DOCSLIB.ORG

Earthquakes It Is Estimated That There Are 500,000 Detectable Earthquakes in the World Each Year

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Earthquakes It Is Estimated That There Are 500,000 Detectable Earthquakes in the World Each Year Kobe, Japan 1995 – 5000 deaths Earthquakes It is estimated that there are 500,000 detectable earthquakes in the world each year. 100,000 of those can be felt, and 100 of them cause damage. The world's deadliest recorded earthquake occurred in 1557 in central China. It struck a region where most people lived in caves carved from soft rock. These dwellings collapsed during the earthqua ke, killing an es tima te d 830,000 people. In 1976 another deadly earthquake struck in Tangshan, China, where more than 250,000 people were killed. Earthquake epicenters in the U.S. 1 Seismic risk map for the U.S. Colors on this map show the level of horizontal shaking that have a 1-in-10 chance of being exceeded in a 50- year period. Shaking is expressed as a percentage of g (g is the acceleration of a falling object due to gravity). Turkey, August 17, 1999…in 40 seconds $20 billion in losses – 10% of Gross National Product Earthquakes happen every day, every hour somewhere in the world. Listening Team – Turkey, 1999 63,000 damaged buildings, 18,000 deaths, 50,000 injuries, 120,000 families without housing 2 Hawaii Island seismicity, 2000 95% of seismicity in Hawaii is due to volcanism – magma movement. Other 5% is due to tectonic forces on the seafloor Plate Tectonic framework for earthquakes Convergent, Divergent and Transform Boundaries 3 Convergent Boundary Divergent Boundary Earthquakes and Plate Margins Circum-Pacific seismic belt – 81% of worlds largest quakes Alpide Belt – 17% of largest quakes Mid-Atlantic Ridge 4 Elastic rebound Locating an earthquake as a cause of Energy is first released at focus, as slippage. This exerts strain along the fault, producing more earthquakes slippage elsewhere – this propagates as energy Elastic Rebound – 1. Slow storage of elastic energy over time (deformation) 2. Forces holding rocks together are overcome (displacement by elastic rebound) Foreshocks – build up of strain Aftershocks – Continued strain release Landforms – scarps, linear features diverted Two types of wave groups generated – Benioff Zone beneath the Tonga Trench Surface waves (Long Waves) Travel along outer layer of crust at the surface causing ground roll like a water wave and lateral shifting…travel slowly and generate the most damage Earthquake foci define the subducting Body waves (two types) slab. Primary waves (P) – compress and pull (dilate) rocks in the direction of movement, involves changing the volume and shape of material….solids, liquids and gases resist compression and will spring back. Thus they propagate the waves forward. P waves travel through all types of matter Fastest wave Secondary waves (S) – motion is 90 degrees to direction of propagation (up and down), involves only changing the shape of transmitting media…fluid and gas do not resist shape change hence they will not spring back and will not transmit the wave forward. S waves travel only through solids. Second fastest wave 5 Seismic body waves Recording earthquakes P Wave - all types of matter, fastest S Wave – solids only, second fastest Typical Seismograph Three seismographs each plot a circle record of the travel distance calculated by the S-P delay…where three circles intersect is the epicenter Average traveltravel--timetime curves Delay between arrival of S and P waves is proportional to the distance traveled by the waves 6 Refraction and reflection of seismic body waves Increased density allows wave to travel faster…causing slow refraction (bending) Refraction also happens suddenly when wave crosses density front. Waves also reflect off density interfaces. Wave front Wave ray Seismic shadow zones - Measuring Earths Interior P-wave refraction creates a shadow zone S-wave propagation creates a shadow zone P wave shadow zone S wave Network of epicenters around shadow zone Earth’s surface defines the interior zones 7 Changes in the seismic velocity of P and S waves mark discontinuities at 100 km (the low velocity zone – LVZ), 400 km (base of the upper mantle), 670 km (top of the lower mantle), 2900 km (top of the core), and 4800 km (inner core boundary). 400 discontinuity - broad depression of the surface (green and blue) under most parts of the Pacific and Indian Oceans. Large elevations in the surface (red and yellow) under continental regions such as Eurasia, North America, Australia, Antarctica and parts of Africa. In general 400 km discontinuity correlates well continents and ocean basins. 670 km discontinuity - very different structure from 400 km surface. Notable features: deep depression in western Pacific, Tonga, and South America. Basin depths 25 km from average position of the surface; consistent with effect of subduction in these regions. 2900 discontinuity - at core-mantle boundary reveals broad basin under Indian Ocean and eastern Eurasia; western Africa, southern Indian Ocean, Australia, and western and central Pacific have a high topography related to thermally buoyant regions on core surface 8 Richter Magnitude – Energy of seismic wave is a function of both amplitude (X) and duration (T). Table 13.3 – Frequency of Occurrence of Earthquakes since 1900 M = log X/T + Y (correction factor) Richter Magnitude Average Annually Descriptor Great 8 and higher 1 Major 7 - 7.9 18 Strong 6 - 6.9 120 Moderate 5 - 5.9 800 Light 4 - 4.9 6,200 (estimated) Minor 3 - 3.9 49,000 (estimated) Magnitude 2 - 3: about 1,000 per day Very Minor < 3.0 Magnitude 1 - 2: about 8,000 per day Table 13.2 Modified Mercalli Intensity Scale I. Not felt except by a very few under especially favorable conditions. II. Felt only by a few persons at rest, especially on upper floors of buildings. III. Felt quite noticeably by persons indoors, especially on upper floors of buildings. Many people do not recognize it as an earthquake. Standing motor cars may rock slightly. Vibrations similar to the passing of a truck. Duration estimated. IV. Felt indoors by many, outdoors by few during the day. At night, some awakened. Dishes, windows, doors disturbed; walls make cracking sound. Sensation like heavy truck striking building. Standing motor cars rocked noticeably. V. Felt by nearly everyone; many awakened. Some dishes, windows broken. Unstable objects overturned. Pendulum clocks may stop. VI. Felt by all, many frightened. Some heavy furniture moved; a few instances of fallen plaster. Damage slight. VII. Damage negligible in buildings of good design and construction; slight to moderate in well-built ordinary structures; considerable damage in poorly built or badly designed structures; some chimneys broken. VIII. Damage slight in specially designed structures; considerable damage in ordinary substantial buildings with partial collapse. Damage great in poorly built structures. Fall of chimneys, factory stacks, columns, monuments, walls. Heavy furniture overturned. IX. Damage considerable in specially designed structures; well-designed frame structures thrown out of plumb. Damage great in substantial buildings, with partial collapse. Buildings shifted off foundations. X. Some well-built wooden structures destroyed; most masonry and frame structures destroyed with foundations. Rails bent. XI. Few, if any (masonry) structures remain standing. Bridges destroyed. Rails bent greatly. XII. Damage total. Lines of sight and level are distorted. Objects thrown into the air. 9 10.
Load more

Recommended publications
  • Geography) 2018
    IASbaba’s 60 Days Plan – Day 46 (Geography) 2018 Q.1) Consider the following statements. 1. A mid-oceanic ridge is composed of two chains of mountains separated by a large depression. 2. Mid-oceanic ridges are formed at convergent boundary of two plates. Which of the above statements is/are correct? a) 1 only b) 2 only c) Both 1 and 2 d) None Q.1) Solution (a) A mid-oceanic ridge is composed of two chains of mountains separated by a large depression. The mountain ranges can have peaks as high as 2,500 m and some even reach above the ocean’s surface. Running for a total length of 75,000 km, these ridges form the largest mountain systems on earth. These ridges are either broad, like a plateau, gently sloping or in the form of steep- sided narrow mountains. These oceanic ridge systems are of tectonic origin formed at divergent plate boundaries and provide evidence in support of the theory of Plate Tectonics. Do you know? A land bridge, in biogeography, is an isthmus or wider land connection between otherwise separate areas, over which animals and plants are able to cross and colonise new lands. A land bridge can be created by marine regression, in which sea levels fall, exposing shallow, previously submerged sections of continental shelf; or when new land is created by plate tectonics; or occasionally when the sea floor rises due to post-glacial rebound after an ice age. THINK! Straits Q.2) ‘Insular shelf’ means a) A continental shelf allocated to landlocked countries.
    [Show full text]
  • 2020 Technical Sessions
    1 2020 Technical Sessions Advances in Real-Time GNSS Data Analysis and Network Operations for Hazards Monitoring Advances in Seismic Imaging of Earth’s Mantle and Core and Implications for Convective Processes Advances in Seismic Interferometry: Theory, Computation and Applications Advances in Upper Crustal Geophysical Characterization Alpine-Himalayan Alpide Shallow Earthquakes and the Current and the Future Hazard Assessments Amphibious Seismic Studies of Plate Boundary Structure and Processes Applications and Technologies in Large-Scale Seismic Analysis Back to the Future: Innovative New Research with Legacy Seismic Data Crustal Stress and Strain and Implications for Fault Interaction and Slip Cryptic Faults: Assessing Seismic Hazard on Slow Slipping, Blind or Distributed Fault Systems Data Fusion and Uncertainty Quantification in Near-Surface Site Characterization Early Results from the 2020 M6.4 Indios, Puerto Rico Earthquake Sequence Earthquake Early Warning: Current Status and Latest Innovations Earthquake Source Parameters: Theory, Observations and Interpretations Environmental and Near Surface Seismology: From Glaciers and Rivers to Engineered Structures and Beyond Exploring Rupture Dynamics and Seismic Wave Propagation Along Complex Fault Systems Explosion Seismology Advances 2 Forthcoming Updates of the USGS NSHMs: Hawaii, Conterminous U.S. and Alaska From Aseismic Deformation to Seismic Transient Detection, Location and Characterization Full-Waveform Inversion: Recent Advances and Applications Innovative Seismo-Acoustic Applications
    [Show full text]
  • Draft IEE: Viet Nam: Water Sector Investment Program
    Initial Environmental Examination Project Number: 41456-033 March 2011 MFF 0054-VIE: Water Sector Investment Program – Tranche 2 This initial environmental examination is a document of the borrower. The views expressed herein do not necessarily represent those of ADB’s Board of Directors, Management, or staff, and may be preliminary in nature. Your attention is directed to the “terms of use” section of this website. In preparing any country program or strategy, financing any project, or by making any designation of or reference to a particular territory or geographic area in this document, the Asian Development Bank does not intend to make any judgments as to the legal or other status of any territory or area. Rehabilitating and Upgrading Project of Haiphong Water Supply System – Stage II: Final Report - Draft Supplementary Appendix 19-a Initial Environmental Examination Construction of Kim Son Water Supply System AECOM Asia Company Ltd. Supplementary Appendix 19-a Rehabilitating and Upgrading Project of Haiphong Water Supply System – Stage II: Final Report - Draft Table of Contents Abbreviations, Weights and Measures, Currency Equivalent iii I. EXECUTIVE SUMMARY 1 A. Purpose of the Report 1 B. Rehabilitating & Upgrading Project of the Hai Phong Water Supply System - 1 Stage II C. Construction of Kim Son Water System 2 D. Summary of Impacts and Mitigation Measures 3 E. Information Disclosure, Consultation and Participation 4 F. Grievance Redress Mechanism 4 G. Environmental Management Plan 5 H. Conclusion 6 II. POLICY, LEGAL & ADMINISTRATIVE FRAMEWORK 7 A. Policy and Legal Framework 7 B. Assessment and Approval Requirements 8 III. DESCRIPTION OF THE SUBPROJECT 8 A.
    [Show full text]
  • Financial Management of Earthquake Risk
    Financial Management of Earthquake Risk Please cite this publication as: OECD (2018), Financial Management of Earthquake Risk, www.oecd.org/finance/Financial-Management-of-Earthquake-Risk.htm. This work is published under the responsibility of the Secretary-General of the OECD. The opinions expressed and arguments employed herein do not necessarily reflect the official views of the OECD or of the governments of its member countries or those of the European Union. This document and any map included herein are without prejudice to the status of or sovereignty over any territory, to the delimitation of international frontiers and boundaries and to the name of any territory, city or area. © OECD 2018 FOREWORD │ 5 Foreword Disasters present a broad range of human, social, financial, economic and environmental impacts, with potentially long-lasting, multi-generational effects. The financial management of these impacts is a key challenge for individuals, businesses and governments in developed and developing countries. The Financial Management of Earthquake Risk applies the lessons from the OECD’s analysis of disaster risk financing practices and the application of its guidance to the specific case of earthquakes. The report provides an overview of the approaches that economies facing various levels of earthquake risk and economic development have taken to managing the financial impacts of earthquakes. The OECD supports the development of strategies and the implementation of effective approaches for the financial management of natural and man-made disaster risks under the guidance of the OECD High-Level Advisory Board on Financial Management of Catastrophic Risks and the OECD Insurance and Private Pensions Committee.
    [Show full text]
  • 8. Magnitude-Frequency Relation O F Earthquakes and Its Bearing on Geotectonics by Setumi MIYAMURA Earthquake Research Institute
    No. 1] 27 8. Magnitude-Frequency Relation of Earthquakes and its Bearing on Geotectonics By Setumi MIYAMURA EarthquakeResearch Institute, University of Tokyo (Comm.by C. TsuBOI,M.J.A., Jan. 12, 1962) A formula log N= a+b (8-M) was introduced by B. Gutenberg and C. F. Richter'' for expressing the number N of earthquakes in relation to their magnitudes M. The coefficient a which represents the logarithm of the number of earthquakes having a magnitude 8±dM/2 depends on the extent of area and the length of time taken into account, but the other one b does not and is believed to be a physical constant related to the mechanical behaviour of the portion of the earth in which the earthquakes occur. The values of the coefficients a and b were numerically deter- mined by Gutenberg and Richter for shallow, intermediate and deep earthquakes for both the entire world and various selected regions. Although the value of b determined by Gutenberg and Richter ranges from 0.45 to 1.5 for various regions, they suspected it is more or less constant so that the rate of increase in frequency of earthquakes with decreasing magnitude does not differ much for all regions. They did not fail to point out, however, that in South America and Central Asia, earthquakes having very large magnitudes are dispro- portionately numerous, while in the Atlantic and Indian oceans, they are disproportionately rare. This study of Gutenberg and Richter has been followed by many similar ones, which were made for various other regions. Most of the authors who have made the studies seem to be inclined to support the view that the rate of increase in frequency of earthquakes with decreasing magnitude does not differ much from a region to another.
    [Show full text]
  • Carsten Hobohm Editor Endemism in Vascular Plants Endemism in Vascular Plants PLANT and VEGETATION
    Plant and Vegetation 9 Carsten Hobohm Editor Endemism in Vascular Plants Endemism in Vascular Plants PLANT AND VEGETATION Vo l u m e 9 Series Editor: M.J.A. Werger For further volumes: http://www.springer.com/series/7549 Carsten Hobohm Editor Endemism in Vascular Plants 123 Editor Carsten Hobohm Ecology and Environmental Education Working Group Interdisciplinary Institute of Environmental, Social and Human Studies University of Flensburg Flensburg Germany ISSN 1875-1318 ISSN 1875-1326 (electronic) ISBN 978-94-007-6912-0 ISBN 978-94-007-6913-7 (eBook) DOI 10.1007/978-94-007-6913-7 Springer Dordrecht Heidelberg New York London Library of Congress Control Number: 2013942502 © Springer Science+Business Media Dordrecht 2014 This work is subject to copyright. All rights are reserved by the Publisher, whether the whole or part of the material is concerned, specifically the rights of translation, reprinting, reuse of illustrations, recitation, broadcasting, reproduction on microfilms or in any other physical way, and transmission or information storage and retrieval, electronic adaptation, computer software, or by similar or dissimilar methodology now known or hereafter developed. Exempted from this legal reservation are brief excerpts in connection with reviews or scholarly analysis or material supplied specifically for the purpose of being entered and executed on a computer system, for exclusive use by the purchaser of the work. Duplication of this publication or parts thereof is permitted only under the provisions of the Copyright Law of the Publisher’s location, in its current version, and permission for use must always be obtained from Springer. Permissions for use may be obtained through RightsLink at the Copyright Clearance Center.
    [Show full text]
  • Uncorrected Transcript
    1 DISASTER-2013/05/10 THE BROOKINGS INSTITUTION MITIGATING NATURAL DISASTERS, PROMOTING DEVELOPMENT: THE SENDAI DIALOGUE AND DISASTER RISK MANAGEMENT IN ASIA Washington, D.C. Friday, May 10, 2013 ANDERSON COURT REPORTING 706 Duke Street, Suite 100 Alexandria, VA 22314 Phone (703) 519-7180 Fax (703) 519-7190 2 DISASTER-2013/05/10 PARTICIPANTS: Introduction: MIREYA SOLIS Senior Fellow and Philip Knight Chair in Japan Studies The Brookings Institution PANEL 1: LESSONS FROM 3/11 Moderator: JAMES GANNON Executive Director JCIE/USA Panelists: DANIEL ALDRICH Fulbright Research Professor, University of Tokyo Associate Professor, Purdue University LEO BOSNER Fellow International Institute of Global Resilience YOSHIAKI KAWATA Professor, Faculty of Safety Science Kansai University RANDY MARTIN Director for Partnership Development East Asia Mercy Corps NAOKI SHIRATSUCHI Director, National Disaster Management Division Japanese Red Cross Society LUNCH ADDRESS Moderator: ELIZABETH FERRIS Senior Fellow and Co-Director, Brookings-LSE Project on Internal Displacement The Brookings Institution Speaker: NANCY LINDBORG Assistant Administrator for Democracy, Conflict, and Humanitarian Assistance ANDERSON COURT REPORTING 706 Duke Street, Suite 100 Alexandria, VA 22314 Phone (703) 519-7180 Fax (703) 519-7190 3 DISASTER-2013/05/10 USAID PANEL 2: CHALLENGES OF DISASTER RISK MANAGEMENT IN ASIA AND THE TRANSFERABILITY OF JAPAN’S BEST PRACTICES Moderator: ELIZABETH FERRIS Senior Fellow and Co-Director, Brookings-LSE Project on Internal Displacement The Brookings
    [Show full text]
  • Seismic Body Wave Attenuation Tomography of the Australian Continent Annual Report 2005
    Seismic Body Wave Attenuation Tomography of the Australian Continent Agus Abdulah Research School of Earth Sciences The Australian National University Annual Report 2005 February 2006 Table of Contents Abstract.............................................................................................................................. 2 Chapter 1 .......................................................................................................................... 4 Introduction....................................................................................................................... 4 Chapter 2 ......................................................................................................................... 10 Australian Setting and Previous Seismic Studies of Australia ................................... 10 2.1 Australian Setting........................................................................................................ 10 2.1.1 The Australian Continent ..................................................................................... 10 2.1.2 Surrounding Regions ........................................................................................... 13 2.2 Previous seismic Tomography and Seismic Attenuation Studies of Australia........... 15 2.2.1 Tomography Studies of Australia ........................................................................ 16 2.2.2 Seismic Attenuation Studies of Australia ............................................................ 21 Chapter 3 ........................................................................................................................
    [Show full text]
  • Bukowska Janiszewska Mordw
    Potentials of Poland Introduction to Socio-Economic Geography of Poland for Foreigners Łódź 2012 citation: Rosińska-Bukowska M., Janiszewska A., Mordwa S. (eds), 2012, Potentials of Poland. Introduction to socio-economic geography of Poland for foreigners, Dep. of Spatial Economy and Spatial Planning, ISBN 978-83937758-1-1, doi: 11089/2690. Review Izabela Sołjan Editors Magdalena Rosińska-Bukowska Anna Janiszewska Stanisław Mordwa Managing editor Ewa Klima (If you have any comments to make about this title, please send them to: [email protected]) Text and graphic design by Karolina Dmochowska-Dudek Cover design by Karolina Dmochowska-Dudek Książka dostępna w Repozytorim Uniwersytetu Łódzkiego http://hdl.handle.net/11089/2690 ISBN: 978-83-937758-1-1 © Copyright by Department of Spatial Economy and Spatial Planning, University of Łódź, Łódź 2012 TABLE OF CONTENTS 1. INTRODUCTION ......................................................................................................... 9 (Editors) 2. POTENTIAL OF THE POLISH ENVIRONMENT ................................................. 10 (Sławomir Kobojek) 2.1. Location – area – spatial resources .............................................. 10 2.2. Resources of the Polish land – geological composition – minerals12 2.2.1. Geological structures in Poland – tectonic units ................... 12 2.2.2. The Quaternary and the Pleistocene – the Polish ice age ... 18 2.3. Diversity of geomorphological landscape – topographic relief of Poland ..........................................................................................
    [Show full text]
  • Tectonic Plates and Faults in Asia-Pacific OCHA Issuedn:O 4Rt Jha Anmuearriyc A2n0 1P0late Regional Office for Asia-Pacific
    Tectonic Plates and Faults in Asia-Pacific OCHA IssuedN:o 4rt Jha Anmuearriyc a2n0 1P0late Regional Office for Asia-Pacific Tectonic Plates and Fault Lines Eurasian Plate Legend Okhotsk The region is home to extremes in elevation and the world's most Depth (m) Elevation (m) active seismic and volcanic activity. Southwest of India, the Maldives Plate Below 5,000 250 MONGOLIA has a maximum height of just 230cm, while far to the north, the Amur Plate 5,000 500 Tibetan Plateau averages over 4,500m across its 2.5 million square 4,000 750 kilometres and is home to all 14 of the world's peaks above 8,000 3,000 1,000 DPR KOREA metres. The Himalaya were born 70 million years ago when the 2,000 1,500 JAMMU & KASHMIR Arabian Plate collided with the Eurasian plate. RO KOREA 1,000 2,000 Jammu AKSAI CHIN and CHINA JAPAN 500 2,500 Kashmir The Pacific Ring of Fire is a belt of oceanic trenches, island arcs, 100 3,000 volcanic mountain ranges and plate movements that encircles the basin Volcano 4,000 ARUNASHAL PRADESH Pacific Plate NEPAL of the Pacific Ocean. The ring is home to 90% of the world's Faultline 5,000 IRAN BHUTAN earthquakes - 95% if the Alpide belt is included, which runs through Plate boundary 7,500 BANGLADESH Java and Sumatra. The Ring of Fire is a direct consequence of plate Above 7,500 Taiwan tectonics and the movement and collisions of crustal plates, with the INDIA Province of China MYANMAR northwestward moving Pacific plate subducted beneath the Aleutian Country Naming Convention LAO PDR Philippine Islands arc in the north, along the Kamchatka peninsula and Japan in UN MEMBER STATE the west.
    [Show full text]
  • Where the Majority of the World's Earthquakes Occur
    Map showing world’s three major “belts” (major plate boundaries) where the majority of the world’s earthquakes occur. Mid-Atlantic Ridge Ring of Fire Alpide Belt Alpide Belt Visual Credit: USGS Earthquake Hazard and Emergency Management: Session 3 Distribution Visual 3.1 3-1 Seismicity of North America North American Plate Pacific Plate Figure Credit: USGS Earthquake Hazard and Emergency Management: Session 3 Distribution 3-2 Visual 3.2 Map Showing Seismicity in S. California Figure Credit: USGS Earthquake Hazard and Emergency Management: Session 3 Distribution 3-3 Visual 3.3 Northern California Seismicity • Seismicity relatively well understood Earthquake Hazard and Emergency Management: Session 3 Distribution 3-4 Visual 3.4 Figure Credit: USGS Pacific Northwest – Cascadia Subduction Zone Figure Credit: USGS Earthquake Hazard and Emergency Management: Session 3 Distribution 3-5 Visual 3.5 Idaho, Utah, Wyoming • Recurring events along Wasatch Figure Credit: USGS Earthquake Hazard and Emergency Management: Session 3 Distribution 3-6 Visual 3.6 Central US Seismic Zones Figure Credit: USGS Earthquake Hazard and Emergency Management: Session 3 Distribution 3-7 Visual 3.7 Reelfoot Rift Figure Credit: USGS Earthquake Hazard and Emergency Management: Session 3 Distribution 3-8 Visual 3.8 Charlevoix Seismic Zone Credit: Natural Resources Canada Earthquake Hazard and Emergency Management: Session 3 Distribution 3-9 Visual 3.9 Southeastern Seismicity • TN relatively active • 1886 event not explained • magnetic signature from NC to GA similar to
    [Show full text]
  • Plate Boundaries It Is Apparent That Most of What We Observe on The
    Plate Boundaries It is apparent that most of what we observe on the surface of the earth and at shallow depth is related in some way to plate tectonics. The beaches along the eastern margin of North America are the result of the weathering, erosion, and breakdown of a huge mountain range (the Appalachian Mountains) over the last 300 million years. The Appalachians were formed during the collision of continents to form a mega continent called Pangaea. The volcanic mountains that form the western margin of North America are the result of subduction of oceanic crust under continental crust. The subduction results in frictional heating and partial melting of material being dragged down into the mantle. Practically all of the major processes that occur on the surface of the earth are related to plate tectonics. Earthquakes, volcanism, and mountain building are three of the most spectacular earth processes related to tectonic activity, however many other processes like metamorphism, sedimentary rock formation, among others are related directly or indirectly to plate tectonics. There are three types of plate boundaries. They are divergent, convergent and oblique slip (transform). Each boundary type has its own characteristic geologic features and processes, by which it can be identified even millions of years after it has been active. It is clear that the area around the Appalachian Mountains was once a subduction zone even though it has not been active for the last 250 million years. Pacific Ring of Fire The Pacific Ring of Fire (or just The Ring of Fire) is an area where large numbers of earthquakes and volcanic eruptions occur in the basin of the Pacific Ocean.
    [Show full text]