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  • Hulen, Jeffrey B.  (6)
  • 1
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    Molybdenum mineralization in an active geothermal system, Valles caldera, New Mexico
    Geological Society of America ; 1987
    In:  Geology Vol. 15, No. 8 ( 1987), p. 748-
    Details
    In: Geology, Geological Society of America, Vol. 15, No. 8 ( 1987), p. 748-
    Type of Medium: Online Resource
    ISSN: 0091-7613
    URL: Article
    DOI: 10.1130/0091-7613(1987)15〈748:MMIAAG〉2.0.CO;2
    Language: English
    Publisher: Geological Society of America
    Publication Date: 1987
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  • 2
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    Internal geology and evolution of the Redondo Dome, Valles Caldera, New Mexico
    American Geophysical Union (AGU) ; 1984
    In:  Journal of Geophysical Research: Solid Earth Vol. 89, No. B10 ( 1984-09-30), p. 8695-8711
    Details
    In: Journal of Geophysical Research: Solid Earth, American Geophysical Union (AGU), Vol. 89, No. B10 ( 1984-09-30), p. 8695-8711
    Abstract: Deep geothermal drilling in the resurgent Redondo dome of the Valles caldera has allowed us to define a consistent intracaldera stratigraphic sequence that differs in a number of respects from the temporally equivalent sequence outside the caldera. Above the deeply eroded, Pliocene Paliza Canyon Formation, felsic ash flows and sediments in the dome area form a complex sequence of undetermined age that we call the Lower Tuffs. An erosional interval separates these rocks from the overlying Otowi Member (1.4 m.y.) of the Bandelier Tuff. Another period of erosion, during which a tuffaceous sandstone was deposited, separates the Otowi from the overlying Tshirege Member (1.1 m.y.) of the Bandelier. Both the Otowi and Tshirege members, with maximum thicknesses of 833 and 1155 m, respectively, are substantially thicker within the caldera than outside, indicating simultaneous deposition and cauldron subsidence. Both are predominantly densely welded with distinctive interior zones of granophyric crystallization. Resurgent doming was initiated after emplacement of the Tshirege Member as evidenced by erosion of the upper portions of the cooling unit prior to deposition of overlying units. An isopach map of the sandstone deposited during this erosional period shows that streams draining the uplifting dome were localized along the present Redondo Creek trend. Subsequent volcanic activity resulted in the formation of at least three additional ash flow tuff cooling units prior to deposition of caldera fill and eruption of the Redondo Creek Member of the Valles Rhyolite. A numerical model applied to formation of the Redondo dome suggests that the top of the causative magma body is located at a depth of about 4700 m, 1458 m beneath the bottom of the deepest geothermal well in the dome. No wells have penetrated intrusives that could be related to this magma. We suggest that the locations of faults bounding the apical graben of the dome were influenced by older faults associated with the northeast trending Jemez lineament. These faults were active early in the uplift history of the dome and account for many of the structural differences between hypothetical dome development and reality.
    Type of Medium: Online Resource
    ISSN: 0148-0227
    URL: Article
    DOI: 10.1029/JB089iB10p08695
    Language: English
    Publisher: American Geophysical Union (AGU)
    Publication Date: 1984
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  • 3
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    Evolution of the Western Valles Caldera Complex, New Mexico: Evidence from intracaldera sandstones, breccias, and surge deposits
    American Geophysical Union (AGU) ; 1991
    In:  Journal of Geophysical Research: Solid Earth Vol. 96, No. B5 ( 1991-05-10), p. 8127-8142
    Details
    In: Journal of Geophysical Research: Solid Earth, American Geophysical Union (AGU), Vol. 96, No. B5 ( 1991-05-10), p. 8127-8142
    Abstract: Scientific core drilling in the Pleistocene Valles caldera complex (encompassing the Valles (1.13 Ma) and coaxial Toledo (1.50 Ma) calderas) of north central New Mexico has provided new insight into the origins of sandstones, breccias, and pyroclastic surge deposits interbedded with the thick intracaldera ignimbrite sequence. These rocks were previously interpreted from geothermal drill cuttings as dominantly fluvial in origin. As such, representing significant erosional intervals, they formed much of the basis for subdividing the intracaldera ignimbrite sequence (up to 2000 m in apparent thickness where drilled) into four major units: the lower tuffs ( 〉 1.50 Ma); the Otowi (1.50 Ma) and Tshirege (1.13 Ma) members of the Bandelier Tuff; and a new unit, the upper tuffs, believed to be post‐Bandelier in age ( 〈 1.13 Ma). All but the upper tuffs correspond to mapped outflow facies ignimbrite sheets. However, Continental Scientific Drilling Program core holes VC‐2A (completed in 1986) and VC‐2B (completed in 1988), in the Sulphur Springs area of the Valles caldera, have provided continuous cores, revealing for the first time that some intracaldera rocks previously thought to be exclusively clastic actually have multiple origins. Some of these rocks are probably pyroclastic surge deposits; others could be lithic‐rich breccias of various origins incorporated nearly instantaneously in ignimbrites during ash flow eruption and concomitant caldera collapse. These new findings demonstrate the value of continuous core for subsurface characterization and correlation of complex intracaldera lithologies; they also necessitate revision of Nielson and Hulen's (1984) cuttings‐based intracaldera stratigraphic framework. For example, the hematitic S 2 “sandstone” was initially interpreted as marking an erosional interval between the Tshirege Member of the Bandelier Tuff and the overlying, petrographically similar upper tuffs. Core from VC‐2A and VC‐2B, however, shows that the S 2 cuttings could also represent disaggregated, Permian red bed‐rich, lithic lag breccias or caldera collapse mesobreccias. If this is the case, then most or all of the upper tuffs are actually uppermost Tshirege Member ignimbrites. In similar fashion and upon review of previously applied correlation criteria the “lower tuffs” of the western Valles caldera complex could represent both genuine pre‐Bandelier ignimbrites and those of the lowermost Otowi Member. The core, however, shows that in the Sulphur Springs subsurface the lower tuffs are separated from overlying ignimbrite sheets by prominent erosional and eruptive breaks; they appear to be slightly more mafic than the overlying tuffs and host distinctive pumice lapilli. At this site the lower tuffs almost certainly predate the Otowi Member and are probably correlative with the outflow facies San Diego Canyon ignimbrites (1.78 Ma). Cores from VC‐2A and VC‐2B support earlier interpretation of the S 3 “sandstone” as a major marker horizon separating the intracaldera Otowi and Tshirege members of the Bandelier Tuff but clearly shows that this important unit is not, as previously thought, entirely a simple intracaldera epiclastic apron. In VC‐2A the S 3 has the superficial appearance of a sandstone but contains abundant blocky shards as well as accretionary and armored lapilli; it is also soft‐sediment‐deformed and invades overlying nonwelded tuff as small clastic dikes. We believe that here the S 3 was emplaced by a wet pyroclastic surge. In nearby corehole VC‐2B the S 3 consists of a basal, massive, sediment‐gravity‐flow (?) sandstone overlain by sandstone and dacite breccias with accretionary and armored lapilli‐bearing tuffaceous matrices. These deposits are probably caldera collapse mesobreccias that were formed simultaneously with early Tshirege Member ash flow eruptions through or into a Toledo caldera lake.
    Type of Medium: Online Resource
    ISSN: 0148-0227
    URL: Article
    DOI: 10.1029/91JB00374
    Language: English
    Publisher: American Geophysical Union (AGU)
    Publication Date: 1991
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  • 4
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    Hydrothermal alteration in the Baca Geothermal System, Redondo Dome, Valles Caldera, New Mexico
    American Geophysical Union (AGU) ; 1986
    In:  Journal of Geophysical Research: Solid Earth Vol. 91, No. B2 ( 1986-02-10), p. 1867-1886
    Details
    In: Journal of Geophysical Research: Solid Earth, American Geophysical Union (AGU), Vol. 91, No. B2 ( 1986-02-10), p. 1867-1886
    Abstract: Thermal fluids circulating in the active hydrothermal system of the resurgent Redondo dome of the Valles caldera have interacted with their diverse host rocks to produce well‐zoned alteration assemblages, which not only help locate permeable fluid channels but also provide insight into the system's thermal history. The alteration shows that fluid flow has been confined principally to steeply dipping normal faults and subsidiary fractures as well as thin stratigraphic aquifers. Permeability along many of these channels has been reduced or locally eliminated by hydrothermal self‐sealing. Alteration from the surface through the base of the Miocene Paliza Canyon Formation is of three distinctive types: argillic, propylitic, and phyllic. Argillic alteration forms a blanket above the deep water table in formerly permeable nonwelded tuffs. Beneath the argillic zone, pervasive propylitic alteration is weakly developed in felsic host rocks but locally intense in deep intermediate composition volcanics. Strong phyllic alteration is commonly but not invariably associated with major active thermal fluid channels. Phyllic zones yielding no fluid were clearly once permeable but now are hydrothermally sealed. High‐temperature alteration phases at Baca are presently found at much lower temperatures. We suggest either that isotherms have collapsed due to gradual cooling of the system, that they have retreated without overall heat loss due to uplift of the Redondo dome, that the system has shifted laterally, or that it has contracted due to a drop in the water table. The deepest Well (B‐12, 3423 m) in the dome may have penetrated through the base of the active hydrothermal system. Below a depth of 2440 m in this well, hydrothermal veining largely disappears, and the rocks resemble those developed by isochemical thermal metamorphism. The transition is reflected by temperature logs, which show a conductive thermal gradient below 2440 m. This depth may mark the dome's neutral plane, which separates an upper permeable zone of extensional fracturing from a lower, less permeable compressional regime. The Baca hydrothermal system is similar to those which have formed ore deposits in other calderas: particularly, Creede (Colorado) type epithermal silver base metal veins and stockworks. Recent scientific drilling has also intersected a deep zone of strong phyllic alteration and molybdenum mineralization in the Valles caldera's ring fracture system, a setting which localized a large stockwork molybdenite orebody in the nearby Questa caldera.
    Type of Medium: Online Resource
    ISSN: 0148-0227
    URL: Article
    DOI: 10.1029/JB091iB02p01867
    Language: English
    Publisher: American Geophysical Union (AGU)
    Publication Date: 1986
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  • 5
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    Hydrothermal brecciation in the Jemez fault zone, Valles Caldera, New Mexico: Results from continental Scientific Drilling Program core hole VC‐1
    American Geophysical Union (AGU) ; 1988
    In:  Journal of Geophysical Research: Solid Earth Vol. 93, No. B6 ( 1988-06-10), p. 6077-6089
    Details
    In: Journal of Geophysical Research: Solid Earth, American Geophysical Union (AGU), Vol. 93, No. B6 ( 1988-06-10), p. 6077-6089
    Abstract: An unusual breccia sequence penetrated in the lower 30 m of Continental Scientific Drilling Program core hole VC‐1 (total depth 856 m) records a complex hydrothermal history culminating in hydraulic rock rupture and associated alteration at the edge of the Quaternary Valles caldera. The breccias, both tectonic and hydrothermal in origin, were formed in the Jemez fault zone, near the intersection of this major regional structure with the caldera's ring‐fracture margin. Tectonic breccias in the sequence are contorted, crushed, and sheared. Coexisting hydrothermal breccias lack such frictional textures but display matrix flow foliation and prominent clast rounding, features characteristic of fluidization. These hydrothermal breccias were intensely altered, during at least five major stages, to quartz‐illite‐phengite‐pyrite aggregates; traces of molybdenite occur locally. This assemblage indicates interaction with hydrothermal fluid at temperatures in excess of 200°C. The extrapolated present maximum temperature of 184°C in the breccia zone therefore represents considerable cooling since these phases were formed. Fluid inclusions in the breccias also preserve evidence of the prior passage of hotter fluids. The inclusions are principally two phase, liquid rich, secondary in origin, and concentrated in hydrothermal quartz. Older, high‐salinity inclusions, unrelated to brecciation, homogenize in the temperature range 189°–246°C. Younger inclusions, in part of interbreccia origin, are low‐salinity and homogenize in the temperature range 230°–283°C; locally coexisting liquid‐ and vapor‐rich inclusions document periodic boiling of the dilute fluids. These fluid‐inclusion data, along with the probable age of the hydrothermal breccias ( 〈 1.5 Ma), the assumed depth at which they developed (about 515 m), and the contemporaneous state of stress (extensional) can be combined to model hydrothermal brecciation at the VC‐1 site. The minimum fluid pressure ( P fr ) required to hydrofracture these rocks was probably about 7.5 MPa (0.0146 MPa/m). A boiling point versus depth curve based on these P fr values graphically defines the physical conditions prevailing when the breccias were formed. When fluid pressure at the assumed depth of brecciation exceeded that curve, in response to rapid release of confining pressure possibly augmented by renewed heating, flashing hydrothermal fluid fractured the enclosing rock. Large overpressures, most likely induced by sudden seismic cracking of a hydrothermally sealed portion of the Jemez fault zone, led to local fluidization of the resulting breccias. Late quartz veining, hydrothermal alteration, and molybdenite mineralization were probably produced by the fluids responsible for brecciation.
    Type of Medium: Online Resource
    ISSN: 0148-0227
    URL: Article
    DOI: 10.1029/JB093iB06p06077
    Language: English
    Publisher: American Geophysical Union (AGU)
    Publication Date: 1988
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  • 6
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    Scientific Drilling at Sulphur Springs, Valles Caldera, New Mexico: Core Hole VC 2A
    American Geophysical Union (AGU) ; 1987
    In:  Eos, Transactions American Geophysical Union Vol. 68, No. 30 ( 1987-07-28), p. 649-662
    Details
    In: Eos, Transactions American Geophysical Union, American Geophysical Union (AGU), Vol. 68, No. 30 ( 1987-07-28), p. 649-662
    Abstract: A scientific core hole has been drilled into the western ring fracture zone of the Valles Caldera, N.Mex. Hole VC‐2A, the second scientific core hole in the caldera, was cored through a faulted and brecciated sequence of intracaldera tuffs and volcaniclastic rocks to a depth of 528 m at Sulphur Springs. As of November 1, 1986, the unequilibrated bottom hole temperature was 212°C. The rocks that have been penetrated are intensely altered and contain molybdenite mineralization (MnC 〉 2) that is less than or equal to 1.1 m.y. in age. The active hydrothermal system at Sulphur Springs consists of a thin (5‐m) acid condensation zone overlying vapor‐ and water‐dominated zones. The latter two zones are apparently separated by a region of tightly sealed rock.
    Type of Medium: Online Resource
    ISSN: 0096-3941 , 2324-9250
    URL: Article
    DOI: 10.1029/EO068i030p00649-01
    Language: English
    Publisher: American Geophysical Union (AGU)
    Publication Date: 1987
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