Your search keyword '"David F. Naar"' showing total 10 results

1. New perspectives on the geology and origin of the Florida Middle Ground carbonate banks, West Florida Shelf, USA

Author

Albert C. Hine, Brian T. Donahue, David J. Mallinson, Stanley D. Locker, and David F. Naar

Subjects

geography, geography.geographical_feature_category, Shoal, Geology, Context (language use), Oceanography, Karst, Geochemistry and Petrology, Benthic zone, Aggradation, Clastic rock, Younger Dryas, Reef

Abstract

Bathymetric and seismic surveys of the Florida Middle Ground area on the West Florida Shelf, aid in identifying the structure and origin of these unusual banks. Recent cores recovered from the area by other workers provide a useful context for interpreting geophysical data. Data indicate that high-relief banks may be largely biohermal, whereas low-relief banks are likely composed of clastic sediments with a vermetid gastropod carbonate caprock. The most seaward ridges reveal subtle internal aggradational stratal geometries indicating a possible origin as a subtidal shoal, or paleoshoreline, deposited during or immediately following the Younger Dryas. Bank locations appear to be related to the antecedent geology, specifically the occurrence of the highly weathered Miocene surface. High-resolution multibeam bathymetry and backscatter data reveal varied morphologies that suggest the influence of karst processes, linear trends suggestive of wave-reworked intertidal hardbottom, poorly lithified and benthic fauna-mantled beach ridges or sand waves, or perhaps surface-water flow patterns during lowstand exposure. Circular depressions on low banks are of the same scale and morphology as modern shallow karst features in the Everglades. An episodically active sand-wave field occurs in the northern study area, and provides sediment to the system. Scoured depressions surrounding carbonate banks also indicate intense, episodic current activity originating from shelf and wave currents. A partial modern analog for some of the morphology of this system may be the Ten Thousand Islands and portions of the Florida Everglades. Data indicate that the banks represent a brief period of reef growth (possibly mixed coral and vermetid) constrained by two rapid sea-level rise events, and impacted by changing water quality and trophic conditions.

Published

2014

2. Quaternary cave levels in peninsular Florida

Author

H. L. Vacher, Lee J. Florea, David F. Naar, and Brian T. Donahue

Subjects

Archeology, Global and Planetary Change, geography, geography.geographical_feature_category, Water table, Geology, Aquifer, Paleontology, Cave, Bathymetry, Glacial period, Speleogenesis, Quaternary, Geomorphology, Ecology, Evolution, Behavior and Systematics, Sea level

Abstract

The hypothesis that caves in the Florida Peninsula are tied to Quaternary sea levels was proposed by hydrogeologists, without data, some 40 years ago. The hypothesis is a version of glacial control of cave levels, which is the logical combination of the water-table theory of speleogenesis and the concept that base level positions the water table. At the USA type example of glacial control of cave levels—Mammoth Cave in the Paleozoic rocks of Kentucky—the intermediary is base level determined by rivers. By hypothesis, the intermediary for Florida is glacioeustatic sea level. This paper presents elevation data that supports this hypothesis. Recent cave surveys in the air-filled caves and spot elevations from archived maps reveal prominent levels of passages centered at 5, 12, 21, and 30 m above sea level over broad areas. They do not follow the large-scale structure of the Floridan aquifer. Instead, they align with nearby, coastal marine terraces identified as modal peaks on frequency plots from various topographic data bases. Levels matching with the three highest terraces—Wicomico, Penholoway, and Talbott—are particularly clear. Lower levels, if they accord with sea-level stands, are likely composites. Data from cavities encountered in drilled wells (e.g., bit drops) and spot elevations from archived underwater cave maps demonstrate passage levels at depths of 15, 30, 70, and 90–120 m below the modern water table. The depths below water table are similar to the depths below sea level of distant submerged terraces and paleoshoreline features identified using multibeam bathymetric data in the Gulf of Mexico. The cave, bit-drop, and terrace data are all consistent with the concept that Quaternary sea level is the fundamental control on the cave-scale porosity within the Floridan aquifer. This conclusion does not rule out the possibility that lithologically favored positions, paleokarst features and confining units, and mixing zones are also involved in the location of caves levels in this near-coastal environment.

Published

2007

3. Strange bedfellows—a deep-water hermatypic coral reef superimposed on a drowned barrier island; southern Pulley Ridge, SW Florida platform margin

Author

D. Palandro, K. T. Ciembronowicz, David F. Naar, A.C Neumann, B.D. Jarrett, David C. Twichell, Chuanmin Hu, Walter C. Jaap, Albert C. Hine, Stanley D. Locker, Robert B. Halley, and Brian T. Donahue

Subjects

geography, geography.geographical_feature_category, biology, Continental shelf, Fringing reef, Coralline algae, Geology, Hermatypic coral, Oceanography, biology.organism_classification, Paleontology, Barrier island, Geochemistry and Petrology, Ridge, Deglaciation, Reef

Abstract

The southeastern component of a subtle ridge feature extending over 200 km along the western ramped margin of the south Florida platform, known as Pulley Ridge, is composed largely of a non-reefal, coastal marine deposit. Modern biostromal reef growth caps southern Pulley Ridge (SPR), making it the deepest hermatypic reef known in American waters. Subsurface ridge strata are layered, lithified, and display a barrier island geomorphology. The deep-water reef community is dominated by platy scleractinian corals, leafy green algae, and coralline algae. Up to 60% live coral cover is observed in 60–75 m of water, although only 1–2% of surface light is available to the reef community. Vertical reef accumulation is thin and did not accompany initial ridge submergence during the most recent sea-level rise. The delayed onset of reef growth likely resulted from several factors influencing Gulf waters during early stages of the last deglaciation (∼14 kyr B.P.) including; cold, low-salinity waters derived from discrete meltwater pulses, high-frequency sea-level fluctuations, and the absence of modern oceanic circulation patterns. Currently, reef growth is supported by the Loop Current, the prevailing western boundary current that impinges upon the southwest Florida platform, providing warm, clear, low-nutrient waters to SPR. The rare discovery of a preserved non-reefal lowstand shoreline capped by rich hermatypic deep-reef growth on a tectonically stable continental shelf is significant for both accurate identification of late Quaternary sea-level position and in better constraining controls on the depth limits of hermatypic reefs and their capacity for adaptation to extremely low light levels.

Published

2005

4. Sediment-starved sand ridges on a mixed carbonate/siliciclastic inner shelf off west-central Florida

Author

Stanley D. Locker, Albert C. Hine, J.H. Edwards, S.E. Harrison, David F. Naar, David J. Mallinson, and David C. Twichell

Subjects

geography, geography.geographical_feature_category, Bedform, Geology, Oceanography, Seafloor spreading, Sedimentary depositional environment, Headland, Paleontology, chemistry.chemical_compound, chemistry, Geochemistry and Petrology, Water environment, Carbonate, Siliciclastic, Geomorphology, Sediment transport

Abstract

High-resolution side-scan mosaics, sediment analyses, and physical process data have revealed that the mixed carbonate/siliciclastic, inner shelf of west-central Florida supports a highly complex field of active sand ridges mantled by a hierarchy of bedforms. The sand ridges, mostly oriented obliquely to the shoreline trend, extend from 2 km to over 25 km offshore. They show many similarities to their well-known counterparts situated along the US Atlantic margin in that both increase in relief with increasing water depth, both are oriented obliquely to the coast, and both respond to modern shelf dynamics. There are significant differences in that the sand ridges on the west-central Florida shelf are smaller in all dimensions, have a relatively high carbonate content, and are separated by exposed rock surfaces. They are also shoreface-detached and are sediment-starved, thus stunting their development. Morphological details are highly distinctive and apparent in side-scan imagery due to the high acoustic contrast. The seafloor is active and not a relict system as indicated by: (1) relatively young AMS 14C dates (

Published

2003

5. Development of small carbonate banks on the south Florida platform margin: response to sea level and climate change

Author

Brian T. Donahue, Stanley D. Locker, David F. Naar, David J. Mallinson, Pamela Hallock, Albert C. Hine, Eugene A. Shinn, and Douglas C. Weaver

Subjects

geography, geography.geographical_feature_category, Pleistocene, Coral, Climate change, Geology, Oceanography, Coring, chemistry.chemical_compound, chemistry, Geochemistry and Petrology, Carbonate, Reef, Sea level, Holocene

Abstract

Geophysical and coring data from the Dry Tortugas, Tortugas Bank, and Riley’s Hump on the southwest Florida margin reveal the stratigraphic framework and growth history of these carbonate banks. The Holocene reefs of the Dry Tortugas and Tortugas Bank are approximately 14 and 10 m thick, respectively, and are situated upon Pleistocene reefal edifices. Tortugas Bank consists of the oldest Holocene corals in the Florida Keys with earliest coral recruitment occurring at ∼9.6 cal ka. Growth curves for the Tortugas Bank reveal slow growth (

Published

2003

6. A history of the Selkirk paleomicroplate

Author

Angelina Blais, Marcia Maia, David F. Naar, and Pascal Gente

Subjects

geography, Rift, geography.geographical_feature_category, Pacific Plate, Fracture zone, Mid-ocean ridge, Latitude, Geophysics, Sinistral and dextral, Lithosphere, Bathymetry, Geology, Seismology, Earth-Surface Processes

Abstract

Located in the South Pacific, between latitudes 33°S and 38°S and longitudes 120°W and 125°W, the extinct Selkirk microplate was first described as originating from lithosphere transferred from the Nazca plate to the Pacific plate [Earth Planet. Sci. Lett. 113 (1992) 293]. Multibeam bathymetry data, backscatter imagery and magnetic data obtained in 1997 during the Foundation Hotline cruise permit a more complete and detailed characterisation of the evolution of this paleomicroplate. The western boundary of the paleomicroplate is a fossil-spreading axis composed by two segments presenting two southward propagations and fan-shaped opening. The eastern boundary of the paleomicroplate is formed by a northward-propagating rift. In the present-day, only the western part of the fan-shaped sequence is present in the Pacific plate. According to satellite altimetry data, the northern boundary is a complex compressive domain formed by N110 ridges and troughs. The southern boundary is located along the Mocha fracture zone. Our magnetic interpretation suggests that this microplate has been active between chron 6C (24 Ma) and chron 6Ar (anomaly 6A, reverse period; 20.8 Ma). The last stage of the Selkirk microplate evolution is marked by a compression in the southern boundary and a sinistral shearing along an associated N45 structure located in the microplate. These observations imply the transfer of the eastern southern boundary of the microplate, previously located along the Mocha fracture zone, to these complex structures. The observed structures imply a change of the microplate rotation axis for this last stage, leading to the locking of the microplate and the transfer of all the spreading to the eastern boundary.

Published

2002

7. The Pacific-Antarctic Ridge–Foundation hotspot interaction: a case study of a ridge approaching a hotspot

Author

David T. Sandwell, Roger Hekinian, G. Ramillien, A. Sabetian, K. Perrot, J. Phipps Morgan, G. A. Dehghani, Marcia Maia, Dietrich Ackermand, John O'Connor, Peter Stoffers, David F. Naar, Pascal Gente, and Sidonie Révillon

Subjects

geography, geography.geographical_feature_category, Geology, Mid-ocean ridge, Geophysics, Oceanography, Mantle (geology), Gravity anomaly, Plume, Ridge push, Geochemistry and Petrology, Hotspot (geology), Bathymetry, Bouguer anomaly, Seismology

Abstract

The Foundation hotspot-Pacific-Antarctic Ridge (PAR) system is the best documented case of a fast spreading ridge approaching a hotspot and interacting with it. The morphology, crustal structure inferred from gravity anomalies and the chemical composition of the lavas of the axial area of the PAR show evidence of the influence of the hotspot, that is presently located roughly 35 km west of the spreading ridge axis. Along-axis variation in the Mantle Bouguer anomaly is about 28 mGal, corresponding to a crustal thickening of 1.5 km where the hotspot is nearer to the PAR. Anomalous ridge elevation is 650 m and the along-axis width of the chemical anomaly is 200 km. A comparison of these axial parameters with those derived for other ridge-hotspot systems, suggests that the amount of plume material reaching the ridge axis is smaller for the Foundation-PAR system. This implies a weaker connection between the plume and the ridge. Cumulative effects of a fast spreading rate and of a fast ridge-hotspot relative motion can be responsible for this weak plume-ridge flow. The flow from the hotspot may be less efficiently channelled towards the ridge axis when a fast ridge is rapidly moving towards a hotspot.

Published

2000

8. Petrology of the Easter microplate region in the South Pacific

Author

Jacques Girardeau, Richard Hey, J.P. Cogné, David F. Naar, M. Constantin, Jean Francheteau, Roger Hekinian, R. Armijo, and Roger Searle

Subjects

geography, Rift, geography.geographical_feature_category, Seamount, Partial melting, Transform fault, Mantle (geology), Igneous rock, Geophysics, Geochemistry and Petrology, Oceanic crust, Rift zone, Petrology, Geology

Abstract

Submersible investigations along the East Rift segments, the Pito Deep and the Terevaka transform fault of the Easter microplate eastern boundary, and on a thrust-fault area of the Nazca Plate collected a variety of basalts and dolerites. The volcanics consist essentially of depleted (N-MORB), transitional (T-MORB) and enriched (E-MORB) basalts with low (0.01−0.1, 0.25, > 1.2–2) K/Ti and(La/Sm)N ratios, respectively. The Fe-Ti-rich ferrobasalt encountered among the N-MORBs are found on the Pito Deep Central volcano, on the Terevaka intra-transform ridge, on the ancient ( 61) are found on topographic highs (2000–2300 m) and lower values (Mg# < 56) at the extremities of the East Rift segments (2500–5600 m depths). The deepest area (5600 m) along the East Rift is located at 23 °S and coincides with a Central volcano constructed on the floor of the Pito Deep. Three major compositional variabilities of the volcanics are observed along the East Rift segments studied: (1) the 26 °S East Rift segment where the volcanics have intermediate Na8 (2.5–2.8%) and Fe8 (8.5–11%) contents; (2) the 23 °S East Rift segment (comprising Pito seamount and Pito Deep Central volcano) which shows the highest (2.9–3.4%) values of Na8 and a low (8–9%) Fe8 content; and (3) the 25 °S (at 24 °50′–26 °10′S) and the 24 °S (at 24 °10′–25 °S) East Rift segments where most of the volcanics have low to intermediate Na8 (2.6–2.0%) and a high range of Fe8 (9–13%) contents. When modeling mantle melting conditions, we observed a relative increase in the extent of partial melting and decreasing melting pressure. These localized trends are in agreement with a 3-D type diapiric upwelling in the sense postulated by Niu and Batiza (1993). Diapiric mantle upwelling and melting localized underneath the 26, 25 and 23 °S (Pito seamount and Central volcano) East Rift segments are responsable for the differences observed in the volcanics. The extent of partial melting varies from 14 to 19% in the lithosphere between 18 and 40 km deep as inferred from the calculated initial (Po=16kbar) and final melting (Pf=7kbar) pressures along the various East Rift segments. The lowest range of partial melting (14–16%) is confined to the volcanics from 23 °S East Rift segment including the Pito seamount and the Central volcano. The Thrust-fault area, and the Terevaka intra-transform show comparable mantle melting regimes to the 25 and 26 °S East Rift segments. The older lithosphere of the EMP interior is believed to have been the site of high partial melting (17–20%) confined to the deeper melting area (29–50 km). This increase in melting with increasing pressure is similar to the conditions encountered underneath the South East Pacific Rise (13–20 °S).

Published

1996

9. Morphology of San Antonio submarine canyon on the central Chile forearc

Author

David F. Naar, Rick A. Hagen, and Hernán P Vergara

Subjects

Canyon, geography, geography.geographical_feature_category, Turbidity current, Sediment, Geology, Submarine canyon, Sinuosity, Oceanography, Geochemistry and Petrology, Bathymetry, Forearc, Geomorphology, Channel (geography)

Abstract

A multibeam survey was conducted over San Antonio submarine canyon, near Valparaiso, Chile, in April and May 1993 using the SeaBeam 2000 system on the R/V Melville. The bathymetric data from this survey reveal a canyon with an overall sinuosity of 1.25, a broad, roughly U-shaped cross-section along most of its length, and an almost constant channel slope above the forearc structural high. The course of the canyon is deflected to the north by a prominent structural high opposite the town of San Antonio. SeaBeam 2000 side-scan sonar data reveal high backscatter material on the floor of the canyon with a longitudinal fabric, reminiscent of stream braiding, and point bars formed on the inside of channel bends. We interpret this high backscatter material to be coarse sediment, transported down the canyon as turbidity currents. The source of these turbidity currents is probably the Rio Maipo, which enters the ocean near the head of the canyon.

Published

1996

10. Pito and Orongo fracture zones: the northern and southern boundaries of the Easter microplate (southeast Pacific)

Author

Philippe Patriat, J. Zukin, R. Armijo, S. Calmant, A. Yelles-Chaouche, J. Segoufin, Roger Searle, M. Doucoure, David F. Naar, Rapanui Scientific Party, and Jean Francheteau

Subjects

Rift, Triple junction, Theoretical models, Transform fault, Seafloor spreading, Narrow band, Tectonics, Geophysics, Shear (geology), Space and Planetary Science, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Seismology, Geology

Abstract

The Easter (Rapanui) microplate is a case example of a large dual spreading center system in a region where the fastest seafloor spreading on Earth is occurring today. Recent theoretical models of the tectonic evolution of dual spreading center systems have explored the effects of shear and rigid rotation on the boundaries and internal structure of microplates but the models must be critically constrained by improved relative motion and structural fabric data sets. During the January 1987 Rapanui expedition on the N/O “Jean Charcot” we conducted a Sea Beam/magnetics/ gravity survey of a portion of the microplate boundaries. The method that was used was to fully map selected portions of the boundaries in order to establish precise structural relationships. The northern terminus of the East Rift or eastern boundary of the microplate is expressed as a series of parallel NW-SE trending valleys including what appears to be, with 5890 m depth, the deepest active rift axis mapped in the Pacific today (Pito Rift). The northern end of the Pito Rift merges with an E-W to 083° narrow band of linear faults interpreted to be a transform fault between the Nazca and Easter (Rapanui) plates. The northern triple junction between the Easter (Rapanui), Nazca and Pacific plates is a RFF type with the two transform faults colinear along an approximately E-W direction. The southwestern boundary of the Easter (Rapanui) microplate is marked by a series of en-echelon offsets, outlined by depressions, which merge into an approximately E-W zone where shear must be predominant. The southern triple junction is a RRF junction with an overlapping ridge system. The structural data acquired during the survey provide strong constraints for kinematic models of the microplate. The structural data need to be combined with crustal age determinations in order to derive a model for the evolution of the microplate.

Published

1988