Anderson’s theory of faulting

Slides:

Advertisements

Similar presentations

Brittle deformation II

Advertisements

FAULTS AND FAULTING Dr. Masdouq Al-Taj

Stress and Deformation: Part II (D&R, ; ) 1. Anderson's Theory of Faulting 2. Rheology (mechanical behavior of rocks) - Elastic: Hooke's.

Chapter 9 – FOLDS, FAULTS & GEOLOGIC MAPS

Stress and Deformation: Part I (D&R, ; ) The goal for today is to explore the stress conditions under which rocks fail (e.g., fracture),

Interactive map.

GEOLOGIC STRUCTURES “Architecture of bedrock” Structural Geology- –shapes, –arrangement, –interrelationships of bedrock –units & forces that cause them.

Mountain Building And Fault types. Faults What is a fault? What causes faults? What are the three types of stresses? A fault is a fracture in the Earth’s.

Preexisting faults and faults that should not exist: Effects of mechanical anisotropy on different scales? Jonas Kley 1 Alexander Malz 2 1 Geoscience Center.

Ch – Forces Within Earth Essential Questions

Section 1: Forces in Earth’s Crust

Chapter 20 Geologic structures.

Lecture-11 1 Lecture #11- Faults and Faulting. Lecture-11 2 Faults Bound the Major Plates.

OF ROCKS [L17 P /IP-B] DEFORMATION OF ROCKS [L17 P /IP-B]

Today’s list____________ Ch15: Rock Deformation

Announcements This week's lab: 1-3 PM with Andrew McCarthy. Please come prepared with specific questions. There will be no lecture this Wednesday! Please.

Dynamic Earth Class February 2005.

Announcements Field trip this Saturday to Collosal Cave area 7:30 AM at loading dock. We will map some really cool stuff! Please review map symbols and.

Announcements Midterm next Monday! Midterm review during lab this week Extra credit opportunities: (1) This Thurs. 4 pm, Rm. Haury Bldg. Rm 216, "The role.

Rock Deformation and Geologic Structures

Lab 3 – Structural Geology and Earthquakes

Types of Metamorphism Regional metamorphism

QUIZ 1.What are Earthquakes? 2._____ is the deformation of a material caused by stress. 3.Describe tension stress. 4.Faulting causes rock to _________.

Rock Deformation Chapter 11, Section 1.

Folds, Faults, and Geologic Maps

Geologic Structures Physical Geology, Chapter 15

 Stress: Force per unit area  Strain: Change in length/area/volume to original length/area/volume  Rocks are subjected to great forces- particularly.

Crustal Deformation Structural Geology

Earth History- Table of Contents RELATIVE vs. ABSOLUTE LAWS UNCONFORMITIES GEOLOGIC SECTIONS.

Lecture Outlines Physical Geology, 14/e Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. Plummer, Carlson &

Structural geology Geology 101, Fall Structural geology The study of the deformation and fabric of rocks in order to understand the tectonic forces.

SEISMOGRAPH THE SCIENCE WHICH STUDIES EARTHQUAKES IN DETAIL IS KNOWN AS SEISMOLOGY. SEISMOGRAPH AN INSTRUMENTSWHICH MEASURES THE INTENSITY OF EARTHQUAKES.

Faults and Folds Normal Fault In normal faulting, the hanging wall block moves down relative to the footwall block. The fault plane.

Unit 2: Tectonic Process Ms. Thind.   Rocks under pressure or tension fracture under strain  If movement takes place along a fracture a rift is formed.

Section 3 Theory of plate tectonics. Plate tectonics  The theory that the Earth’s lithosphere is divided into tectonic plates that move around on top.

1 SGES 1302 INTRODUCTION TO EARTH SYSTEM LECTURE 7: Geological Structures: Joints & Faults.

Integrating geologic maps with fault mechanics John Singleton, George Mason University NSF Cutting Edge Workshop 2012.

This is the trace of the strain tensor. In general the trace of the strain tensor gives area change in 2-D and volume change in 3-D The principal axes.

Types of Faults Strike Slip Fault: Two layers of rock are shifted horizontally or parallel to the fault plane.

This is an illustration of the Earth laid out flat and show- ing the major cracks (faults) (in the Earth’s crust. Each section of the Earth’s crust is.

Geologic Structure.

What is the Great Shake Out?

Chapter 19 - Earthquakes Forces within Earth.

Geology Failure Models

Brittle Deformation Remember that  is the angle between  3 and a plane.

STRUCTURAL GEOLOGY  PRIMARY & NON-TECTONIC STRUCTURES 1) PRINCIPLE OF ORIGINAL HORIZONTALITY (NICOLAS STENO ) – LAYERS OF SEDIMENTS ARE ORIGINALLY.

Mohr-Coulomb failure Goal: To understand relationship between stress, brittle failure, and frictional faulting and to use this relationship to predict.

Structure An Introduction to Deformation. Standards Describe the composition and structure of Earth’s materials.

Lecture Outlines Physical Geology, 12/e

Forces In Mountain Building

Folds, Faults & Geologic Maps

LEQ: What are the categories and types of faults, and what type of stress produce each? Key Terms: displacement, strike slip fault, dip slip fault,

Eric H Christiansen.

Forces In Mountain Building

I. Basic Techniques in Structural Geology

Modification of Rocks by Folding and Fracturing

Layer Thickness and Map Width

Earth’s Materials and Processes-Part 10 Mountain Building and Faults

Earthquakes EARTHQUAKE 101.

Chapter 11.1 Rock Deformation.

Tectonic Forces and Geologic Structures

Fractures, Faults, & Friction

Title: 19.1 Forces Within Earth Page #: Date: 6/6/2013

Structure Contour Maps

Mountain construction and destruction

The Results of Stress.

MOUNTAIN BUILDING AND EVOLUTION OF CONTINENTS

Presentation transcript:

Anderson’s theory of faulting Goals: 1) To understand Anderson’s theory of faulting and its implications. 2) To outline some obvious exceptions to Anderson’s theory and some possible explanations for how these exceptions work.

Primary assumptions Surface of the earth is not confined, and not acted on by shear stresses. Also, tectonic plates move parallel with Earth’s surface (unknown in 1951) Homogenous rocks Coulomb behavior

Three possible stress combinations Hypothetically requires 2 of the 3 principal stresses to be parallel with the surface of the earth What are they? What kind of faults would you expect at each?

σ1 horizontal, σ3 vertical — reverse faults σ1 vertical, σ3 horizontal — normal faults σ1 horizontal, σ3 horizontal — strike-slip faults

Most rocks have an angle of internal friction ≈ 30° What dip angles does Anderson’s theory predict for σ1 horizontal, σ3 vertical — reverse faults? σ1 vertical, σ3 horizontal — normal faults? σ1 horizontal, σ3 horizontal — strike-slip faults?

Hypothetically Can you think of any exceptions?? Reverse faults: should form at ~30° dip Normal faults: should form at ~60° dip Strike-slip faults: should form at ~90° dip Can you think of any exceptions??

Common exceptions Thrust faults — mechanically unfavorable Low-angle normal faults — mechanically very unfavorable

Possible explanations Elevated pore fluid pressure Pre-existing weaknesses Rolling-hinge model for low-angle normal faults

1. Elevated pore fluid pressure (Pf)

High Pf can lower effective stress σ1 σn σ3eff σ3

This can activate slip on a low-angle fault σ3eff σ1eff

However, if cohesive strength is sufficiently low... σ3eff σ1eff

Pore-fluid-pressure mechanism requires low σeff on fault, but high σeff in surrounding rocks

It also doesn’t work well for low-angle normal faults σ3eff σ1eff

2. Pre-existing anisotropy Bedding Weak layer (salt, shale) Foliation

Donath (1961) produced shear fractures at very low angles to σ1 in anisotropic rock

3. Rolling-hinge model for low-angle normal faults

Cartoon cross section illustrating the rolling-hinge model

East Humboldt Range Ruby Mountains

Geologic map of the Ruby Mountains and East Humboldt Range

Cross section of a low-angle normal-fault system

Cartoon cross section illustrating the rolling-hinge model