DOCSLIB.ORG

Bubble Shapes and Orientations in Obsidian Lavas, Pyroclasts, and Vents of the Tweed Shield Volcano,…

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Bubble Shapes and Orientations in Obsidian Lavas, Pyroclasts, and Vents of the Tweed Shield Volcano,… 4/21/2020 Abstract: BUBBLE SHAPES AND ORIENTATIONS IN OBSIDIAN LAVAS, PYROCLASTS, AND VENTS OF THE TWEED SHIELD VOLCANO,… Start |Grid View | Author Index | View Uploaded Presentations | Meeting Information North-Central Section - 54th Annual Meeting - 2020 Paper No. 29-17 Presentation Time: 8:30 AM-5:30 PM BUBBLE SHAPES AND ORIENTATIONS IN OBSIDIAN LAVAS, PYROCLASTS, AND VENTS OF THE TWEED SHIELD VOLCANO, EASTERN AUSTRALIA FLINT, Juliana M., Center for Earth and Environmental Science, SUNY Plattsburgh, Plattsburgh, NY 12901 and KNESEL, Kurt, Department of Geosciences, Trinity University, One Trinity Place, San Antonio, TX 78212 The Tweed volcano in eastern Australia consists of the eroded remnants of a former volcanic shield some 100 km in diameter constructed in the early Miocene. The volcano hosts an unusually high proportion of rhyolite lavas and pyroclastic units, which are heavily dissected and provide excellent stratigraphic exposure. To assess the flow conditions of both effusive and explosive eruptions of rhyolitic magma, we examine the shapes and orientations of deformed bubbles in obsidian samples from some of these well- exposed lavas, pyroclastic deposits, and their associated vents. Bubble deformation in a highly viscous, low Reynolds number fluid, such as rhyolitic magma, is governed by the competing shear stress that deform the bubble and the surface-tension stresses that minimize interfacial area. The ratio of these stresses is the capillary number, Ca. Here we use the relationships between Ca and the shape and orientation of bubbles to evaluate the type and magnitude of shear stress associated magma flow. For each sample, the 3-D shapes of bubbles were measured using a petrographic microscope and two mutually perpendicular thin-sections cut perpendicular to the flow banding following the method outlined in Rust et al. (2003). Flow-induced bubble deformation is quantified as a dimensionless number, D, given by (l-b)/(l+b), where l and b are the semi-major and semi-minor axes of the deformed bubble. Bubble orientations in all samples are indicative of predominantly simple shear, with minor components of pure shear and bubble relaxation in some populations.Bubble deformation is modest in the obsidian lava, yielding shear stresses of a few kPa. In contrast, bubble geometries in obsidian clasts from pyroclastic flow and fall units record greater deformation and shear stresses between 50 and 90 kPa. Bubbles in samples from the vent, thought to be associated with a boulder tuff (agglomerate), yield intermediate shear stresses of 10 to 30 kPa, which somewhat surprisingly do not correlate with distance from the conduit walls. The moderate shear stresses for the vent samples are consistent with a fountain-fed origin for the boulder tuff. Rust, A.C., Manga, M., and Cashman, K.V., 2003, Determining flow type, shear rate and shear stress in magmas from bubble shapes and orientations. J. Volcanol. Geotherm. Res. 122, 111-132. Session No. 29--Booth# 21 T4. Petrology, Mineralogy, and High-Temperature Geochemistry (Posters) Tuesday, 19 May 2020: 8:30 AM-5:30 PM Lake Superior Ballroom KJ (Duluth Entertainment Convention Center) Geological Society of America Abstracts with Programs. Vol. 52, No. 5 doi: 10.1130/abs/2020NC-348341 © Copyright 2020 The Geological Society of America (GSA), all rights reserved. Permission is hereby granted to the author(s) of this abstract to reproduce and distribute it freely, for noncommercial purposes. Permission is hereby granted to any individual scientist to download a single copy of this electronic file and reproduce up to 20 paper copies for noncommercial purposes advancing science and education, including classroom use, providing all reproductions include the complete content shown here, including the author information. All other forms of reproduction and/or transmittal are prohibited without written permission from GSA Copyright Permissions. Back to: T4. Petrology, Mineralogy, and High-Temperature Geochemistry (Posters) << Previous Abstract | Next Abstract https://gsa.confex.com/gsa/2020NC/webprogram/Paper348341.html 1/1.
Load more

Recommended publications
  • Summary of the Mineral Information Package for the Khanneshin Carbonatite Area of Interest
    Chapter 21A. Summary of the Mineral Information Package for the Khanneshin Carbonatite Area of Interest Contribution by Robert D. Tucker, Harvey E. Belkin, Klaus J. Schulz, Stephen G. Peters, and Kim P. Buttleman Abstract The Khanneshin carbonatite is a deeply dissected igneous complex of Quaternary age that rises approximately 700 meters above the flat-lying Neogene sediments of the Registan Desert, Helmand Province, Afghanistan. The complex consists almost exclusively of carbonate-rich intrusive and extrusive igneous rocks, crudely circular in outline, with only three small hypabyssal plugs of leucite phonolite and leucitite outcropping in the southeastern part of the complex. The complex is broadly divisible into a central intrusive vent (or massif), approximately 4 kilometers in diameter, consisting of coarse-grained sövite and brecciated and agglomeratic barite-ankerite alvikite; a thin marginal zone (less than 1 kilometer wide) of outwardly dipping (5°–45°). Neogene sedimentary strata; and a peripheral apron of volcanic and volcaniclastic strata extending another 3–5 kilometers away from the central intrusive massif. Small satellitic intrusions of biotite-calcite carbonatite, no larger than 400 meters in diameter, crop out on the southern and southeastern margin of the central intrusive massif. In the 1970s several teams of Soviet geologists identified prospective areas of interest for uranium, phosphorus, and light rare earth element (LREE) mineralization in four regions of the carbonatite complex. High uranium concentrations are reported in two regions; the greatest concentrations are confined to silicified shear zones in sandy clay approximately 1.1 kilometers southwest of the peripheral part of the central vent. An area of phosphorus enrichment, primarily occurring in apatite, is present in coarse-grained agglomeratic alvikite, with abundant fenite xenoliths, approximately 750 meters south of the periphery of the central vent.
    [Show full text]
  • Geology of the Nairobi Region, Kenya
    % % % % % % % % %% %% %% %% %% %% %% % GEOLOGIC HISTORY % %% %% % % Legend %% %% %% %% %% %% %% % % % % % % HOLOCENE: %% % Pl-mv Pka %%% Sediments Mt Margaret U. Kerichwa Tuffs % % % % %% %% % Longonot (0.2 - 400 ka): trachyte stratovolcano and associated deposits. Materials exposed in this map % %% %% %% %% %% %% % section are comprised of the Longonot Ash Member (3.3 ka) and Lower Trachyte (5.6-3.3 ka). The % Pka' % % % % % % L. Kerichwa Tuff % % % % % % Alluvial fan Pleistocene: Calabrian % % % % % % % Geo% lo% gy of the Nairobi Region, Kenya % trachyte lavas were related to cone building, and the airfall tuffs were produced by summit crater formation % % % % % % % % % % % % % % % % % Pna % % % % %% % (Clarke et al. 1990). % % % % % % Pl-tb % % Narok Agglomerate % % % % % Kedong Lake Sediments Tepesi Basalt % % % % % % % % % % % % % % % % %% % % % 37.0 °E % % % % 36.5 °E % % % % For area to North see: Geology of the Kijabe Area, KGS Report 67 %% % % % Pnt %% % PLEISTOCENE: % % %% % % % Pl-kl %% % % Nairobi Trachyte % %% % -1.0 ° % % % % -1.0 ° Lacustrine Sediments % % % % % % % % Pleistocene: Gelasian % % % % % Kedong Valley Tuff (20-40 ka): trachytic ignimbrites and associated fall deposits created by caldera % 0 % 1800 % % ? % % % 0 0 % % % 0 % % % % % 0 % 0 8 % % % % % 4 % 4 Pkt % formation at Longonot. There are at least 5 ignimbrite units, each with a red-brown weathered top. In 1 % % % % 2 % 2 % % Kiambu Trachyte % Pl-lv % % % % % % % % % % %% % % Limuru Pantellerite % % % % some regions the pyroclastic glass and pumice has been
    [Show full text]
  • Lamington National Park Management Plan 2011
    South East Queensland Bioregion Prepared by: Planning Services Unit Department of Environment and Resource Management © State of Queensland (Department of Environment and Resource Management) 2011 Copyright protects this publication. Except for purposes permitted by the Copyright Act 1968, reproduction by whatever means is prohibited without the prior written permission of the Department of Environment and Resource Management. Enquiries should be addressed to Department of Environment and Resource Management, GPO Box 2454, Brisbane Qld 4001. Disclaimer This document has been prepared with all due diligence and care, based on the best available information at the time of publication. The department holds no responsibility for any errors or omissions within this document. Any decisions made by other parties based on this document are solely the responsibility of those parties. Information contained in this document is from a number of sources and, as such, does not necessarily represent government or departmental policy. This management plan has been prepared in accordance with the Nature Conservation Act 1992. This management plan does not intend to affect, diminish or extinguish native title or associated rights. Note that implementing some management strategies might need to be phased in according to resource availability. For information on protected area management plans, visit <www.derm.qld.gov.au>. If you need to access this document in a language other than English, please call the Translating and Interpreting Service (TIS National) on 131 450 and ask them to telephone Library Services on +61 7 3224 8412. This publication can be made available in alternative formats (including large print and audiotape) on request for people with a vision impairment.
    [Show full text]
  • North Coast Bioregion
    171 CHAPTER 14 The North Coast Bioregion 1. Location 2. Climate The North Coast Bioregion runs up the east coast of NSW from just north of The general trend in this bioregion from east to west is from a sub-tropical Newcastle to just inside the Qld border. The total area of the bioregion is climate on the coast with hot summers, through sub-humid climate on the 5,924,130 ha (IBRA 5.1) and the NSW portion is 5,692,351.6 ha or 96.1% of the slopes to a temperate climate in the uplands in the western part of the bioregion. The NSW portion of North Coast Bioregion occupies 7.11% of the bioregion, characterised by warm summers and no dry season. A montane state. climate occurs in a small area in the southwest of the bioregion at higher elevations. The Sydney Basin Bioregion bounds the North Coast Bioregion in the south and the Nandewar and New England Tablelands bioregions lie against its western boundary. The North Coast Bioregion has proven to be a popular 3. Topography place to live, with hundreds of “holiday towns” lining the coast and eastern inland, including Port Macquarie, Ballina, Coffs Harbour, Byron Bay, Tweed The North Coast Bioregion covers northern NSW from the shoreline to the Heads, Lismore, Alstonville, Dorrigo, Forster and Taree. Great Escarpment. Typically, there is a sequence from coastal sand barrier, through low foothills and ranges, to the steep slopes and gorges of the The Tweed, Richmond, Clarence, Coffs Harbour, Bellinger, Nambucca, Macleay, Escarpment itself, with rainfall increasing inland along this transect.
    [Show full text]
  • We Tend to Think of Tamborine Mountain Itself As Timeless And
    NATURE NOTES With Tamborine Mountain Natural History Association www.naturalhistory.org.au We tend to think of Tamborine Mountain itself as timeless and unchanging, in fact the landform we know today has been created and modified by millions of years of geological processes such as erosion, weathering, subduction and volcanic activity. The Mountain’s geological history includes being 1000m underwater, thrust up from the seabed, smothered in lava and eroded Three to four hundred million years ago, the eastern edge of Australia was west of its present position. In our region the coastline was west of Toowoomba, shallow seas and a continental shelf extended eastward. Our area was in deep ocean probably over 1000 metres in depth. Around this time (give or take a few million years), west of Toowoomba the oceanic crustal plate was forced under the continental plate (subduction) forming a chain of volcanoes. Over millions of years basalt lava flows and large volumes of eroded sediments from the mountain chain flowed or were deposited eastward. The sea became shallower as evidenced by the shallow sea fossils found on the foothills of Mt Barney. Three to two hundred million years ago, geological activity on the deep seabed thrust up a high mountain range called the Neranleigh-Fernvale beds. This high terrain was reduced by erosion, and is now seen as the eastern foothills of the Tamborine Plateau, Cedar Creek Falls and outcrops on the north of the Plateau. Two hundred and fifty million years ago, the eastern edge of the continent began to stabilise, but then about two hundred and twenty five million years ago there were widespread violent volcanic eruptions west of the Neranleigh-Fernvale beds.
    [Show full text]
  • Petroglyph National Monument: Geologic Resources Inventory Report
    National Park Service U.S. Department of the Interior Natural Resource Stewardship and Science Petroglyph National Monument Geologic Resources Inventory Report Natural Resource Report NPS/NRSS/GRD/NRR—2017/1547 ON THE COVER Photograph of Albuquerque volcanoes. Three spatter cones, known as the Sisters, form a distinctive skyline west of Albuquerque, New Mexico. These small volcanoes are part of the Albuquerque volcanic field and occur in the Volcanoes area of Petroglyph National Monument. The volcanic field was active about 156,000 years ago. NPS photograph by Chanteil Walter (Petroglyph National Monument). THIS PAGE Photograph of the West Mesa escarpment along the Rinconada Canyon Trail. Erosion of the Santa Fe Group sediments that underlie a basaltic cap rock has caused large blocks of rock to tumble down the eastern escarpment of the mesa. Most of the petroglyphs were chiseled into the dark patina of desert varnish on these large boulders, exposing the lighter colored basaltic rock beneath. NPS photograph by Dale Pate (Geologic Resources Division). Petroglyph National Monument Geologic Resources Inventory Report Natural Resource Report NPS/NRSS/GRD/NRR—2017/1547 Katie KellerLynn Colorado State University Research Associate National Park Service Geologic Resources Division Geologic Resources Inventory PO Box 25287 Denver, CO 80225 November 2017 U.S. Department of the Interior National Park Service Natural Resource Stewardship and Science Fort Collins, Colorado The National Park Service, Natural Resource Stewardship and Science office in Fort Collins, Colorado, publishes a range of reports that address natural resource topics. These reports are of interest and applicability to a broad audience in the National Park Service and others in natural resource management, including scientists, conservation and environmental constituencies, and the public.
    [Show full text]
  • The Scenic Rim of Southeastern Queensland, Australia: a History of Mid Cenozoic Intraplate Volcanism
    103 by Benjamin E. Cohen The scenic rim of southeastern Queensland, Australia: A history of mid Cenozoic intraplate volcanism School of Earth Sciences, The University of Queensland, Brisbane, QLD 4072, Australia. E-Mail: [email protected] Intraplate volcanism was widespread in southeastern volcanism extending over 4,000 km, covering a present-day area of 2 Queensland during the mid Cenozoic, leaving a legacy 1.6 million km (Figure 1a) (Johnson, 1989). Eruptions occurred throughout the Cenozoic (Wellman and McDougall, 1974; of variably eroded volcanoes and rugged topography Vasconcelos et al., 2008), with the most recent activity as little as known locally as “The Scenic Rim”. These plume-derived 4.3 kya (Blackburn et al., 1982; Robertson et al., 1996). volcanoes provide a detailed record of northward The products of intraplate volcanism were particularly abundant Australian plate velocity, and indicate a major slowdown in SE Queensland during the mid Cenozoic, extending over the state commencing at 26 Ma and persisting until 23 Ma, border into New South Wales (Figures 1 and 2). The largest Cenozoic volcanoes on the continent are located in this region; the Main Range correlated with initial collision of the massive Ontong volcano is over 80 km N-S, and Tweed has a diameter of c. 100 km Java plateau with the northern subduction margin of the (Figure 1b). This region also hosts some of the greatest diversity of Australian plate. Despite traversing over 36 km of magma types found in eastern Australia, and an unusually large volume continental crust, trace element and isotopic signatures of highly fractionated rhyolites (Ewart et al., 1985; Ewart and Grenfell, 1985; Ewart et al., 1988).
    [Show full text]
  • Lunar Crater Volcanic Field (Reveille and Pancake Ranges, Basin and Range Province, Nevada, USA)
    Research Paper GEOSPHERE Lunar Crater volcanic field (Reveille and Pancake Ranges, Basin and Range Province, Nevada, USA) 1 2,3 4 5 4 5 1 GEOSPHERE; v. 13, no. 2 Greg A. Valentine , Joaquín A. Cortés , Elisabeth Widom , Eugene I. Smith , Christine Rasoazanamparany , Racheal Johnsen , Jason P. Briner , Andrew G. Harp1, and Brent Turrin6 doi:10.1130/GES01428.1 1Department of Geology, 126 Cooke Hall, University at Buffalo, Buffalo, New York 14260, USA 2School of Geosciences, The Grant Institute, The Kings Buildings, James Hutton Road, University of Edinburgh, Edinburgh, EH 3FE, UK 3School of Civil Engineering and Geosciences, Newcastle University, Newcastle, NE1 7RU, UK 31 figures; 3 tables; 3 supplemental files 4Department of Geology and Environmental Earth Science, Shideler Hall, Miami University, Oxford, Ohio 45056, USA 5Department of Geoscience, 4505 S. Maryland Parkway, University of Nevada Las Vegas, Las Vegas, Nevada 89154, USA CORRESPONDENCE: gav4@ buffalo .edu 6Department of Earth and Planetary Sciences, 610 Taylor Road, Rutgers University, Piscataway, New Jersey 08854-8066, USA CITATION: Valentine, G.A., Cortés, J.A., Widom, ABSTRACT some of the erupted magmas. The LCVF exhibits clustering in the form of E., Smith, E.I., Rasoazanamparany, C., Johnsen, R., Briner, J.P., Harp, A.G., and Turrin, B., 2017, overlapping and colocated monogenetic volcanoes that were separated by Lunar Crater volcanic field (Reveille and Pancake The Lunar Crater volcanic field (LCVF) in central Nevada (USA) is domi­ variable amounts of time to as much as several hundred thousand years, but Ranges, Basin and Range Province, Nevada, USA): nated by monogenetic mafic volcanoes spanning the late Miocene to Pleisto­ without sustained crustal reservoirs between the episodes.
    [Show full text]
  • The Boring Volcanic Field of the Portland-Vancouver Area, Oregon and Washington: Tectonically Anomalous Forearc Volcanism in an Urban Setting
    Downloaded from fieldguides.gsapubs.org on April 29, 2010 The Geological Society of America Field Guide 15 2009 The Boring Volcanic Field of the Portland-Vancouver area, Oregon and Washington: Tectonically anomalous forearc volcanism in an urban setting Russell C. Evarts U.S. Geological Survey, 345 Middlefi eld Road, Menlo Park, California 94025, USA Richard M. Conrey GeoAnalytical Laboratory, School of Earth and Environmental Sciences, Washington State University, Pullman, Washington 99164, USA Robert J. Fleck Jonathan T. Hagstrum U.S. Geological Survey, 345 Middlefi eld Road, Menlo Park, California 94025, USA ABSTRACT More than 80 small volcanoes are scattered throughout the Portland-Vancouver metropolitan area of northwestern Oregon and southwestern Washington. These vol- canoes constitute the Boring Volcanic Field, which is centered in the Neogene Port- land Basin and merges to the east with coeval volcanic centers of the High Cascade volcanic arc. Although the character of volcanic activity is typical of many mono- genetic volcanic fi elds, its tectonic setting is not, being located in the forearc of the Cascadia subduction system well trenchward of the volcanic-arc axis. The history and petrology of this anomalous volcanic fi eld have been elucidated by a comprehensive program of geologic mapping, geochemistry, 40Ar/39Ar geochronology, and paleomag- netic studies. Volcanism began at 2.6 Ma with eruption of low-K tholeiite and related lavas in the southern part of the Portland Basin. At 1.6 Ma, following a hiatus of ~0.8 m.y., similar lavas erupted a few kilometers to the north, after which volcanism became widely dispersed, compositionally variable, and more or less continuous, with an average recurrence interval of 15,000 yr.
    [Show full text]
  • Rare Earth Element Mineralogy, Geochemistry, and Preliminary Resource Assessment of the Khanneshin Carbonatite Complex, Helmand Province, Afghanistan
    Prepared in cooperation with the Task Force for Business and Stability Operations, under the auspices of the U.S. Department of Defense and the Afghanistan Geological Survey Rare Earth Element Mineralogy, Geochemistry, and Preliminary Resource Assessment of the Khanneshin Carbonatite Complex, Helmand Province, Afghanistan Robert D. Tucker, Harvey E. Belkin, Klaus J. Schulz, Stephen G. Peters, and Kim P. Buttleman Open-File Report 2011–1207 USGS Afghanistan Project Product No. 200 U.S. Department of the Interior U.S. Geological Survey U.S. Department of the Interior KEN SALAZAR, Secretary U.S. Geological Survey Marcia K. McNutt, Director U.S. Geological Survey, Reston, Virginia: 2011 For more information on the USGS—the Federal source for science about the Earth, its natural and living resources, natural hazards, and the environment—visit http://www.usgs.gov or call 1–888–ASK–USGS For an overview of USGS information products, including maps, imagery, and publications, visit http://www.usgs.gov/pubprod To order this and other USGS information products, visit http://store.usgs.gov Suggested citation: Tucker, R.D., Belkin, H.E., Schulz, K.J., Peters, S.G., and Buttleman, K.P., 2011, Rare earth element mineralogy, geochemistry, and preliminary resource assessment of the Khanneshin carbonatite complex, Helmand Province, Afghanistan: U.S. Geological Survey Open-File Report 2011–1207, 50 p. Any use of trade, product, or firm names is for descriptive purposes only and does not imply endorsement by the U.S. Government. Although this report is in the public domain, permission must be secured from the individual copyright owners to reproduce any copyrighted material contained within this report.
    [Show full text]
  • Pine Island Agglomerate
    February 2018 BACKGROUND INFORMATION PINE ISLAND AGGLOMERATE (part Block 1 Section 47 and part Block 16 Section 46, GREENWAY) At its meeting of 8 February 2018 the ACT Heritage Council decided that the Pine Island Agglomerate was not eligible for provisional registration. The information contained in this report was considered by the ACT Heritage Council in assessing the nomination for the Pine Island Agglomerate against the heritage significance criteria outlined in s10 of the Heritage Act 2004. HISTORY The Pine Island Agglomerate (the Agglomerate) is a localised rock formation but has many unusual features that make identifying its origin difficult. An agglomerate consists of rounded volcanic rocks, usually formed by liquid flying through the air, embedded in a volcanic ash matrix. However, the most likely explanation is that it is a volcanic mudslide, or a lahar, that occurred during the formation of the Laidlaw Volcanics; however it is very localised, not as well sorted as would be expected and has a larger variety of rock types than would be expected for a typical lahar (Finlayson, 2012). Finlayson (2012) in the Significant Geological Features in the Australian Capital Territory describes the Agglomerate: “The agglomerate exposed at this locality shows several puzzling features, and interpretation of its origin remains problematic at present. The rock occurs within the Laidlaw Volcanics, an ignimbrite unit noted for its extreme uniformity over tens of kilometres, and appears to represent a very localized deposit during a lull in the ignimbritic activity. A feature of the deposit is the variety of clasts present, which include chert, granite, quartzite, and volcanic porphyry in a medium-grained crystal and lithic matrix.
    [Show full text]
  • Petrography and Engineering Properties of Igneous Rocks
    ENGINEERil~G MONOGRAPHS No. I United States Department of the Interior BUREAU OF RECLAMATION PETROGRAPIIY AND ENGINEERING· PROPER11ES OF IGNEOUS ROCKS hy Rit~bard C. 1\lielenz Denver, Colorado October 1948 95 cents (R.evised September 1961) United States Department of the Interior STEWART L. UDALL, Secretacy Bureau of Reclamation FLOYD E. DOMINY, Commissioner G~T BLOODGOOD, Assistant Commissioner and Chief Engineer Engineering Monograph No. 1 PETROGRAPHY AND ENGINEERING PROPERTIRES ·OF IGNEOUS RO<;:KS by Richard C. Mielenz Revised 1959. by William Y. Holland Head. Petrographic Laboratory Section Chemical Engineering Laboratory Branch Commissioner's Office. Denver Technical Infortnation Branch Denver Federal Center Denver, Colorado ENGINEERING MONOGRAPHS are published in limited editions for the technical staff of the Bureau of Reclamation and interested technical circles in Government and private agencies. Their purpose is to record devel­ opments, innovations, .and progress in the engineering and scientific techniques and practices that are employed in the planning, design, construction, and operation of Rec­ lamation structures and equipment. Copies 'may be obtained from the Bureau of Recla- · mation, Denver Federal Center, Denver, Colon.do, and Washington, D. C. Excavation and concreting of altered zones in rhyolite dike in the spillway foundation. Davis Damsite. Arizona-Nevada. Fl'ontispiece CONTENTS Page Introduction . 1 General Basis of Classification of Rocks . 1 Relation of the Petrographic Character to the Engineering Properties of Rocks . 3 Engineering J?roperties of Igneous Rocks ................................ :. 4 Plutonic Rocks . 4 Hypabyssal Rocks . 6 Volcanic Rocks..... 7 Application of Petrography to Engineering Problems of the Bureau of Reclamation . 8 A Mineralogic and Textural Classification of Igneous Rocks .
    [Show full text]