DOCSLIB.ORG

Sheeting Joints and Polygonal Patterns in the Navajo Sandstone, Southern Utah: Controlled by Rock Fabric, Tectonic Joints, Buckling, and Gullying David B

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text

Load more

University of Nebraska - Lincoln DigitalCommons@University of Nebraska - Lincoln Papers in the Earth and Atmospheric Sciences Earth and Atmospheric Sciences, Department of 2018 Sheeting joints and polygonal patterns in the Navajo Sandstone, southern Utah: Controlled by rock fabric, tectonic joints, buckling, and gullying David B. Loope University of Nebraska, Lincoln, [email protected] Caroline M. Burberry University of Nebraska - Lincoln, [email protected] Follow this and additional works at: http://digitalcommons.unl.edu/geosciencefacpub Part of the Earth Sciences Commons Loope, David B. and Burberry, Caroline M., "Sheeting joints and polygonal patterns in the Navajo Sandstone, southern Utah: Controlled by rock fabric, tectonic joints, buckling, and gullying" (2018). Papers in the Earth and Atmospheric Sciences. 519. http://digitalcommons.unl.edu/geosciencefacpub/519 This Article is brought to you for free and open access by the Earth and Atmospheric Sciences, Department of at DigitalCommons@University of Nebraska - Lincoln. It has been accepted for inclusion in Papers in the Earth and Atmospheric Sciences by an authorized administrator of DigitalCommons@University of Nebraska - Lincoln. Research Paper GEOSPHERE Sheeting joints and polygonal patterns in the Navajo Sandstone, southern Utah: Controlled by rock fabric, tectonic joints, buckling, GEOSPHERE, v. 14, no. 4 and gullying https://doi.org/10.1130/GES01614.1 David B. Loope and Caroline M. Burberry 14 figures; 1 table Department of Earth and Atmospheric Sciences, University of Nebraska, Lincoln, Nebraska 68588, USA CORRESPONDENCE: [email protected] ABSTRACT overburden, sheeting joints (like “A-tents” and “pop-ups”; Jahns, 1943; Ro- CITATION: Loope, D.B., and Burberry, C.M., 2018, mani and Twidale, 1999; Twidale and Bourne, 2003) have more recently been Sheeting joints and polygonal patterns in the Navajo Sandstone, southern Utah: Controlled by rock fabric, Sheeting joints are ubiquitous in outcrops of the Navajo Sandstone on the interpreted as products of compressive stresses parallel to exposed rock sur- tectonic joints, buckling, and gullying: Geosphere, west-central Colorado Plateau, USA. As in granitic terrains, these are open- faces (Holzhausen, 1989; Bahat et al., 1999; Martel, 2011, 2017). These stresses v. 14, no. 4, p. 1818–1836, https://doi.org/10.1130/ ing-mode fractures and form parallel to land surfaces. In our study areas in can be perturbed by local topography, so landscapes have strong influences GES01614.1. south-central Utah, liquefaction during Jurassic seismic events destroyed on the distribution and abundance of fresh, fractured rock (Miller and Dunne, stratification in large volumes of eolian sediment, and first-order sheeting 1996; St. Clair et al., 2015; Slim et al., 2015). At shallow depth, compressive Science Editor: Raymond M. Russo joints are now preferentially forming in these structureless (isotropic) sand- stress parallel to convex land surfaces induces tension perpendicular to the stones. Vertical cross-joints abut the land-surface-parallel sheeting joints, surface, allowing sheeting joints to open (Martel, 2011, 2017). Received 13 September 2017 Revision received 13 March 2018 segmenting broad (tens of meters) rock sheets into equant, polygonal slabs Sheeting joints are prominent and well known from outcrops of homoge- Accepted 2 May 2018 ~5 m wide and 0.25 m thick. On steeper slopes, exposed polygonal slabs have nous granite, but they are also well developed in some stratified sandstones Published online 8 June 2018 domed surfaces; eroded slabs reveal an onion-like internal structure formed (Bradley, 1963; Bahat et al., 1995). Formation of these joints is not restricted to by 5-m-wide, second-order sheeting joints that terminate against the cross- active plate boundaries; contemporaneous stresses are also forming them on joints, and may themselves be broken into polygons. In many structureless cratons and passive margins (Twidale and Bourne, 2009). Polygonal fracture sandstone bodies, however, the lateral extent of first-order sheeting joints patterns can develop in tabular granitic masses generated by sheet jointing (Ri- is severely limited by pre-existing, vertical tectonic joints. In this scenario, ley et al., 2012); such patterns are also prominent in sheet-jointed Navajo Sand- non-conjoined sheeting joints form extensive agglomerations of laterally con- stone (west-central Colorado Plateau, USA). The sheeting joints we describe tiguous, polygonal domes 3–6 m wide, exposing exhumed sheeting joints. possess most of the fundamental characteristics of sheeting joints in granite, These laterally confined sheeting joints are, in turn, segmented by short but the interactions of surface-parallel stresses, buckling, and gullying have vertical cross-joints into numerous small (~0.5 m) polygonal rock masses. generated spectacular, small-scale landforms that are unknown from granite We hypothesize that the sheeting joints in the Navajo Sandstone form via or any other rock type. The purpose of this field-based study is to describe and contemporaneous, land-surface-parallel compressive stresses, and that verti- interpret the structures, patterns, and landforms developed in sheet-jointed cal cross-joints that delineate polygonal masses (both large and small) form outcrops of the Jurassic Navajo Sandstone of southern Utah (Fig. 1). OLD G during compression-driven buckling of thin, convex-up rock slabs. Abrasion While the lateral scale and low curvature of some sheeting joints in the of friable sandstone during runoff events widens vertical tectonic joints into cross-stratified Navajo Sandstone are reminiscent of those seen in other ar- gullies, enhancing land-surface convexity. Polygonal rock slabs described here eas (e.g., Sierra Nevada granite, western USA; Gilbert, 1904; Matthes, 1930; provide a potential model for interpretation of similar-appearing patterns de- Martel, 2011), we show here that, in southern Utah, sheet-jointed sandstone OPEN ACCESS veloped on the surface of Mars. can form expansive composite landforms that resemble pans of giant bread muffins. Clusters of polygonal domes extend for hundreds of meters, but each exposed, convex sheeting joint measures <5 m in diameter (Fig. 2). INTRODUCTION In our study areas, the shapes and scales of most individual sheeting joints are strongly constrained by the spacing, continuity, and orientation of verti- Sheeting joints are opening-mode fractures that typically have convex-up cal joints. We will refer to some of these vertical joints (which are unrelated This paper is published under the terms of the curvature and form at shallow depth (<100 m) with no discernible offset (Mar- to topographic stresses) as “tectonic joints” (appearing as bold black lines in CC‑BY‑NC license. tel, 2017). Long viewed as “unloading structures” requiring removal of thick our diagrams). Also present are vertical cross-joints that form polygonal pat- © 2018 The Authors GEOSPHERE | Volume 14 | Number 4 Loope and Burberry | Sheeting joints and polygonal patterns in the Navajo Sandstone Downloaded from https://pubs.geoscienceworld.org/gsa/geosphere/article-pdf/14/4/1818/4265578/1818.pdf 1818 by Univ Nebraska Lincoln user on 04 December 2018 Research Paper Wa N Boulder terpocket fold A WY B DM ange 15 Escalante * NVNV 12 UT Figure 1. (A) Location of Colorado Plateau (red) and LRB* study area (gray). Two sites mentioned in Fig. 4 lie out- CCO side the study area: Little Rainbow Bridge (LRB) and So- W Basin and R wats Point (SP). WY—Wyoming; UT—Utah; CO—Colo- *SP 89 rado; AZ—Arizona; NM—New Mexico. (B) Outcrop map AAZZ NM of Jurassic Navajo Sandstone (gray) showing locations of the three southern Utah study sites: Coyote Buttes 110.9˚ (CB), Buckskin Gulch (BG), and Durfey Mesa (DM). Springdale Colorado Plateau 100 km 59 89 East Kaibab monocline Kanab BG CB 37.0˚ N Figure 2. Landforms controlled by strongly convex sheeting joints at Buckskin Gulch, southern Utah (37.045°N, 111.995°W, WGS84). Each 3–6-m-wide domed surface is an exhumed sheeting joint. Narrow gullies cut by runoff accentuate the boundaries between the large polygons. The smaller polygons are laterally bounded by short, vertical joints that abut the over- and underlying sheeting joints. GEOSPHERE | Volume 14 | Number 4 Loope and Burberry | Sheeting joints and polygonal patterns in the Navajo Sandstone Downloaded from https://pubs.geoscienceworld.org/gsa/geosphere/article-pdf/14/4/1818/4265578/1818.pdf 1819 by Univ Nebraska Lincoln user on 04 December 2018 Research Paper terns (thin black lines). Because sheeting joints (red lines) are opening-mode PREVIOUS STUDIES fractures, they cannot propagate across the voids generated by other open- ing-mode fractures. Compressive stresses can, however, be transmitted, al- Stratified and Structureless Navajo Sandstone beit in a perturbed state, across pre-existing vertical joints in the near surface (Rawnsley et al., 1992; Homberg et al., 1997; Zhao et al., 2008). The Navajo Sandstone, a Lower Jurassic quartz arenite, was deposited in a Compared to granite, most thick, wind-blown sandstones, although well giant dune field near the western edge of Pangea (Kocurek and Dott, 1983). The sorted, are quite heterogeneous. The bulk of the Navajo Sandstone is com- preserved deposits of this erg extend from central Wyoming to southeastern posed of large-scale, eolian cross-strata; thin laminations were deposited California. The formation is ~400 m thick in south-central Utah, but it thickens across dune slopes by migrating
Recommended publications
  • Hexagonal Fracture Patterns on Navajo Sandstone Crossbeds at Yellow Knolls, Washington County

    Hexagonal Fracture Patterns on Navajo Sandstone Crossbeds at Yellow Knolls, Washington County

    Hexagonal Fracture Patterns On Navajo Sandstone Crossbeds At Yellow Knolls, Washington County David B. Loope Earth & Atmospheric Sciences, University of Nebraska Lincoln, NE 68588-0340 [email protected] Utah Geosites 2019 Utah Geological Association Publication 48 M. Milligan, R.F. Biek, P. Inkenbrandt, and P. Nielsen, editors Cover Image: Southward-sloping crossbeds in the Navajo Sandstone at Yellow Knolls. M. Milligan, R.F. Biek, P. Inkenbrandt, and P. Nielsen, editors 2019 Utah Geological Association Publication 48 Presidents Message I have had the pleasure of working with many diff erent geologists from all around the world. As I have traveled around Utah for work and pleasure, many times I have observed vehicles parked alongside the road with many people climbing around an outcrop or walking up a trail in a canyon. Whether these people are from Utah or from another state or country, they all are quick to mention to me how wonderful our geology is here in Utah. Utah Geosites 2019 Utah is at the junction of several diff erent geological provinces. We have the Basin and Range to the west and the Central Utah Utah Geological Association Publication 48 Hingeline and Th rust Belt down the middle. Th e Uinta Mountains M. Milligan, R.F. Biek, P. Inkenbrandt, and P. Nielsen, editors have outcrops of some of the oldest sedimentary rock in Utah. Utah also has its share of young cinder cones and basaltic lava Utah Geosites showcases some of Utah’s spectacular geology, both fl ows, and ancient laccoliths, stratovolcanoes, and plutonic rocks. little-known localities and sites seen by visitors to Utah’s many Th e general public comes to Utah to experience our wonderful national and state parks and monuments.
  • Vermilion Cliffs

    Vermilion Cliffs

    2014 Manager’s Manager’s Annual Report Vermilion Cliffs National Monument Manager’s Annual Report FY 2014 Arizona Table of Contents 1 Vermilion Cliffs Profile 2 2 Planning and NEPA 5 3 Year’s Projects and Accomplishments 6 4 Science 10 5 Resources, Objects, Values, and Stressors 11 Summary of Performance Measures 20 6 7 Manager’s Letter 21 1 Vermilion Cliffs Profile 1 Designating Authority Designating Authority: Presidential Proclamation Date of Designation: November 9, 2000 If other legislation exists that has affected the management of the unit, list it here as well. N/A Acreage Total Acres in Unit BLM Acres Other Fed. Acres State Acres Other Acres 293,687 279,566 0 13,438 683 (private) Contact Information Unit Manager Phone E-mail Mailing Address Kevin Wright 435-688-3241 [email protected] 345 E Riverside Dr. St. George, UT 84790 Field Office District Office State Office Arizona Strip Arizona Strip AZ Budget Total FY14 Budget Subactivity 1711 Other Subactivities’ Other Funding Contributions 789,359 376,009 413,350 2 Map of Vermilion Cliffs National Monument 3 Managing Partners If an outside group or a non-BLM agency (like the Park or Forest Service) formally helps to manage the unit, please describe them in this section. If BLM is the sole official manager of the unit, simply enter “N/A.” Regular partnerships and partner activities are covered in a later section of this report. N/A Staffing How is the unit’s work accomplished? Does it have its own dedicated manager and staff? Does it share staff with another unit, BLM office, or other Federal agency? Summarize the types (e.g., job series) and numbers of staff members.
  • Arizona, Road Trips Are As Much About the Journey As They Are the Destination

    Arizona, Road Trips Are As Much About the Journey As They Are the Destination

    Travel options that enable social distancing are more popular than ever. We’ve designated 2021 as the Year of the Road Trip so those who are ready to travel can start planning. In Arizona, road trips are as much about the journey as they are the destination. No matter where you go, you’re sure to spy sprawling expanses of nature and stunning panoramic views. We’re looking forward to sharing great itineraries that cover the whole state. From small-town streets to the unique landscapes of our parks, these road trips are designed with Grand Canyon National Park socially-distanced fun in mind. For visitor guidance due to COVID19 such as mask-wearing, a list of tourism-related re- openings or closures, and a link to public health guidelines, click here: https://www.visitarizona. com/covid-19/. Some attractions are open year-round and some are open seasonally or move to seasonal hours. To ensure the places you want to see are open on your travel dates, please check their website for hours of operation. Prickly Pear Cactus ARIZONA RESOURCES We provide complete travel information about destinations in Arizona. We offer our official state traveler’s guide, maps, images, familiarization trip assistance, itinerary suggestions and planning assistance along with lists of tour guides plus connections to ARIZONA lodging properties and other information at traveltrade.visitarizona.com Horseshoe Bend ARIZONA OFFICE OF TOURISM 100 N. 7th Ave., Suite 400, Phoenix, AZ 85007 | www.visitarizona.com Jessica Mitchell, Senior Travel Industry Marketing Manager | T: 602-364-4157 | E: [email protected] TRANSPORTATION From east to west both Interstate 40 and Interstate 10 cross the state.
  • Paria Canyon Vermilion Cliffs Wilderness Management Plan

    Paria Canyon Vermilion Cliffs Wilderness Management Plan

    01\16• ,.J ~ UNITED STATES DEPARTMENT OF THE INTERIOR -- BUREAU OF LAND MANAGEMENT ~Lf 1.,.J/ t'CI/C w~P 0 ARIZONA STRIP FIELD OFFICE/KANAB RESOURCE AREA PARIA CANYONNERMILION CLIFFS WILDERNESS MANAGEMENT PLAN AMENDMENT ENVIRONMENTAL ASSESSMENT EA-AZ-01 0-97-16 I. INTRODUCTION The Paria Canyon - Vermilion Cliffs Wilderness Area contains 112,500 acres (92,500 acres in Coconino County, Arizona and 20,000 acres in Kane County, Utah) of public lands managed by the Bureau of Land Management. The area is approximately 10 to 30 miles west of Page, Arizona. Included are 35 miles of the Paria river Canyon, 15 miles of the Buckskin Gulch, Coyote Buttes, and the Vermilion Cliffs from Lee's Ferry to House Rock Valley (Map 1). The Paria Canyon, Buckskin Gulch, Wire Pass, and the Coyote Buttes Special Management Area are part of the larger Paria Canyon-Vermilion Cliffs Wilderness, designated in August 1984 (Map 2). Existing management plan guidance is to protect primitive, natural conditions and the many outstanding opportunities for hiking, backpacking, photographing, or viewing in the seven different highly scenic geologic formations from which the canyons and buttes are carved. Visitor use in Paria Canyon, Buckskin Gulch, and Coyote Buttes has increased from 2,400 visits in Fiscal Year (FY) 1986 to nearly 10,000 visits in FY96-a 375% increase in use over 10 years. This increased use, combined with the narrow nature of the canyons, small camping terraces, and changing visitor use patterns, is impacting the wilderness character of these areas. Human waste, overcrowding, and public safety have become important issues.
  • 1 Uphill-Only Dinosaur Tracks? a Talking Rocks 2017 Participant

    1 Uphill-Only Dinosaur Tracks? a Talking Rocks 2017 Participant

    1 Uphill-only Dinosaur Tracks? A Talking Rocks 2017 Participant Seeks Answers Robert T. Johnston Talking Rocks 2017 was a geology tour organized by Adventist pastor John McLarty and guided by Gerald Bryant, an Adventist geology professor at Dixie State University (St. George, UT) and an expert in the sedimentary geology of the area—in particular, the extensive sandstone outcrops of the geologic unit formally known as the Navajo Sandstone. I had the pleasure of participating in the first Talking Rocks tour last year and enjoyed the experience so much that I went again this year! Two other participants from 2016 also repeated. New participants included a mix of men and women of varied backgrounds and points of view on the age of the earth and “Flood geology”, and two children. Besides Bryant, none of us had formal geology backgrounds, but we were eager to learn more about geology and the intersection of faith and science. We converged on St. George, Utah, from where we traveled to various sites in Utah and northern Arizona. Places not visited last year included the Pine Valley Mountains, new sites in Snow Canyon, and a hike to what locals call the Vortex, an amazing area where a complex stack of ancient, trough-shaped dune deposits is dissected by the modern canyons. The topography features an enormous vortex-shaped “scour pit”1 at the top of a ridge, where sand grains loosened by weathering are removed by wind currents sweeping the landscape (Figure 1). Figure 1. Talking Rocks organizer John McLarty making his way into the Vortex, a weathered and eroded Navajo Sandstone feature north of St.
  • Directions to Hiking to Coyote Buttes & the Wave

    Directions to Hiking to Coyote Buttes & the Wave

    Coyote Buttes/The Waves Ron Ross December 22, 2007 Coyote Buttes is located in the Paria Canyon-Vermilion Cliffs Wilderness just south of US¶89 about halfway between Kanab, Utah and Page, Arizona. The wilderness area sits on the border between Arizona and Utah and is managed by the BLM. It is divided into two areas: Coyote Buttes North and Coyote Buttes South. To visit either of the Coyote Buttes areas you will need to purchase a hiking permit in advance (see https://www.blm.gov/az/paria/index.cfm?usearea=CB). Only 20 people per day (10 advanced reservations and 10 walk-ins) are allowed to hike in, and separate permits are required for the North and South sections. The walk-in permits can be acquired off the web, from the BLM office in Kanab, or from the Paria Ranger Station near the Coyote Buttes. The Northern section of Coyote Buttes is by far the most popular, as it contains the spectacular sandstone rock formations, pictured below, known as the Wave and the Second Wave. As a result of their popularity, getting permits for the Northern section is very competitive and often results in a lottery to select the lucky folks for a particular day. The Southern section also contains some outstanding sandstone formations known as the Te- pees. However, the road to the southern section can be very sandy and challenging, even for high- clearance 4x4 vehicles. As a result, walk-in permits for the Southern section are widely available. COYOTE BUTTES NORTH—THE WAVE Trailhead The hike to the wave begins at the Wire Pass Trailhead about 8 miles south of US¶89 on House Rock Valley Road.
  • Zion National Park Tour from Las Vegas (Zion)

    Zion National Park Tour from Las Vegas (Zion)

    ZION NATIONAL PARK TOUR FROM LAS VEGAS (ZION) Zion National Park, just 163 miles from Las Vegas is located near Springdale, Utah, covers 229 square miles (590 km2) at the junction of the Colorado Plateau, Great Basin, and Mojave Desert regions, the park's unique geography and variety of life zones allow for unusual plant and animal diversity. The primary feature of the park is Zion Canyon, which is 15 miles (24 km) long and up to half a mile (800 m) deep cut through the sandstone by the North Fork of the Virgin River. Common daytime animals include mule deer, rock squirrels, pinyon jays, as well as whiptail and collared lizards. Desert cottontails, jackrabbits, and Merriam's kangaroo rats come out at night. Cougars, coyotes, gray foxes, and ring-tail cats are the top predators. The park is home to 289 bird, 79 mammal, 28 reptile, 7 fish, and 6 amphibian species. Golden eagles, red-tailed hawks, peregrine falcons, and white- throated swifts can be seen in the area. California condors and bighorn sheep were reintroduced in the 1990s. Nineteen species of bat also live in the area. Notable geographical features of the park which leave visitors in awe include the Virgin River Narrows, Emerald Pools, Hidden Canyon, Angels Landing, The Great White Throne, Checkerboard Mesa, The Three Patriarchs, and Kolob Arch. The geology of the Zion and Kolob canyons area includes nine formations that together represent 150 million years of mostly Mesozoic-aged sedimentation. This entire area was truly created by the hand of God. ZION NATIONAL PARK TOUR FROM LAS VEGAS Artists and photographers have been drawn to Zion for decades in an effort to capture its infinite variety of moods.
  • Hexagonal Fracture Patterns on Navajo Sandstone Crossbeds at Yellow Knolls, Washington County

    Hexagonal Fracture Patterns on Navajo Sandstone Crossbeds at Yellow Knolls, Washington County

    University of Nebraska - Lincoln DigitalCommons@University of Nebraska - Lincoln Earth and Atmospheric Sciences, Department Papers in the Earth and Atmospheric Sciences of 2019 Hexagonal Fracture Patterns On Navajo Sandstone Crossbeds At Yellow Knolls, Washington County David Loope Follow this and additional works at: https://digitalcommons.unl.edu/geosciencefacpub Part of the Earth Sciences Commons This Article is brought to you for free and open access by the Earth and Atmospheric Sciences, Department of at DigitalCommons@University of Nebraska - Lincoln. It has been accepted for inclusion in Papers in the Earth and Atmospheric Sciences by an authorized administrator of DigitalCommons@University of Nebraska - Lincoln. Hexagonal Fracture Patterns On Navajo Sandstone Crossbeds At Yellow Knolls, Washington County David B. Loope Earth & Atmospheric Sciences, University of Nebraska Lincoln, NE 68588-0340 [email protected] Utah Geosites 2019 Utah Geological Association Publication 48 M. Milligan, R.F. Biek, P. Inkenbrandt, and P. Nielsen, editors Cover Image: Southward-sloping crossbeds in the Navajo Sandstone at Yellow Knolls. M. Milligan, R.F. Biek, P. Inkenbrandt, and P. Nielsen, editors 2019 Utah Geological Association Publication 48 Presidents Message I have had the pleasure of working with many diff erent geologists from all around the world. As I have traveled around Utah for work and pleasure, many times I have observed vehicles parked alongside the road with many people climbing around an outcrop or walking up a trail in a canyon. Whether these people are from Utah or from another state or country, they all are quick to mention to me how wonderful our geology is here in Utah.
  • Nature Photography

    Nature Photography

    Experiences and Changes Text and Photography Copyright Pete and Alice Bengeyfield All rights reserved. Antelope Canyon. Coyote Buttes. Two small patches of sandstone that in recent years have become photographic icons of the red rock country. Landscape photographers that were formerly judged by their treatment of Delicate Arch or the Great White Throne, now make pilgrimages to these new locations in order to define the Colorado Plateau. Both are intimately spectacular. Both reflect the color, form, and texture that are the hallmarks of the region. However, although they are products of the erosive forces that shaped the Plateau, they are quite different in appearance. Antelope Canyon is an underground kaleidoscope of color. Beams of sunlight penetrate a narrow slit in the earth's surface, bouncing off planes and angles of sandstone that have been shaped over the years by the surging waters of flash floods. In dark, narrow canyons, a spectrum of warm colors change constantly with the sun's measured pace across the sky. Coyote Buttes is the anti-canyon. Twisted sandstone outcrops split the sky from the backbone of a high ridge that rises in isolation above the surrounding sagebrush hills. At dawn and dusk, long, low light paints the layered rock in Colorado Plateau colors, while sinuous curves and shadows intertwine the scene. The two are roughly a hundred miles apart, down on the Arizona-Utah border. In May of 2000, my wife and I made a week long trip to photograph them. I had been to Antelope Canyon twice before, in 1990 and 1993, but despite having hiked nearby Buckskin Gulch, had never visited Coyote Buttes.
  • Arizona Strip Visitor Map Arizona

    Arizona Strip Visitor Map Arizona

    / •/ Jte A^ [?*"tfi L' h / P t JEM' • t£ L, OURMiSSION We serve customers from around the corner and around the world by integrating growing public needs with traditional uses on the remote public lands &z^Bflfch — north of the Grand Canyon. / ADDRESSES & WEBSITES BUREAU OF LAND MANAGEMENT —ARIZONA PUBLIC LANDf A • (-t • r-A- , • , A-\rr- i i r ,• r~ Collared llizari d Arizona atrip District Ottice and Information Center Grand Canyon-Parashant National Monument 345 E. Riverside Drive, St. George, UT 84790 Phone (435) 688-3200/3246 http://www.blm.gov/az/asfo/index.htm Arizona Strip Interpretive Association (ASIA) 345 E. Riverside Drive, St. George, UT 84790 Phone (435) 688-3246 http://www.thearizonastrip.com —UTAH PUBLIC LANDS— St. George Field Office and Information Center 345 E. Riverside Drive, St. George, UT 84790 Phone (435) 688-3200 http://www.ut.blm.gov/st_george Kanab Field Office 318 N. 100 E.,Kanab, UT 84741 ,« Visitor Map Phone (435) 644-4600 O.vJU http://www.ut.blm.gov/kanab 2DQfj Grand Staircase-Escalante National Monument 190 E. Center Street, Kanab, UT 84741 Phone (435) 644-4300/4680 (visitor information) http://www.ut.blm.gov/spotgse.html FOREST SERVICE North Kaibab Ranger District 430 South Main, Fredonia, AZ 86022 Phone (928) 643-7395 http://www.fs.fed.us/r3/kai NATIONAL PARK SERVICE Grand Canyon National Park P.O. Box 129, Grand Canyon, AZ 86023 Phone (928) 638-7888 http://www.nps.gov/grca Lake Mead National Recreation Area 601 Nevada Way, Boulder City, NV 89005 Phone (702) 293-8990 http://www.nps.gov/lame View from Black Rock Mountain, AZ Glen Canyon National Recreation Area P.O.Box 1507, Page, AZ 86040 FOR EMERGENCIES, CALL: Phone (928) 608-6404 http://www.nps.gov/glca Washington County, UT 91 1 or (435) 634-5730 Kane County, UT 91 1 or (435) 644-2349 Pipe Spring National Monument 406 N.
  • Erosion, Weathering, and Change Activity Guide

    Erosion, Weathering, and Change Activity Guide

    National Park Service U.S. Department of the Interior Zion National Park Weathering, Erosion, and Change Geologic Events in Zion PHOTO CREDIT Contents Introduction 2 Core Connections 2 Background 2 Activities Earth’s Power Punches 4 Rock On, Zion 5 It Happened Here! 6 Glossary 8 References 9 Introduction This guide contains background information about how weathering, erosion, and other geologic processes such as volcanoes continually shape the landscape, and directions for three activities that will help students better understand how these processes are at work in Utah. This guide is specifically designed for fifth grade classrooms, but the activities can be NPS modified for students at other levels. Theme of deposition (sedimentation), lithification, The Earth’s surface is a dynamic system that is uplift, weathering, erosion, tectonics, and constantly changing due to weathering, volcanic activity make the park a showcase for erosion, floods, earthquakes, volcanoes, and changing landscapes. other geologic events. Deposition (Sedimentation) Focus Zion National Park was a relatively flat basin The activities focus on relationship between near sea level 275 million years ago, near the NPS/MARC NEIDIG geologic processes such as weathering and coast of Pangaea, the land area believed to erosion and changes on the Earth’s surface. have once connected nearly all of the earth’s landmasses together. As sands, gravels, and Activities muds eroded from surrounding mountains, Earth’s Power Punches streams carried these materials into the Students view a presentation of digital im- basin and deposited them in layers. The sheer ages showing the forces that shape the Earth’s weight of these accumulated layers caused surface.
  • The Colorado Plateau

    The Colorado Plateau

    The Colorado Plateau An OUGS Severnside Field Trip 2015 The Colorado Plateau 2015 Introduction This was to be another Severnside trip, but one with a new organiser! Janet Hiscott and Tom Sharpe had devised the idea for this trip when talking about what he would do in his retirement from the Museum of Wales. The large group of 27 members that collected in Denver at the end of September 2015 were the beneficiaries of this chat. We were all eager to explore the Colorado Plateau with Janet and Tom to guide us. The Colorado Plateau is an area between the Rockies and the Basin and Range Province and extends through parts of 4 states, Utah, Colorado, New Mexico and Arizona. (Fig. 1) It contains some of the most famous and most visited National Parks of the USA and we were here for 17 days to be introduced to the geology, paleontology and human interaction with and exploitation of the region. The Rockies have been through several cycles of uplift and erosion since the Precambrian, the most recent period of uplift started 5Ma ago and the area has seen a change in elevation of 5000ft. There was associated volcanic activity, building volcanoes and causing a redistribution of metals by heated fluids. The latter having been exploited by man in the Colorado Mineral Belt. The debris eroded from the Rockies during these successive periods of upift was deposited in the plains surrounding them. These sediments, and marine deposits from a period of inundation by an inland sea, form the level beds that comprise the Colorado plateau.