DOCSLIB.ORG

Canyonlands Island in the Sky District Trails and Roads

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Canyonlands Island in the Sky District Trails and Roads National Park Service Canyonlands U.S. Department of the Interior Canyonlands National Park Island in the Sky District Trails and Roads Paved road/ High-clearance, At-large Pull out 4-wheel-drive road Backpacking Zone Boat Launch Developed Campground Drinking Water Available Ranger Station Backcountry Vehicle Camp Self-guiding Trail Unpaved Name Name of 2-wheel-drive road Hiking Trail Backpacking Zone Picnic Area Designated Backpacking Site Backcountry Trailhead Parking Toilet NOTE: White shading within Canyonlands indicates areas with designated site camping only. Island in the Sky Visitor Center to Moab 32mi/51km 313 2.4 Long Canyon Road Mineral Bottom 12.9 1.0 (Horsethief Trail) Mineral Road 5.6 DEAD HORSE POINT 6.5 STATE PARK Visitor Center Taylor Ca Labyrinth n yon R 1.0 Moses and oad 5.0 Taylor Zeus 0.6 Shafer Dead Horse Fort Bottom U TAYLORCANYON Point Overlook P H Visitor Center Ruin E 1mi A 1.0 Potash V Taylor A A l 1.7 L c rail C 5.6 o fer T A e v Sha Road 3.5 clin e N Syn Y S 5.3 4.9 p 5.8 Gooseneck O T r 1.5 ra i Overlook N il n g Neck Syncline Spring Hardscrabble 1.5 First Whale 3.4 Overlook Rock Musselman 3.8 Arch Second Overlook Lathrop Potato Bottom Upheaval Dome ISLAND IN 6.8 THE SKY 11.3 Upper West Basins 6mi 11.0 5mi 6.1 d Aztec a o Wilhite Butte r R Washer Airport e v W Woman L Rim i Arch R A e H it h Mesa Arch T W I 11.5 H R Willow d T Flat a O Green River o R P Candlestick E Overlook 10.0 6mi Gooseberry/ m 10km Ri Lathrop e t Murphy i G Point 0.5 h re W e R Buck n 1.3 Canyon I Overlook 1.5 2.8 o M d a erry r eb Gooseberry o l os o 2.7 o 1.3 2.7 G C White Rim Overlook Murphy Hogback Grand View Point Overlook 8.0 1.0 M 5.5 I R Monument Basin E Riv I T er W H 1.4 White Crack THE MAZE Lower Basins THE LOOP Interpretive Activities VISITOR CENTER INTERPRETIVE TALKS AND GUIDED WALKS Open daily March through December, 9 am Presented daily March through October. to 4 pm, with extended hours in summer. Locations, times, and topics vary. A program Exhibits, information, permits, video schedule and description of activities is presentation, booksales, and water for sale. posted at the visitor center, campground, and Call 435-259-4712 to verify hours. entrance station. Hiking Trails Trails are marked with cairns (small rock Potash and Shafer Trail roads in a single piles). Do not disturb existing cairns or build day. You can walk your pet along paved new ones. Signs are located at trailheads roads, in parking lots, and at Willow Flat and intersections. All trails leading below Campground, but must be on a leash at all the mesa top are primitive and rough. There times. Protect your pet from heat exhaustion: is no potable water along any hiking trails. do not leave your pet unattended in a vehicle Drinking water is available spring through during hot weather. fall at the visitor center. Backcountry Permit Office TRAVELLING WITH PETS 2282 Resource Blvd. Pets are not allowed on any hiking trails or Moab, UT 84532 in the backcountry. Pets may not accompany Phone: 435-259-4351 you in your vehicle on four-wheel-drive www.nps.gov/cany roads, except when traveling along the Round-Trip Round-Trip One-way Distance Hiking Time Elevation Change Description Mesa Top (Easy Trails) Mesa Arch 0.5mi / 0.8km 30 minutes 100ft / 30m good for sunrise, arch on cliff edge Murphy Point Overlook 3.6mi / 5.8km 2 hours 100ft / 30m panoramic view w/Henry Mtns. White Rim Overlook 1.8mi / 2.9km 1 hour 25ft / 8m view of potholes, White Rim Road Grand View Point 2.0mi / 3.2km 1.5 hours 50ft / 15m panoramic view along cliff edge Mesa Top (Moderate Trails) Neck Spring 5.8mi / 9.3km 3 - 4 hours 300ft / 91m springs, evidence of ranching Aztec Butte 2.0mi / 3.2km 1.5 hours 225ft / 69m steep slickrock to top, grainaries Whale Rock 1.0mi / 1.6km 1 hour 100ft / 30m bare slickrock, good views Upheaval Dome to first overlook 0.8mi / 1.3km 1 hour 100ft / 30m view into crater to second overlook 1.8mi / 2.9km 1.5 hours 150ft / 45m crater & upheaval canyon view Mesa Top to White Rim (Steep & Strenuous Trails) Lathrop to White Rim Road 13.6mi / 22km 5- 7 hours 1600ft / 488m views of Colorado River & LaSals Murphy Loop 10.8mi / 17.4km 5 - 7 hours 1400ft / 427m panoramic view from hogback Gooseberry 5.4mi / 8.6km 4 - 6 hours 1400ft / 427m views of cliffs & LaSal Mtns. Wilhite 12.2mi / 19.6km 6 - 8 hours 1600ft / 488m slot cyn across White Rim Road Alcove Spring 11.2mi / 18km 6 - 7 hours 1300ft / 396m large alcove, views of Taylor Cyn Syncline Loop 8.3mi / 13.3km 5 - 7 hours 1300ft / 396m canyon hiking, some shade Upheaval Crater spur 3mi / 4.8km 2 hours 350ft / 107m some scrambling over rocks Upheaval Canyon spur 7mi / 11.2km 3 - 4 hours 400ft / 122m sandy hike along wash bottom Trails along the White Rim Road Gooseneck Overlook 0.6mi / 1.0km 30 minutes 50ft / 15m excellent view of Colorado River Fort Bottom Ruin 3mi / 4.8km 2 hours 500ft / 152m tower ruin from ancient times Moses and Zeus 1mi /1.6km 1 hour 500ft / 152m views of Taylor Cyn, climbing routes Protect Your Park Protect Yourself • Pets are not allowed on hiking trails or • Drink at least one gallon (4 L) of water each four-wheel-drive roads, even in a vehicle. day. Be sure to eat food as well. Pets may accompany groups traveling by • Always carry a topo map, adequate clothing, vehicle on the Potash and Shafer Trail roads and a flashlight. in a single day. • Remain in one place if you become lost or • Do not enter, alter, damage or deface separated from a group. archeological sites. Do not collect artifacts. • Never cross a canyon that is flooding. For More Information • Vehicles and bikes must stay on roads. • During lightning storms, avoid lone trees, cliff Canyonlands National Park • ATVs and OHVs are not permitted. edges and high ridges. Return to your vehicle 2282 Resource Blvd. • Protect cryptobiotic soil crusts by staying on if possible. Moab, UT 84532 (435)719-2313 trails and roads. • Be careful near cliff edges, especially when Web www.nps.gov/cany • Permits are required for all overnight rock surfaces are wet or icy. Social Media @CanyonlandsNPS backcountry trips. Printed by Canyonlands Natural History Association 05/21 EXPERIENCE YOUR AMERICA.
Load more

Recommended publications
  • Thesis-Reproduction (Electronic)
    A synopsis of the geologic and structural history of the Randsburg Mining District Item Type text; Thesis-Reproduction (electronic) Authors Morehouse, Jeffrey Allen, 1953-1985 Publisher The University of Arizona. Rights Copyright © is held by the author. Digital access to this material is made possible by the University Libraries, University of Arizona. Further transmission, reproduction or presentation (such as public display or performance) of protected items is prohibited except with permission of the author. Download date 27/09/2021 08:53:56 Link to Item http://hdl.handle.net/10150/558085 Call No. BINDING INSTRUCTIONS INTERUBRARY INSTRUCTIONS Dept. E9791 Author: Morehouse, J. 1988 245 Title: RUSH___________________ PERMABIND____________ PAMPHLET._____________ GIFT____________________ COLOR: M,S* POCKET FOR MAP______ COVERS Front_______Both Special Instructions - Bindery or Repair REFERENCE____ i________ O th er--------------------------- 3 /2 /9 0 A SYNOPSIS OF THE GEOLOGIC AND STRUCTURAL HISTORY OF THE RANDSBURG MINING DISTRICT by Jeffrey Allen Morehouse A Thesis Submitted to the Faculty of the DEPARTMENT OF GEOSCIENCES In Partial Fulfillment of the Requirements For the Degree of MASTER OF SCIENCE In the Graduate College THE UNIVERSITY OF ARIZONA 19 8 8 THE UNIVERSITY OF ARIZONA TUCSON, ARIZONA 85721 DEPARTMENT OF GEOSCIENCES BUILDING *77 GOULD-SIMPSON BUILDING TEL (602) 621-6024 To the reader of Jeff Morehouse's thesis: Jeff Morehouse's life was lamentably cut short by a hiking-rock climbing accident in the Santa Catalina Mountains near Tucson, Arizona, on March 24, 1985. Those who knew Jeff will always regret that accident, not only because it abbreviated what would certainly have been an uncommonly productive geological career but also because it snuffed an effervescent, optimistic,, charming personality.
    [Show full text]
  • Development of a Dilatant Damage Zone Along a Thrust Relay in a Low-Porosity Quartz Arenite
    Journal of Structural Geology 28 (2006) 776–792 www.elsevier.com/locate/jsg Development of a dilatant damage zone along a thrust relay in a low-porosity quartz arenite Jennie E. Cook a, William M. Dunne a,*, Charles M. Onasch b a Department of Earth and Planetary Sciences, University of Tennessee, Knoxville, TN 37996-1410, USA b Department of Geology, Bowling Green State University, Bowling Green, OH 43403, USA Received 12 August 2005; received in revised form 26 January 2006; accepted 15 February 2006 Available online 18 April 2006 Abstract A damage zone along a backthrust fault system in well-cemented quartz arenite in the Alleghanian foreland thrust system consists of a network of NW-dipping thrusts that are linked by multiple higher-order faults and bound a zone of intense extensional fractures and breccias. The damage zone developed at an extensional step-over between two independent, laterally propagating backthrusts. The zone is unusual because it preserves porous brittle fabrics despite formation at O5 km depth. The presence of pervasive, late-stage fault-normal joints in a fault-bounded horse in the northwestern damage zone indicates formation between two near-frictionless faults. This decrease in frictional resistance was likely a result of increased fluid pressure. In addition to physical effects, chemical effects of fluid also influenced damage zone development. Quartz cements, fluid inclusion data, and Fourier Transform Infrared analysis indicate that both aqueous and methane-rich fluids were present within the damage zone at different times. The backthrust network likely acted as a fluid conduit system, bringing methane-rich fluids up from the underlying unit and displacing resident aqueous fluids.
    [Show full text]
  • A N–S-Trending Active Extensional Structure, the Fiuhut (Afyon) Graben
    Turkish Journal of Earth Sciences (Turkish J. Earth Sci.), Vol. 16, 2007, pp. 391–416. Copyright ©TÜB‹TAK A N–S-trending Active Extensional Structure, the fiuhut (Afyon) Graben: Commencement Age of the Extensional Neotectonic Period in the Isparta Angle, SW Turkey AL‹ KOÇY‹⁄‹T & fiULE DEVEC‹ Middle East Technical University, Department of Geological Engineering, Active Tectonics and Earthquake Research Laboratory, TR–06531 Ankara, Turkey (E-mail: [email protected]) Abstract: The fiuhut graben is an 8–11-km-wide, 24-km-long, N–S-trending, active extensional structure located on the southern shoulder of the Akflehir-Afyon graben, near the apex of the outer Isparta Angle. The fiuhut graben developed on a pre-Upper Pliocene rock assemblage comprising pre-Jurassic metamorphic rocks, Jurassic–Lower Cretaceous platform carbonates, the Lower Miocene–Middle Pliocene Afyon stratovolcanic complex and a fluvio- lacustrine volcano-sedimentary sequence. The eastern margin of the fiuhut graben is dominated by the Afyon volcanics and their well-bedded fluvio- lacustrine sedimentary cover, which is folded into a series of NNE-trending anticlines and synclines. This volcano- sedimentary sequence was deformed during a phase of WNW–ESE contraction, and is overlain with angular unconformity by nearly horizontal Plio–Quaternary graben infill. Palaeostress analyses of slip-plane data recorded in the lowest unit of the modern graben infill and on the marginal active faults indicate that the fiuhut graben has been developing as a result of ENE–WSW extension since the latest Pliocene. The extensional neotectonic period in the Isparta Angle started in the latest Pliocene. All margins of the fiuhut graben are determined and controlled by a series of oblique-slip normal fault sets and isolated fault segments.
    [Show full text]
  • Faults and Joints
    97 FAULTS Fractures are planar discontinuities, i.e. interruption of the rock physical continuity, due to stresses. The geological fractures occur at every scale so that any large volume of rock has some or many. These discontinuities are attributed to sudden relaxation of elastic energy stored in the rock. The geological fractures have their economic importance. The loss of continuity in intact rocks provides the necessary permeability for migration and accumulation of fluids such as groundwater and petrol. Fractured reservoirs and aquifers are typically anisotropic since their transmissivity is regulated by the conductive properties of fractures, which the local stress field partially controls. Geological fractures may be partially or wholly healed by the introduction of secondary minerals, often giving rise to ore deposits, or by recrystallization of the original minerals. Planar discontinuities along which rocks lose cohesion during their brittle behavior are: - joints if there is no component of displacement parallel to the plane (there may be some very small orthogonal parting; joints are extension fractures). - faults if rocks on both sides of the plane have moved relative to each other, parallel to the plane (faults are shear fractures). - veins if the fractures are filled with secondary crystallization. Joints and faults divide the rocks into blocks whose size and shape must be taken into consideration for engineering, quarrying, mining, and geomorphology. Fault terminology Definitions Faults separate two adjacent blocks of rock that have moved past each other because of induced stresses. The notion of localized movement leads to two genetically different classes of faults reflecting the two basic behaviors of rocks under stress: brittle and ductile.
    [Show full text]
  • Geology Maps
    Student Name: Grade: Physical Geology 101 Laboratory Interpreting Geology Maps Introduction & Purpose: The purpose of this laboratory is to gain a working knowledge and skill to read geology maps. Students will learn to read a geology map for the purpose of understanding surface and subsurface structural relations and geologic history that may include a record of rock forming events, mountain building deformation, and the relationship between geology and topography Part I. Review Taking Strike and Dip Directions: Use the Compass and Inclinometer, provided by your instructor, to determine the strike and dip of two inclined boards that are setup in the classroom. Note: Use the boards labeled “X” and “Z”. 1. What is the strike and dip of the board labeled “X” strike: ___________ dip: ________ 2. What is the strike and dip of the board labeled “Z” strike: ___________ dip: ________ Part II – Reading and Interpreting a Simplified Geologic Map Introduction: A geologic map is a greatly scaled-down, two-dimensional abstract representation of the surface geology, structure, and relief of a geographic region of Earth, or even another terrestrial planet. A geologic map typically includes most information found on a topographic map, but most importantly, includes color-coding regions and symbols that denote rock units, contacts, and other structural information. Additionally, all the geologic color-coding and symbols are explained in the legend on a geologic map, including topographic and cardinal information. Directions: The simplified geology map below contains several geologic features that include the following: Sedimentary beds "A", "B", "C", and "D"; Basalt dike" E"; Granite pluton; Fault "Y"; and Unconformity "Z".
    [Show full text]
  • Mineral Resources of the Horse Mountain and Continental Divide Wilderness Study Areas, Catron County, New Mexico
    Mineral Resources of the Horse Mountain and Continental Divide Wilderness Study Areas, Catron County, New Mexico U.S. GEOLOGICAL SURVEY BULLETIN 1734-C 4: Chapter C Mineral Resources of the Horse Mountain and Continental Divide Wilderness Study Areas, Catron County, New Mexico By JAMES C. RATTE, RICHARD W. SALTUS, and ROBERT L TURNER U.S. Geological Survey CARL L ALMQUIST and ROBERT H. WOOD, 2d U.S. Bureau of Mines U.S. GEOLOGICAL SURVEY BULLETIN 1734 MINERAL RESOURCES OF WILDERNESS STUDY AREAS- WEST-CENTRAL NEW MEXICO DEPARTMENT OF THE INTERIOR DONALD PAUL MODEL, Secretary U.S. GEOLOGICAL SURVEY Dallas L Peck, Director UNITED STATES GOVERNMENT PRINTING OFFICE: 1988 For sale by the Books and Open-File Reports Section U.S. Geological Survey Federal Center Box 25425 Denver, CO 80225 Library of Congress Cataloging-in-Publication Data Mineral resources of the Horse Mountain and Continental Divide Wilderness Study Areas, Catron County, New Mexico. (Mineral resources of wilderness study areas west-central New Mexico ; ch. C) (U.S. Geological Survey bulletin ; 1734-C) Bibliography: p. Supt. of Docs, no.: I 19.3:1734-C 1. Mines and mineral resources New Mexico Horse Mountain Wilderness. 2. Mines and mineral resources New Mexico Continental Divide Wilderness. 3. Horse Mountain Wilderness (N.M.) 4. Continental Divide Wilderness (N.M.) I. Ratte, James C. (James Clifford), 1925- . II. Series. QE75.B9 no. 1734-C 557.3 S [553'.09789'93] 87-600410 [TN24.N6] STUDIES RELATED TO WILDERNESS Bureau of Land Management Wilderness Study Areas The Federal Land Policy and Management Act (Public Law 94-579, October 21, 1976) requires the U.S.
    [Show full text]
  • Journal of Mechanics of Materials and Structures Vol 1 Issue 2, Feb 2006
    JOURNAL OF MECHANICS OF MATERIALS AND STRUCTURES Journal of Mechanics of Materials and Structures Volume 1 No. 2 February 2006 Journal of Mechanics of Materials and Structures 2006 Vol. 1, No. 2 Volume 1, Nº 2 February 2006 mathematical sciences publishers JOURNAL OF MECHANICS OF MATERIALS AND STRUCTURES http://www.jomms.org EDITOR-IN-CHIEF Charles R. Steele ASSOCIATE EDITOR Marie-Louise Steele Division of Mechanics and Computation Stanford University Stanford, CA 94305 USA SENIOR CONSULTING EDITOR Georg Herrmann Ortstrasse 7 CH–7270 Davos Platz Switzerland BOARD OF EDITORS D. BIGONI University of Trento, Italy H. D. BUI Ecole´ Polytechnique, France J. P. CARTER University of Sydney, Australia R. M. CHRISTENSEN Stanford University, U.S.A. G. M. L. GLADWELL University of Waterloo, Canada D. H. HODGES Georgia Institute of Technology, U.S.A. J. HUTCHINSON Harvard University, U.S.A. C. HWU National Cheng Kung University, R.O. China IWONA JASIUK University of Illinois at Urbana-Champaign B. L. KARIHALOO University of Wales, U.K. Y. Y. KIM Seoul National University, Republic of Korea Z. MROZ Academy of Science, Poland D. PAMPLONA Universidade Catolica´ do Rio de Janeiro, Brazil M. B. RUBIN Technion, Haifa, Israel Y. SHINDO Tohoku University, Japan A. N. SHUPIKOV Ukrainian Academy of Sciences, Ukraine T. TARNAI University Budapest, Hungary F. Y. M. WAN University of California, Irvine, U.S.A. P. WRIGGERS Universitat¨ Hannover, Germany W. YANG Tsinghua University, P.R. China F. ZIEGLER Tech Universitat¨ Wien, Austria PRODUCTION PAULO NEY DE SOUZA Production Manager SILVIO LEVY Senior Production Editor NICHOLAS JACKSON Production Editor ©Copyright 2007.
    [Show full text]
  • Quicksilver Deposits of the Horse Heaven Mining District Oregon
    Quicksilver Deposits of the Horse Heaven Mining District Oregon GEOLOGICAL SURVEY BULLETIN 969-E QUICKSILVER DEPOSITS OF THE HORSE HEAVEN MINING DISTRICT, OREGON By A. C. WATERS, RANDALL E. BROWN, ROBERT R. COMPTON, LLOYD W. STAPLES, GEORGE W. WALKER, and HOWEL WILLIAMS ABSTRACT Commercial quantities of cinnabar were discovered in the Horse Heaven dis­ trict, north-central Oregon, in 1933. The district has since produced' 15,000 flasks of quicksilver, most of which has come from the Horse Heaven mine, although the Axe Handle mine produced about 150 flasks. Four prospects contain some cinnabar that may be mined for quicksilver in the future. The ore deposits found thus far are closely related to volcanic plugs. Four of them occur in or near autobrecciated plugs of biotite rhyolite. The ores of the Axe Handle mine are in altered rocks at tho margin of a plug of augite andesite. A small outlier of pre-Tertiary metamorphic rocks occurs about 5 miles north of the Horse Heaven mine. The oldest rocks close to the mine, however, are andesite flows, tuffs, and tuffaceous sedimentary rocks of the Clarno formation. The Clarno rocks were deformed, eroded to a rolling surf ace, and then covered! by three series of volcanic rocks. The oldest consists of basaltic andesite, fol­ lowed after a period of erosion by biotite rhyolite flows and pyroclastics, It is in the rhyolite plugs formed during this period of volcanism that most of the quicksilver deposits are found. Finally, the rhyolite flows and tuffs were moderately eroded, and in the southern part of the area they were covered by flows of augite andesite.
    [Show full text]
  • Glossary of Thrust Tectonics Terms
    Glossary of thrust tectonics terms K.R. McClay Department of Geology, Royal Holloway and Bedford New College, University of London, Egham, Surrey, England, TW20 OEX This glossary aims to illustrate, and to define where possible, recognise the difficulty in precisely defining many of the some of the more widely used terms in thrust tectonics. It is terms used in thrust tectonics as individual usages and pref­ presented on a thematic basis - individual thrust faults and erences vary widely. related structures, thrust systems, thrust fault related folds, 3- D thrust geometries, thrust sequences, models of thrust sys­ tems, and thrusts in inversion tectonics. Fundamental terms Thrust faults are defined first, followed by an alphabetical listing of related structures. Where appropriate key references are given. Thrust fault: A contraction fault that shortens a datum surface, usually bedding in upper crustal rocks or a regional Since some of the best studied thrust terranes such as the foliation surface in more highly metamorphosed rocks. Canadian Rocky Mountains, the Appalachians, the Pyrenees, and the Moine thrust zone are relatively high level foreland This section of the glossary defines terms applied to indi­ fold and thrust belts it is inevitable that much of thrust vidual thrust faults (after McClay 1981; Butler 1982; Boyer tectonics terminology is concerned with structures found in & Elliott 1982; Diegel 1986). the external zones of these belts. These thrustbelts character­ istically consist of platform sediments deformed by thrust Backthrust: A thrust fault which has an opposite vergence faults which have a ramp-flat trajectories (Bally et al. 1966; to that of the main thrust system or thrust belt (Fig.
    [Show full text]
  • Signature Redacted for Privacy. Abstract Approved: "T/ Dr
    AN ABSTRACT OF THE THESIS OF Daniel Glenn Carpenter for the degree ofMaster of Science in the Department of Geology presented onjj February 1989 Title: GEOLOGY OF THE NORTH MUDDY MOUNTAINS.CLARK COUNTY, NEVADA AND REGIONAL STRUCTURAL SYNTHESIS: FOLD-THRUST AND BASIN-RANGE STRUCTURE IN SOUTHERN NEVADA.SOUTHWEST UTAH, AND NORTHWEST ARIZONA Signature redacted for privacy. Abstract approved: "T/ Dr. R. S. Yeats The North Muddy Mountains are locatedin southern Nevada, about 65 km northeast of Las Vegasand near the eastern boundary of the Basin and Rangeprovince. The north-south-trending range block is bounded on theeast and west, respectively, by east- and west-dipping,high-angle normal faults. Sevier age contractional and Cenozoic age extensional structures are present in the range. The Summit thrust and Willow Tankthrust crop out, respectively, on the southwest and northeastsides of the North Muddy Mountains. A newly mapped thrustsegment connects the Summit and Willow Tank thrusts. It juxtaposed Jurassic on Cretaceous age rocks.The most recent displacement on the thrust is bracketed between95.8+1-3.5 Ma (age of youngest deformed rocks) and 93.1+/- 3.4 Ma (age of oldest overlying undefornied beds). These numbers indicate an Albian to Turonian(?) age rangefor the thrust. The Summit-Willow Tank thrust sheet waslater folded by a northwest-southeast-trending, southwest inclined foldtrain by displacement on the Arrowhead fault, aMiocefle and possibly younger(?) extensional structure. The oldest (Albian) synorogenicdeposits in the area contain exotic clasts of formations that werenot involved in local thrusting; the debris was transportedeastward from older thrust sheets. Younger (Cenoinanian) synorogenicbeds are composed of Mesozoic age clastsat the base of the section, grading to early paleozoic age clasts nearthe top (reverse clast stratigraphy).
    [Show full text]
  • Rock Horse Tuscarora District, Nevada
    Epithermal Au-Ag Rock Horse Tuscarora District, Nevada Contact Project Locations Overview • Large under-explored land position in a highly prospective area with extensive strong alteration • Low-sulfidation epithermal Au-Ag targets with similar host rocks, geology, and alteration to Hollister, Fire Creek, and Midas mines • Surface rock-chip vein samples have grades up to 0.67 g/t Au • Potential Carlin-style Au targets at depth with similar host rocks and geology to Big Springs and Jerritt Canyon mines Details • 185 unpatented lode claims on BLM, covering ~1,460 hectares • 3% NSR • 23 km North of Hecla’s producing Hollister Mine and 20 km Northeast of Hecla’s producing Midas Mine • Situated close to established mining infrastructure Data • 94 rock samples • 4 stream sediment samples TSXV: C +1 (604) 449-3361 [email protected] www.ContactGold.com Epithermal Au-Ag Rock Horse Tuscarora District, Nevada Rock Samples Au ppm As ppm Rock Type EL-AW-0021 0.677 5570 Silicified tuff EL-AW-0037 0.448 1250 Quartz vein EL-AW-0054 0.353 959 Silicified breccia EL-AW-0036 0.328 1030 Silicified breccia EL-TC-10 0.189 5160 Oxidized quartzite EL-AW-0010 0.147 >10,000 Quartz vein Geology • Gently dipping Eocene to Miocene volcanic rocks and Tertiary lake bed sediments over Ordovician to Silurian upper plate cherts, quartzites, and siltstones • Hg and As enriched sinter and silicified fault breccias are common throughout the volcanic sequence • Similar host rocks and alteration to other epithermal Au-Ag vein deposits like Hollister, Midas, and Fire Creek
    [Show full text]
  • Prediction of a Rift Valley Fever Outbreak
    Prediction of a Rift Valley fever outbreak Assaf Anyambaa,1, Jean-Paul Chretienb,2, Jennifer Smalla, Compton J. Tuckera, Pierre B. Formentyc, Jason H. Richardsond,3, Seth C. Britche, David C. Schnabelf, Ralph L. Ericksonb, and Kenneth J. Linthicume aNational Aeronautics and Space Administration Goddard Space Flight Center, Biospheric Sciences Branch, Code 614.4, Greenbelt, MD 20771; bDepartment of Defense Global Emerging Infections Surveillance and Response System, Division of Preventive Medicine, Walter Reed Army Institute of Research, 503 Robert Grant Avenue, Silver Spring, MD 20910; cBiorisk Reduction for Dangerous Pathogens, Communicable Diseases Cluster/Department of Epidemic and Pandemic Alert and Response, World Health Organization, 20 Avenue Appia, CH-1211, Geneva 27, Switzerland; dDepartment of Entomology and Vector-borne Disease, United States Army Medical Research Unit-Kenya, APO AE 09831-4109; eUnited States Department of Agriculture–Agricultural Research Service Center for Medical, Agricultural, and Veterinary Entomology, 1600 SW 23rd Drive, Gainesville, FL 32608; and fUnited States Army Medical Research Unit-Kenya, Unit 64109 Box 401 APO AE 09831-4109 Edited by B. L. Turner, II, Arizona State University, Tempe, AZ, and approved November 14, 2008 (received for review July 11, 2008) El Nin˜o/Southern Oscillation related climate anomalies were ana- resolutions (2, 15–18). These systematic observations of the oceans, lyzed by using a combination of satellite measurements of ele- atmosphere, and land have made it possible to evaluate different vated sea-surface temperatures and subsequent elevated rainfall aspects of climate variability and their relationships to disease and satellite-derived normalized difference vegetation index data. outbreaks (16), in addition to providing valuable long-term climate A Rift Valley fever (RVF) risk mapping model using these climate and environmental data (Table S1).
    [Show full text]