AS MAPPING.

Slides:

Advertisements

Similar presentations

GEOLOGIC MAPPING 2014 EVENT OVERVIEW.

Advertisements

Ways to tell the age of a rock

Relative Dating : Which Came First?

Unconformities and Faults

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

Use answer key to make correction to p. 2 in binder

The relative age of rocks and geological events.

Unconformity. It is one of the most common geological feature found in rocks or in succession. It is different then all other geological structures viz.

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

Tis a Puzzlement.... Work with your partner to answer the following questions. Use these two trash pits to explain relative age. What can you infer about.

Principles of Relative Dating

LESSON 2 THE RELATIVE AGE OF ROCKS

 Uniformitarianism- Principle that states that the same geological process shaping the Earth today have been at work throughout Earth’s history.  Examples:

1 Lab 08 ONLINE LESSON. 2 If viewing this lesson in Powerpoint Use down or up arrows to navigate.

Supplemental Review and Exercises

Physical Geology Chapter 6 The Rock Record. Uniformitarianism Is a theory that rejects the idea that catastrophic forces were responsible for the current.

GEOLOGIC PRINCIPLES & RELATIVE DATING. HOW OLD IS THE EARTH? The Earth is about 4.6 billion years old Much of its history is recorded in the rocks Observations.

Exercise set 3: Basic cross sections

Aim: How do Scientists Read Rocks?

Geologic History

WELCOME TO CLASS. Agenda TODAY Sequencing Time Rock Record Notes Relative Age activity Hand back tests NEXT TIME Absolute age lab Geologic Time QUIZ.

Lab evaluations Go to Acadia Central Log in Click on Online Registration Click on Information.

Rock Deformation.

UNIT 5: GEOLOGIC HISTORY. AT THE END OF THIS UNIT YOU WILL BE ABLE TO  Calculate the absolute age of a substance based on its decay rate  Correlate.

Geology Review Game Ready your Mind!. Your teams are your table groups.

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

Interpreting Earth’s Rocks to Determine Its Past History.

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

Ch.6 Earth’s History. Who’s got the TIME? RELATIVE: order/sequence known, but not the actual date of occurrence. “Time Line” ABSOLUTE: actual date determined.

Calving Glacier 3VTgIPoGU?rel=0.

Interpreting Earth’s Rocks to Determine Its Past History.

Dating Rocks Ways to tell the age of a rock. What are relative and absolute Locations?

Ch. 23.6: Interpreting the Rock Record

Stratigraphy Stratigraphy is the branch of geology that deals with the arrangement of rocks in layers.

The Geologist as Detective Chapter 6 : Interpreting Geologic History.

1 Earth’ s History Unit 6. 2 Vocabulary List 1.Relative Dating 2.Absolute Dating 3.Superposition 4.Cross-cutting relationships 5.Uniformitarianism 6.Original.

GEOLOGICAL TIME. GEOLOGY NEEDS A TIME SCALE An investigation of the history of Earth Understanding how features of landscape developed and formed Reconstructing.

4.2 The Relative Age Of Rocks

DO NOW! 1. List and define the four types of fossils 2. What is the most common fossil type? 3. What 2 conditions are best for fossils to form? 4. Where.

Geologic Time. Rocks Record Earth History Rocks record geological events and changing life forms of the past. We have learned that Earth is much older.

The Rock Record Section 1 Section 1: Determining Relative Age Preview Objectives Uniformitarianism Relative Age Law of Superposition Principle of Original.

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

Paleontology Notes Relative Age is the “age” of a rock or strata compared to the ages of other rocks or strata.

Rock Relationships and Geological Histories You must have the presentation on Slide Show mode. On opening the presentation, you may be asked to enable.

Earth’s History Introduction: The earth is about 4.6 billion years old. Much of its history is recorded in the rock. Observations of fossils, rock types,

Aim: How do Scientists Read Rocks? Do Now: In your notes, answer the following question. Of the three types of rocks we have discussed (Igneous, Sedimentary.

The Rock and Fossil Record II. Relative Dating: Which Came First?

Relative Dating: Which Came First?

Geologic time Relative dating

Earth History- Table of Contents

Aim: How do Scientists Read Rocks?

Eric H Christiansen.

Discovering Earth’s History

Earth History- Table of Contents

Ketobe Knob, UT.

Complete the “Who Dun It” activity at your seat. Be prepared to

Relative age dating Earth is very old (4.6 billion years old) and has changed over geologic time The rock record provides evidence of geological events.

Look at the block diagram below.

Relative Dating Notes.

Unit 2: Relative Dating - Part 2

Some Basic Stratigraphic Principles

Modification of Rocks by Folding and Fracturing

The History of Earth Relative Dating Absolute Dating

DO NOW Pick up notes and Review #11. Turn IN Review #10.

The History of Earth Relative Dating Absolute Dating

Lab evaluations Go to Acadia Central

Old Red Sandstone formation, St. Annes Whales

Aim: How do Scientists read Rocks?

Earth History- Table of Contents

Relative Dating Notes.

Presentation transcript:

AS MAPPING

You will be given a map which shows some simple geological structures and features to interpret. There will also be some questions which relate to the map and to the rock, mineral and fossil specimens.

The map will have a key, a scale and a north arrow.

The key will include the Rock Units shown on the map The key will include the Rock Units shown on the map. Sometimes you are told what type of rocks each rock unit represents but not always. It is a good idea to write the letters of each rock unit on the map before you start using it. The key also tells you which rock units have a specimen available to study.

What type of folds are these What type of folds are these? What is the trend and the symmetry of these folds? Folds A B

A B Folds There are two folds on this map. What type of folds are they? What is the trend and the symmetry of these folds?

Unconformities mark times when erosion is dominant and no sediments are deposited. They mark a break in deposition because of uplift and mountain building. The rocks above overlay the rocks below UNCONFORMABLY and are often very different in dip and strike. Unconformities cut across other beds.

Give the geological history of this map. What type of fold is this? What is the trend and the symmetry of this fold? Give the geological history of this map. Folds D C B A

Locate a fold and an unconformity on this map. Describe them both fully. Give the geological history of this area. Unconformities A B C D

A B Unconformities Where are the unconformities on these maps? How can you be sure that they are unconformities?

Locate two folds and an unconformity on this map Locate two folds and an unconformity on this map. Describe them both fully. Give the geological history of this area. Unconformities D A B C

Locate a fold and an unconformity on this map. Describe them both fully.

B A What type of igneous intrusions are shown on this map? What rocks could A and B be? Igneous intrusions B A

If faults are shown by straight lines then they are vertical If faults are shown by straight lines then they are vertical. If faults have a sinuous outcrop then they are at an angle to the horizontal and are probably reverse or thrust faults. What type of faults are these? What is the geological history of this area? B Faults F2 A C E D

What type of fault is F2? How do you know? Why does it appear to be in two sections? Faults granite

Faults The youngest rocks are always on the downthrow side of a fault. You need to know how old each rock is to find out the downthrow.

Faults Strike-slip faults are vertical but the movement on them is lateral (sideways). If the far side moves to the right the sense of movement is dextral, if it moves to the left the movement is called sinistral. Which way has this strike-slip fault moved?

What types of faults are F1 and F2? How can you tell? Which one occurred first? How do you know? What is the geological history of this area? E Faults D A B C

Faults F2 What types of faults are F1 and F2? Which occurred first? How do you know?

Which fault F1 or F2 is not vertical. How do you know Which fault F1 or F2 is not vertical? How do you know? Which fault F1 or F2 came first? How do you know? What is the geological history of this area? A B C D E

Answer the exam question about locality 1 on the map above.

A A Using evidence from Map 2, give one reason why this is a dyke rather than a sill.

What map evidence would you need to know to convince you that the feature formed by Rock B was a sill? C C Sills B

Graphic logs Asymmetrical ripples Cross bedding Give the evidence from the graphic log that shows that these rocks were laid down in a fluvial environment. Erosional base

Complete the log using the descriptions contained in Table 2. Graphic logs

Complete this table about F2.

Has the student got this geological history right?

A student identified this fossil as being Fossil A. Was this correct? Fossil evaluation

Fold wavelengths and amplitudes

Evaluation of fold axes Are these statements true? the fold trends are NS the folds are symmetrical the fold wavelength is 200m. Evaluation of fold axes

A What is the geological history of this area? Geological history D B G F E C

State three pieces of evidence, either from Map 3 or your fieldwork or knowledge, which confirm the presence of an unconformity. Draw and label on Map 3 the axial planes of two folds to the east of Fault F2. Questions

Rock unit B was deposited in tropical, shallow seas Rock unit B was deposited in tropical, shallow seas. What evidence from the photo and the graphic log would confirm this statement?

THE END