Where do they come from?

Similar documents
C E C U R R I C U L U M I E N S C B L E I T A. i N T E G R A T I N G A R T S i n O N A T I D U C B L I P U. Student Learning Objectives:

Background See background information on Student Sheet, Station 4, page 9.7.

National Center for Atmospheric Research: Climate Discovery Teacher s Guide

Science in the Schoolyard Guide: FOSS California Solid Earth

Where do they come from?

Core Curriculum/Oklahoma AIMS Education Foundation

Grade Six: Earthquakes/Volcanoes Lesson 6.2: Fault Formations

Teacher Background. Impact! Down to Earth KS 3&4

Sediment Sleuths. Purpose: To identify the types of rocks and minerals found in various regions of the state.

GOING WITH THE FLOW (1 Hour)

How did they form? Exploring Meteorite Mysteries

Soil and Erosion. Spring Lesson 5 - Grade 5. Lesson Description. Learning Objectives. Materials and Preparation

Activity Title: It s Either Very Hot or Very Cold Up There!

Graphing Sea Ice Extent in the Arctic and Antarctic

LOOK OUT BELOW! (1 Hour)

7.5. Weathering Breaks Down Rocks

C E C U R R I C U L U M I E N S C B L E I T A. i N T E G R A T I N G A R T S i n O N A T I D U C B L I P U. Student Learning Objectives:

EROSION RATES (1 Hour)

Lesson 2 The Inner Planets

Biosphere. All living things, plants, animals, (even you!) are part of the zone of the earth called the biosphere.

I. Introduction: II. Background:

What are they? Exploring Meteorite Mysteries

In this activity, students experiment with sand and hair dryers to observe how wind, sand, and barriers interact to form sand dunes.

Antarctica. The Frozen Continent: Earth Science. by Laura Crawford. Scott Foresman Reading Street 3.2.1

Light Up Your World Adapted from Reflecting on Reflectivity,

What Can Craters Tell Us About a Planet?

Lab Activity: Deposition

Jell-O Rocks. Science Concept: Objectives: GLEs Addressed: Vocabulary: Materials: Most rocks are made of different substances.

Unit 1 Science Models & Graphing

Sunlight and Temperature

Mechanical Weathering

5 th Grade Lesson Plan: Matter and Chemical Reactions

You Might Also Like. Thanks. Connect

Moon. Grade Level: 1-3. pages 1 2 pages 3 4 pages 5 page 6 page 7 page 8 9

PROCESSES THAT SHAPE EARTH (4.ES.NGSS)

Physical Science Review Sheet Matter & Physical Properties

Teacher Lesson 4: Are Craters Always Round?

SAND ANALYSIS EXERCISE

Problem How can I find and mine valuable resources from a simulated moon surface?

4th Grade. Slide 1 / 101. Slide 2 / 101. Slide 3 / 101. Earth Systems. Earth Systems Earth's Systems. Mechanical Weathering

1 Shoreline Erosion and Deposition

Core Curriculum/Oklahoma AIMS Education Foundation

Rockin Roots. Weathering causes rocks to break down. Acid rain, roots, freezing and thawing of water causes weathering in rocks.

Alliance Created State Giant Traveling Map Lesson

SOIL SHAKE-UP (MODIFIED FOR ADEED)

GEOLOGIST S NOTEBOOK THREE ROCKS. Pre-Test/Anticipation Guide

Oil and Natural Gas in Arkansas Fossil Fuel Resources from the Natural State

Data Sheet for Task 1: Mixing It Up!

Directed Reading. Section: Volcanic Eruptions. light in color is called a. felsic. b. oceanic. c. mantle. d. mafic. dark in color is called

SEA ICE AND GLOBAL WARMING

What effect do they have?

This Rocks! Author: Sara Kobilka Institute for Chemical Education and Nanoscale Science and Engineering Center University of Wisconsin-Madison

Lesson 1 Matter and Its Properties

Teachersʼ Guide. Creating Craters. Down to Earth KS3

Temperature Changes OBJECTIVES PREPARATION SCHEDULE MATERIALS. The students. For each student. For each team of two. For the class

Earth s Ocean Waters

Newton s Laws of Motion Discovery

Weather Watchers Part II: Mini-Meteorologists

sort examples of weathering into categories of biological, chemical, and physical;

Integrated Curriculum and Instruction Design: Inquiry-Based Learning Authors: Tomi Diefenbach & Leslie Harder Title: Solar System Grade Level: 3

Stars Above, Earth Below By Tyler Nordgren Laboratory Exercise for Chapter 7

Replica Rocks - Teacher Notes

Chapter 3 Erosion and Deposition. The Big Question:

CLASSROOM NEWS Week of December 5, 2016! jmccool3rdgrade.weebly.com! (302)

Bell Ringer. Are soil and dirt the same material? In your explanation be sure to talk about plants.

Earth s Dynamic Surface

LASER TEAM ANTI-BULLYING PROGRAM STUDENT WORKSHEET MASTERS AND ANSWER KEYS

Norwood Science Center. Geology Grade 4

Mixtures, Solutions, and Suspensions

Erosion. changing landforms. Purpose. Process Skills. Background. Time 1 1 ½ hours Grouping Pairs, small groups, or class.

Mixtures. Part 2 Add 50 ml of water (one full syringe) to each cup. Stir and observe. Write your observations on the opposite page.

A) usually less B) dark colored and rough D) light colored with a smooth surface A) transparency of the atmosphere D) rough, black surface

Using Geography to Plan Civil War Campsites

You Might Also Like. I look forward helping you focus your instruction while saving tons of time. Kesler Science Station Lab Activities 40%+ Savings!

INSTRUCTIONAL PLANNING GUIDE FOR CHARACTERISTICS OF THE EARTH, MOON, AND SUN

Tips for Success on a Test

What's Up, Earth? Header Insert Image 1 here, right justified to wrap. Grade Level. 3rd. Time Required: 60 minutes

STUDENT NAME DATE ID GRADE 5 SCIENCE

3 Organizing Data. What is scientific notation? How are precision and accuracy different? How do scientists use graphs to show data?

Thanks. You Might Also Like. I look forward helping you focus your instruction and save time prepping.

Classify Rock (rock1)

Science & Literacy Activity GRADES 3-5

Meteoroids & Craters

5th Grade Science Syllabus and Classroom Expectations

Unit 2. Phases of Matter and Density

Lesson 5. Weathering Competition. Summary. Suggested Timeline. Materials. Objective. Teacher Background Knowledge. Page 1 of 6

SECOND GRADE 1 WEEK LESSON PLANS AND ACTIVITIES

Grade 5 Hands on Science Weathering, Erosion and Deposition

College of the Canyons Biotechnology Program

SU230R Grades 4-8. Hayes FAST FACTS & DAZZLING DATA OUR SOLAR SYSTEM

MAPPING MARS TEACHER PAGE

Performance script for sixth graders By Thomas Kuo and Kimberly Kline LEAPS Fellows, University of California, Santa Barbara

This nonfiction book

THE SUN, THE MOON AND OUR SOLAR SYSTEM TEACHER NOTES TO SHARE WITH STUDENTS

Where is Earth s Water?

Title of Lesson. Understanding Sand

CURRICULUM TR AILING ICE AGE M YST ERI E S

Follow the instructions to determine if your sample is metamorphic, sedimentary or igneous rock.

Scientists named the space rock NT7 and clocked its speed at 7 miles per second. The scientists thought the asteroid was heading straight for Earth!

STATES OF MATTER NOTES..

Transcription:

Exploring Meteorite Mysteries Lesson 3 Searching for Meteorites Objectives Students will: perform a demonstration of meteorite impacts with water balloons. assess various terrains for meteorite recovery using geography skills. attempt to recover simulated meteorite fragments. make experimental predictions. graph experimental results and draw conclusions. Background Finding meteorites is quite difficult because most meteorites look like Earth rocks to the casual or untrained eye. Even to the trained eye, recognizing meteorites can be difficult. In many cases meteorites break apart into many fragments as they pass through the atmosphere or impact the Earth. These smaller fragments are harder to find than one large meteorite. Meteorites are rarely found in forests or fields, where they become lost or buried among the plants. In rocky areas, meteorites are hard to find because they tend to be dull black, gray or white, and do not stand out among the much more common Earth rocks (see Meteorite Sample Disk if available). Iron meteorites are the exception. There are few natural sources of metal except meteorites. Old iron implements can be (and often are) mistaken for meteorites. In many cases, a chemical analysis is required to distinguish a meteorite from an Earth rock. Where do they come from? About This Lesson Water balloons filled with flour and pebbles help students model the distribution of materials after meteorite impacts. The flour simulates the ejected crater material and the pebbles represent the meteorite fragments. Students will use the model to draw conclusions about where it would be easiest to find meteorites. Vocabulary meteorite, ejecta, terrain, velocity, impact In their experiments, students will likely discover that good places to retrieve meteorites are surfaces that have no similar rocks, are very flat, have a contrasting background, and do not have thick vegetation. These conditions are best met on Earth by the polar ice cap in Antarctica, where in fact, thousands of meteorites have been found since 1969. Lots of meteorites are also found in deserts, especially in the Sahara and in southern Australia, where there are flat areas with few other rocks. NASA EG-1997-08-104-HQ Lesson 3 Searching for Meteorites 3.1

Materials Per Student Student Procedure and Data Table (pgs. 3.3-3.5) 1 balloon (round balloons work best) 0.1 liter flour (1/2 cup) 10 to 20 small pebbles (colored aquarium rocks work well) graph paper Per Group or Classroom water faucet to fill balloon funnel (one per group) measuring cup thin stick or skewer Procedure Advanced Preparation 1. Assemble materials. 2. Practice filling balloon with flour and check for appropriate locations to conduct impacts. Classroom Procedure 1. Distribute Student Procedure and Data Table. 2. Discuss background and intent for activity (why and how). 3. Look at (or discuss) selected impact sites prior to predicting on Student Procedure. 4. Have students collect materials. 5. Follow Student Procedure. 6. Discuss results and lead to conclusions that Antarctica and deserts are likely the easiest places to find meteorites. Extensions 1. Vary the exercise by using a variety of materials, chart all data, and rewrite the activity, making it more effective. 2. Dramatize the impact and scatter pattern of pebbles, using students as pebbles and doing the dramatization in slow motion. 3. On a world map have students predict where meteorites might easily be found. 4. Lesson 18 could be used to extend the Antarctic meteorite team information. 5. Show Antarctic slides (available from NASA, see page iv). 3.2 Lesson 3 Searching for Meteorites NASA EG-1997-08-104-HQ

Lesson 3 Searching for Meteorites Student Procedure Materials Per Student Student Procedure and Data Table 1 balloon 0.1 liter flour (1/2 cup) 10 to 20 small pebbles graph paper Per Group or Classroom water faucet funnel measuring cup thin stick or skewer Procedure Designate Groups This activity is designed to be done in groups of 3-4 students. Although each student launches (throws) a balloon filled with water and pebbles, students should work as a group to choose areas, make predictions, record observations, and draw conclusions. Designate Target Areas Working with your teacher, find 3-4 locations of various surfaces where balloons filled with water and pebbles can be exploded. Surfaces commonly found at a school site are concrete pavement, long jump pit or other sand pit, grassy area, gravel, pebble, or shell surface, asphalt pavement, snow, ice, and water. Be sure to get permission to use all areas. Classroom Procedure 1. Gather all equipment. 2. Choose or assign terrain targets for each student. 3. Record information on Data Table. 4. Make predictions and record on Data Table. NASA EG-1997-08-104-HQ Lesson 3 Searching for Meteorites 3.3

5. Place a funnel in the neck of a balloon. Fill balloon with approximately 0.1 liter (1/2 cup) of flour. Flour tends to pack, so it should be poured into the funnel slowly. A thin stick may be used to keep the flour flowing, but do not puncture the balloon. 6. Add pebbles one at a time, noting number of pebbles and color. 7. Fill balloon 3/4 full with water. Do not shake the balloon. Be sure to tie the balloon securely. This step must be done just before going outside to launch the balloons. 8. Launch balloons one at a time in designated areas. You may throw the balloon at an angle, lob them or throw them straight up so that they impact vertically. Remember to work as a group. Record observations at your launch site quickly then move to the next launch. When the group launches are complete, individuals return to their impact site to finish the sketch of their scatter pattern. 9. Clean up all balloon fragments and leave impact areas as clean as possible. 3.4 Lesson 3 Searching for Meteorites NASA EG-1997-08-104-HQ

Searching for Meteorites: Data Table Name: Date: Other Team members: Individual Launch Information Balloon Filling pebbles (note number and color) water volume (estimate) flour volume predict number and colors of pebbles that you will recover Launch Site Description (note terrain, estimate wind direction, and wind speed) Launch Specifics impact angle (estimate) impact direction impact velocity (fast-slow) sketch impact site in the space at right number(s) and colors of pebbles recovered Team Launch Data list different terrains below pebbles pebbles pebbles explain other variables (predict if you think it will be # launched # recovered % recovered (wind or height, etc.) easy or hard to find the pebbles) and colors and colors 2 red, 1 blue, 2 red, 1 blue, example: ice easy 8 6 75% building blocked wind 5 green 3 green NASA EG-1997-08-104-HQ Lesson 3 Searching for Meteorites 3.5

Graph Make a graph of the percentage of pebbles recovered from each impact surface. Note how the data compares to your predictions. Include data from different colors of pebbles if available. Questions Based on your data, which surface was the easiest for pebble recovery? Why? Did this match your predictions? What kind of land surface might be most productive for searching for meteorites? Why? How is the scatter pattern affected: by the ground surface? by the angle of impact? How might a scientist use this type of information to help locate meteorites? 3.6 Lesson 3 Searching for Meteorites NASA EG-1997-08-104-HQ

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback