each sample site, the data were normalized to a previously estimated regional threshold value. A regional isopleth map was then prepared, using a cell-averaging computer routine, with contours drawn at the 25th, 50th, 75th, 80th, 90th, 95th and 99th percentiles of the computed data.     

Substrate Influences on Step-Pool Sequences in the Christopher Creek Drainage, Arizona

Step-pool sequences formed in alluvial and bedrock channel segments of the Christopher Creek drainage in central Arizona suggest that bedform geometries may reflect subtle differences in relative substrate resistance and in the ratio of driving forces to resisting forces. Three alluvial channel segments and two bedrock channel segments along a 72-km2 drainage and a 4-km2 drainage facilitated comparison across different substrates and hydraulic environments. As substrate resistance increased or the ratio of hydraulic driving forces and boundary resisting forces decreased, channel gradient increased, the ratio of step height to length normalized by gradient decreased, and pool dimensions normalized by gradient decreased. These changes in bedform geometry suggest that as the ratio of driving to resisting forces increases, proportionally more flow energy is dissipated within the flow as turbulence and shearing (as in the alluvial reaches) rather than being applied to erosion of the channel boundaries (as in the bedrock reaches).     

The paleoecology and archaeology of long‐term water storage in a Hohokam reservoir,southwestern Arizona,U.S.A.

Water storage reservoirs were an important feature of economic organization among ancient societies in the North American Southwest. Analyses of reservoir sediments from a Hohokam archaeological site in the Sonoran Desert yielded taxonomic species of ostracodes (microscopic crustaceans) and pollen grains that are indicative of a past water‐rich environment. The discovery that this reservoir was capable of storing water on a long‐term basis indicates that archaeological models for the region, which have relied on direct historic analogy, must be reexamined. In contrast to the local ethnographic record, paleoecological data generated by this study imply that the Hohokam could establish permanent desert settlements with water storage reservoirs away from perennial rivers and streams. Moreover, residents of these areas were geographically positioned to facilitate the circulation of marine resources (i.e., salt and shell) from the Gulf of California to territories within and beyond the Hohokam region. © 2004 Wiley Periodicals, Inc.     

Use of 234U and 238U isotopes to evaluate contamination of near-surface groundwater with uranium-mill effluent: a case study in south-central Colorado, U.S.A.

The ²³⁴U/²³⁸U alpha activity ratio (AR) was determined in 47 samples of variably uraniferous groundwater from the vicinity of a uranium mill near Cañon City, Colorado. The results illustrate that uranium isotopes can be used to determine the distribution of uranium contamination in groundwater and to indicate processes such as mixing and chemical precipitation that affect uranium concentrations. Highly to moderately contaminated groundwater samples collected from the mill site and land immediately downgradient from the mill site contain more than 100?μg/l of dissolved uranium and typically have AR values in the narrow range of 1.0–1.06. Other samples from the shallow alluvial aquifer farther downgradient from the mill contain 10–100?μg/l uranium and plot along a broad trend of increasing AR (1.06–1.46) with decreasing uranium concentration. The results are consistent with mixing of liquid mill waste (AR≈1.0) with alluvial groundwater of small, but variable, uranium concentrations and AR of 1.3–1.5. In the alluvial aquifer, the spatial distribution of wells with AR values less than 1.3 is consistent with previous estimates of the probable distribution of contamination, based on water chemistry and hydrology. Wells more distant from the area of probable contamination have AR values that are consistently greater than 1.3 and are indicative of little or no contamination. The methodology of this study can be extended usefully to similar sites of uranium mining, milling, or processing provided that local geohydrologic settings promote uranium mobility and that introduced uranium contamination is isotopically distinct from that of local groundwater.     

The zonal distribution of selected elements above the Kalamazoo porphyry copper deposit, San Manuel district, Pinal County, Arizona

There may be many as-yet-undiscovered porphyry copper deposits that exist as blind deposits deep within exposed rock bodies. The Kalamazoo porphyry copper-molybdenum deposit is a blind deposit present at depths up to at least 1,000 m (about 3,200 ft) that contains zoning features common to many of the known porphyry copper deposits found in western North and South America.As the preliminary phase in a geochemical study of the Kalamazoo deposit, whole-rock samples of core and cuttings from two drill holes have been analyzed for 60 different elements. Each hole represents a different major rock unit and each has penetrated completely through all the existing alteration zones and the ore zone.Plots of concentration vs. depth for 17 selected elements show distinct high- or low-concentration zones that are spatially related to the ore zone. For most of the ore-related elements no significant correlation with the two lithologies is apparent. The spatial distribution and abundance of elements such as Co, Cu, S, Se, Mn, Tl, Rb, Zn, B, and Li may be useful in determining the direction for exploration to proceed to locate a blind deposit. Trace element studies should be valuable in evaluating areas containing extensive outcrops of rocks with disseminated pyrite. Elemental zoning should be at least as useful as alteration-mineralization zoning for evaluating rock bodies thought to contain blind deposits similar to the Kalamazoo deposit.