Science Teachers: Apply to Pilot KQED’s New Engineering Curriculum

Are you a middle or high school science teacher looking for ways to integrate the NGSS engineering standards into your classroom? Join KQED Education this fall in piloting a new media-rich, NGSS-based engineering curriculum. Developed by KQED and a group of outstanding Bay Area science teachers, Engineering for Good is a two-week, project-based learning unit focused on developing solutions for negative impacts of plastics on the environment. Designed to fit into life, earth and physical science classes, and full of engaging videos of real-world engineering stories, the unit culminates with students producing videos about their own solutions. Student stories will be collected by KQED on a platform that encourages sharing, conversation and feedback in a way that further promotes student voice and agency, and the acquisition of 21st century skills.

Teachers participating in the pilot will be supported through a blended experience employing both in-person meetings and KQED’s new online professional learning platform. You will learn video production in order to scaffold the process with your students and receive guidance on classroom implementation of the Engineering for Good curriculum. In addition, you will receive a $750 stipend, and your feedback will assist in developing outstanding, free engineering resources for science teachers in California and beyond.

The Details

• The pilot will run August 2016 through January 2017
• After completion of the pilot, participants will receive a $750 stipend
• We encourage you to apply with one or more teachers from your school
• Open to Bay Area middle and high school science teachers

Requirements

• Attend an all-day kickoff meeting at KQED on Saturday, August 6, 2016
• Implement the Engineering for Good curriculum in the fall 2016 semester (10-day unit)
• Complete the “Storytelling with Video” course on KQED’s online professional learning platform (6 modules; 20 hours total)
• Actively participate in an online forum/community for pilot participants
• Share student work created as part of the Engineering for Good curriculum
• Provide feedback on the Engineering for Good curriculum and participate in an evaluation of the pilot
• Write an In the Classroom post to be shared on KQED’s website or online learning platform (this will also earn you the KQED “Storytelling with Video In the Classroom” badge)
• Attend an end-of-pilot meeting at KQED in January (date TBD)

Apply below by June 15, 2016.  Applicants will be notified by June 30, 2016.

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Are you a middle or high school science teacher looking for ways to integrate the NGSS engineering standards into your classroom? Join KQED Education this fall in piloting a new media-rich, NGSS-based engineering curriculum. Developed by KQED and a group of outstanding Bay Area science teachers, Engineering for Good is a two-week, project-based learning unit focused on developing solutions for negative impacts of plastics on the environment. Designed to fit into life, earth and physical science classes, and full of engaging videos of real-world engineering stories, the unit culminates with students producing videos about their own solutions. Student stories will be collected by KQED on a platform that encourages sharing, conversation and feedback in a way that further promotes student voice and agency, and the acquisition of 21st century skills.

Teachers participating in the pilot will be supported through a blended experience employing both in-person meetings and KQED’s new online professional learning platform. You will learn video production in order to scaffold the process with your students and receive guidance on classroom implementation of the Engineering for Good curriculum. In addition, you will receive a $750 stipend, and your feedback will assist in developing outstanding, free engineering resources for science teachers in California and beyond.

The Details

• The pilot will run August 2016 through January 2017
• After completion of the pilot, participants will receive a $750 stipend
• We encourage you to apply with one or more teachers from your school
• Open to Bay Area middle and high school science teachers

Requirements

• Attend an all-day kickoff meeting at KQED on Saturday, August 6, 2016
• Implement the Engineering for Good curriculum in the fall 2016 semester (10-day unit)
• Complete the “Storytelling with Video” course on KQED’s online professional learning platform (6 modules; 20 hours total)
• Actively participate in an online forum/community for pilot participants
• Share student work created as part of the Engineering for Good curriculum
• Provide feedback on the Engineering for Good curriculum and participate in an evaluation of the pilot
• Write an In the Classroom post to be shared on KQED’s website or online learning platform (this will also earn you the KQED “Storytelling with Video In the Classroom” badge)
• Attend an end-of-pilot meeting at KQED in January (date TBD)

Apply below by June 15, 2016.  Applicants will be notified by June 30, 2016.

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Should We Make Cities More Inviting to Wildlife?

This post is part of KQED’s Do Now U project. Do Now U is a weekly activity for students and the public to engage and respond to current issues using social media. Do Now U aims to build civic engagement and digital literacy for learners of all ages. This Read More …

Source:: DoNow Science

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This post is part of KQED’s Do Now U project. Do Now U is a weekly activity for students and the public to engage and respond to current issues using social media. Do Now U aims to build civic engagement and digital literacy for learners of all ages. This Read More …

Source:: DoNow Science

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Will Robots Replace Us At Work?

Should Animals Be Kept in Zoos?

Featured Media Resource: VIDEO: Zoo Conservation Raise Debate (CNN)
Hear opposing thoughts from a field biologist at the University of York and the President of the Born Free Foundation about keeping animals in zoos for conservation purposes.

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Do Now U

Do you Read More …

Source:: DoNow Science

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Featured Media Resource: VIDEO: Zoo Conservation Raise Debate (CNN)
Hear opposing thoughts from a field biologist at the University of York and the President of the Born Free Foundation about keeping animals in zoos for conservation purposes.

---

Do Now U

Do you Read More …

Source:: DoNow Science

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Should Teens Be Allowed to Buy E-Cigarettes?

Featured Media Resource [VIDEO]: “Are Electronic Cigarettes Safe?” (BBC News)
As e-cigarettes and vaping grow in popularity among teens, the U.S. Food and Drug Administration (FDA) has yet to regulate their distribution. Researchers are still determining the health risks associated with the popular product. In Read More …

Source:: DoNow Science

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Featured Media Resource [VIDEO]: “Are Electronic Cigarettes Safe?” (BBC News)
As e-cigarettes and vaping grow in popularity among teens, the U.S. Food and Drug Administration (FDA) has yet to regulate their distribution. Researchers are still determining the health risks associated with the popular product. In Read More …

Source:: DoNow Science

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Should the Federal Minimum Wage Be Increased?

Featured Media Resource: VIDEO: Do You Understand the Minimum Wage Debate? (Citizen Tools)
View a non-partisan explanation of the history and current status of the minimum wage debate.

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Do Now U

Do you think the federal minimum wage should be increased? #DoNowUWage

---

How to Do Now

To respond to the Do Now Read More …

Source:: DoNow Science

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Featured Media Resource: VIDEO: Do You Understand the Minimum Wage Debate? (Citizen Tools)
View a non-partisan explanation of the history and current status of the minimum wage debate.

---

Do Now U

Do you think the federal minimum wage should be increased? #DoNowUWage

---

How to Do Now

To respond to the Do Now Read More …

Source:: DoNow Science

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Educator Guide: Exploring Earthquakes

What are earthquakes? Get a new perspective on these powerful phenomena with our collection of videos and infographics co-produced with KQED, originally designed with middle and high school educators in mind. You and your students will learn why earthquakes happen, how they’ve shaped the Bay Area, and what you can do to prepare for the next one. We’ve included ideas for how to structure a sequence of learning tasks, but feel free to pick and choose!

Whether you want to use the Exploring Earthquakes resources with students or to polish your own content knowledge, the following guide provides ideas for how to get started.

1. The Earth’s Structure

Core, Mantle and Crust

Before learning about earthquakes, let’s look at the inside of our planet.

• View the video Inside the Earth: Exploring Earth’s Layers and consider the following questions:
  1. What are distinct characteristics of each layer?
  2. How is Earth’s surface impacted by its interior?
• Read more about the core, mantle and crust.

Plate Boundaries

Movement in narrow zones along plate boundaries causes most earthquakes. Most seismic activity occurs at three types of plate boundaries – convergent, divergent, and transform.

• Observe the three types of plate boundaries and note where they occur on Earth.
• Review the brief description of each boundary type.
• After watching the Plate Boundaries video, research and find specific examples of convergent, divergent, and transform boundaries.

Evidence of Earth’s Layers

During an earthquake, different types of seismic waves move through the Earth, traveling through solids or liquids differently. This helps scientists understand the properties and composition of the Earth’s layers – the core, mantle, and crust.

• Look at the Seismic Waves video and discuss with a friend how P and S waves travel differently through the Earth’s layers.

2. Plate Movement through Geologic Time

The Supercontinent Cycle

Today’s configuration of continents is dramatically different than it was in the past. Learn how previous supercontinents formed and then broke up again over hundreds of millions of years due to plate tectonics.

• Watch the Plate Tectonics: Shaping the Continents video to witness how Earth’s forces have shaped the continents from present day to millions of years ago. Choose a location to follow back in time and describe its path.
• Watch the Back in Time: 200 Million Years Ago to Present Day video on the Earthquake YouTube playlist. Pause the video two to three times while you are watching and reflect on how the land masses have changed over time.

Formation of the Atlantic Ocean

The breakup of Pangaea was fueled by the formation of the Atlantic Ocean as new crust was formed along the underwater ridge. By speeding up geologic time through computer simulations, we can witness the movement of the plates and the beginning of this great ocean.

• You are about to witness the formation of the Atlantic Ocean. Before watching, predict when the Atlantic began to form.
• After viewing this timelapse video from 200 Million Years to Present Day, describe what the Atlantic might look like in millions of years.

Evidence of Plate Tectonics

Some Evidence of Plate Tectonics comes from what we know about previous life on Earth. Scientists have found fossils of the same land-dwelling animal in Africa and South America. How did similar fossils come to be so far apart? Evidence of plate tectonics has also been gathered from clues left by glaciers and the shapes of coastlines. This has helped scientists to piece together the previous configuration of the continents. How is this possible?

• After viewing the Records in Rock graphic of fossil evidence, make a list of questions that you have about fossil records and the connection to plate tectonics.
• Similar fossils from South America and Africa are now separated by an ocean. What connections can you make between this video and the previous graphic? What new questions do you have?
• View this Remnants in Rock graphic of glacier evidence and discuss how it supports the idea of a past supercontinent.
• This Complementary Coasts graphic provides evidence of complementary coastlines along Africa and South America. Look at a world map and determine other coastlines that could fit together based on their shapes.

Plate Tectonics Shaped Human History

Plate tectonics played an important role in the history of ancient civilizations both by causing destructive events and opportunities for life to flourish.

• Watch the Plate Tectonics and Ancient Civilizations video and consider why early civilizations would spring up in tectonically active areas.

3. Earthquake 101

Anatomy of an Earthquake

Although the Earth’s surface is moving and changing through geologic time, we usually do not see it happening before our eyes, but we can experience it through earthquakes. As the plates move past each other, along fault zones, they sometimes get caught and pressure builds up. When the plates finally give and slip due to the increased pressure, energy is released as seismic waves, causing the ground to shake. This is an earthquake.

• Using the Anatomy of an Earthquake diagram, describe the relationship between the faults and the plates. How are the focus and the epicenter different?
• Design a demonstration or model using everyday materials showing how earthquakes occur (built-up strain and sudden energy release).

Fault Types

Basic fault types found around the world are normal, reverse, and strike-slip. How do fault types relate to plate boundaries?

• View these animations to learn about the basic fault types. Use your own words and hand movements to describe the different fault types to a friend.
• Read Faults: Where Earthquakes Occur to learn more about the different types of faults.

Determining the Epicenter

How is the location of the earthquake slip determined? The process is called triangulation.

• Watch the Epicenter video to learn how to determine the epicenter of an earthquake.
• Use the online activity Virtual Earthquake by Geology Labs On-Line to practice finding the epicenter of an earthquake.
• Alternatively, do this activity to learn how to triangulate.
• Then, discuss the following questions with a friend:
  1. Why is it necessary to have information from three seismograph stations for triangulation? Why is it not possible to find the epicenter using information from just two stations?
  2. Why is it important to know where the epicenter of an earthquake is located?
  3. What can scientists learn about faults from mapping earthquake epicenters?

Measuring Earthquakes

Earthquakes are generally described by their magnitude (the energy released) and intensity (the damage that is done). Learn how these are measured.

• Read more about measuring earthquakes.
• Watch the Magnitude video from a scientist at the Pacific Tsunami Warning Center about earthquake energy release. Describe the difference between a 6.9 and an 8.5 earthquake.
• Compare the two earthquakes in the Intensity Comparison of the 1906 and 1989 Earthquakes animation. Make some observations about their intensities.

Seismic Waves

An earthquake generates a series of seismic waves that transmit the energy released by an earthquake. They travel through the interior and near the surface of the Earth. Learn about the different types of seismic waves.

• Build your own seismograph to experience the phenomenon firsthand.
• Watch the Seismic Waves animation and answer the following questions:
  1. What are the different kinds of waves?
  2. Which wave moves the fastest?
  3. Which wave causes the most destruction?
• After watching the animation, review with a friend how the buildings fared on the different substrates. On which type of substrate is it safest to build?

4. Bay Area Earthquakes

Bay Area Faults

California lies within an active seismic zone, straddling the Pacific and North American plates, which are grinding past each other. There are many active faults in California that are capable of creating major earthquakes. The Bay Area sits on a series of active faults that include the San Andreas, Calaveras, and Hayward.

• Read more about Bay Area Faults.
• Use the Bay Area Fault Planes image to determine how many fault planes cut through the Bay Area. Why do you think there are so many?
• Watch the Hayward Fault: Predictable Peril video and discuss: Why are scientists so concerned about earthquakes occurring on the Hayward Fault?
• Based on the evidence of the video above, what type of fault is the Hayward Fault? Why do you think so? (Review the fault animations.)

The Great San Francisco Earthquake of 1906

The San Andreas Fault, part of the boundary between the Pacific and North American plates, has been the source of damaging earthquakes in the Bay Area. In 1906 a large earthquake occurred on the San Andreas Fault that led to the destruction of many city blocks in San Francisco.

• Watch The Science Behind the 1906 Earthquake video and collect the following information:
  1. Where was the focus of the 1906 Earthquake?
  2. What do the red and yellow colors represent on the simulation and how are they related?

Personal Accounts of Earthquakes

Below are oral history accounts from the 1906 earthquake. Explore these documents and answer the questions provided. Then, seek out a family member or family friend who experienced the 1989 Loma Prieta earthquake. Compare and contrast events as told from several perspectives.

• Explore these oral history accounts from the 1906 earthquake. 
  1. ​Compare and contrast the first-person narratives.
  2. Why do personal accounts differ from each other?
• Use this guide to conduct your own interviews of family or family friends who experienced the 1989 Loma Prieta earthquake.
• Share your findings of your interviews with your fellow students. Do these personal accounts differ from each other? Why?

5. Get Prepared

Engineering Preparedness

California has experienced many damaging earthquakes. From the damage caused, scientists and engineers have learned how to design buildings that will better withstand the shaking. Over the past few decades, many structures have undergone earthquake retrofitting in the Bay Area and beyond.

• Watch The Shaking Table at UC Berkeley video to learn more about how engineers make our built environment better able to withstand earthquakes.
• View the The New Bay Bridge: Earthquake Makeover video to learn about changes to the new Bay Bridge in the San Francisco Bay Area.

What to Do Before an Earthquake

Creating an emergency plan, preparing an earthquake kit, and safely storing and securing heavy items are a few ways to prepare for the big one!

• Read How to Prepare for an Earthquake.
• Make a list of items for your classroom earthquake kit and create a kit that you store at school.
• Develop an emergency plan. Think about a few places where you spend the majority of your time. This may be at home, at school, in your car, etc.

What to Do During an Earthquake

Earthquakes are unpredictable and can happen at any time. It is important to know what to do when an earthquake occurs whether you are at home, at work or at play.

• Go to the FEMA Ready website and research what to do during an earthquake. Relate this information to your plans for preparing for an earthquake.
• If an earthquake occurred at home, at work, or at play, what would you do? Imagine realistic scenarios and consider where you would drop, cover, and hold on. Do these locations have hazards?

What to Do After an Earthquake

The more prepared you are after an earthquake, the better. Consider the information you have learned regarding what to do before and after an earthquake. It is not known what the situation will actually be after an earthquake. What are necessary steps that you can take to assess the situation and your safety?

• If you don’t already know, take the time to learn how to turn off water and gas in your home.
• Set a safe location to meet your family or friends after an earthquake. How will you get there? What would you bring with you?

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Connections to NGSS Disciplinary Core Ideas

ESS1.C The History of Planet Earth

• (Grade 4) Local, regional, and global patterns of rock formations reveal changes over time due to earth forces, such as earthquakes. The presence and location of certain fossil types indicate the order in which rock layers were formed.
• (Grades 6-8) Tectonic processes continually generate new ocean sea floor at ridges and destroy old sea floor at trenches.
• (Grades 9-12) Continental rocks, which can be older than 4 billion years, are generally much older than the rocks of the ocean floor, which are less than 200 million years old.

ESS2.A Earth Materials and Systems

• (Grades 9-12) Evidence from deep probes and seismic waves, reconstructions of historical changes in Earth’s surface and its magnetic field, and an understanding of physical and chemical processes lead to a model of Earth with a hot but solid inner core, a liquid outer core, a solid mantle and crust. Motions of the mantle and crust occur primarily through thermal convection, which involves the cycling of matter due to the outward flow of energy from Earth’s interior and gravitational movement of denser materials toward the interior.

ESS2.B Plate Tectonics and Large-Scale System Interactions

• (Grade 4) The locations of mountain ranges, deep ocean trenches, ocean floor structures, earthquakes, and volcanoes occur in patterns. Most earthquakes and volcanoes occur in bands that are often along the boundaries between continents and oceans. Major mountain chains form inside continents or near their edges. Maps can help locate the different land and water features areas of Earth.
• (Grades 6-8) Maps of ancient land and water patterns, based on investigations of rocks and fossils, make clear how Earth’s plates have moved great distances, collided, and spread apart.
• (Grades 6-8) The planet’s systems interact over scales that range from microscopic to global in size, and they operate over fractions of a second to billions of years. These interactions have shaped Earth’s history and will determine its future.
• (Grades 9-12) Plate tectonics is the unifying theory that explains the past and current movements of the rocks at Earth’s surface and provides a framework for understanding its geologic history. Plate movements are responsible for most continental and ocean-floor features and for the distribution of most rocks and minerals within Earth’s crust.
• (Grades 9-12) Plate tectonics can be viewed as the surface expression of mantle convection.

ESS3.B Natural Hazards

• (Grade 4) A variety of hazards result from natural processes (e.g., earthquakes, tsunamis, volcanic eruptions). Humans cannot eliminate the hazards but can take steps to reduce their impacts.
• (Grades 6-8) Mapping the history of natural hazards in a region, combined with an understanding of related geologic forces can help forecast the locations and likelihoods of future events.
• (Grades 9-12) Natural hazards and other geologic events have shaped the course of human history; [they] have significantly altered the sizes of human populations and have driven human migrations.

PS4.A Wave Properties

• (Grades 9-12) Geologists use seismic waves and their reflection at interfaces between layers to probe structures deep in the planet.

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This post is part of Exploring Earthquakes, a rich collection of resources co-presented by the California Academy of Sciences and KQED. This material is also available as a free iBooks textbook and iTunes U course.

Don’t miss Earthquake, an interactive exhibit at the Academy exploring the seismic forces that impact us today and featuring the Shake House, an earthquake simulator.

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What are earthquakes? Get a new perspective on these powerful phenomena with our collection of videos and infographics co-produced with KQED, originally designed with middle and high school educators in mind. You and your students will learn why earthquakes happen, how they’ve shaped the Bay Area, and what you can do to prepare for the next one. We’ve included ideas for how to structure a sequence of learning tasks, but feel free to pick and choose!

Whether you want to use the Exploring Earthquakes resources with students or to polish your own content knowledge, the following guide provides ideas for how to get started.

1. The Earth’s Structure

Core, Mantle and Crust

Before learning about earthquakes, let’s look at the inside of our planet.

• View the video Inside the Earth: Exploring Earth’s Layers and consider the following questions:
  1. What are distinct characteristics of each layer?
  2. How is Earth’s surface impacted by its interior?
• Read more about the core, mantle and crust.

Plate Boundaries

Movement in narrow zones along plate boundaries causes most earthquakes. Most seismic activity occurs at three types of plate boundaries – convergent, divergent, and transform.

• Observe the three types of plate boundaries and note where they occur on Earth.
• Review the brief description of each boundary type.
• After watching the Plate Boundaries video, research and find specific examples of convergent, divergent, and transform boundaries.

Evidence of Earth’s Layers

During an earthquake, different types of seismic waves move through the Earth, traveling through solids or liquids differently. This helps scientists understand the properties and composition of the Earth’s layers – the core, mantle, and crust.

• Look at the Seismic Waves video and discuss with a friend how P and S waves travel differently through the Earth’s layers.

2. Plate Movement through Geologic Time

The Supercontinent Cycle

Today’s configuration of continents is dramatically different than it was in the past. Learn how previous supercontinents formed and then broke up again over hundreds of millions of years due to plate tectonics.

• Watch the Plate Tectonics: Shaping the Continents video to witness how Earth’s forces have shaped the continents from present day to millions of years ago. Choose a location to follow back in time and describe its path.
• Watch the Back in Time: 200 Million Years Ago to Present Day video on the Earthquake YouTube playlist. Pause the video two to three times while you are watching and reflect on how the land masses have changed over time.

Formation of the Atlantic Ocean

The breakup of Pangaea was fueled by the formation of the Atlantic Ocean as new crust was formed along the underwater ridge. By speeding up geologic time through computer simulations, we can witness the movement of the plates and the beginning of this great ocean.

• You are about to witness the formation of the Atlantic Ocean. Before watching, predict when the Atlantic began to form.
• After viewing this timelapse video from 200 Million Years to Present Day, describe what the Atlantic might look like in millions of years.

Evidence of Plate Tectonics

Some Evidence of Plate Tectonics comes from what we know about previous life on Earth. Scientists have found fossils of the same land-dwelling animal in Africa and South America. How did similar fossils come to be so far apart? Evidence of plate tectonics has also been gathered from clues left by glaciers and the shapes of coastlines. This has helped scientists to piece together the previous configuration of the continents. How is this possible?

• After viewing the Records in Rock graphic of fossil evidence, make a list of questions that you have about fossil records and the connection to plate tectonics.
• Similar fossils from South America and Africa are now separated by an ocean. What connections can you make between this video and the previous graphic? What new questions do you have?
• View this Remnants in Rock graphic of glacier evidence and discuss how it supports the idea of a past supercontinent.
• This Complementary Coasts graphic provides evidence of complementary coastlines along Africa and South America. Look at a world map and determine other coastlines that could fit together based on their shapes.

Plate Tectonics Shaped Human History

Plate tectonics played an important role in the history of ancient civilizations both by causing destructive events and opportunities for life to flourish.

• Watch the Plate Tectonics and Ancient Civilizations video and consider why early civilizations would spring up in tectonically active areas.

3. Earthquake 101

Anatomy of an Earthquake

Although the Earth’s surface is moving and changing through geologic time, we usually do not see it happening before our eyes, but we can experience it through earthquakes. As the plates move past each other, along fault zones, they sometimes get caught and pressure builds up. When the plates finally give and slip due to the increased pressure, energy is released as seismic waves, causing the ground to shake. This is an earthquake.

• Using the Anatomy of an Earthquake diagram, describe the relationship between the faults and the plates. How are the focus and the epicenter different?
• Design a demonstration or model using everyday materials showing how earthquakes occur (built-up strain and sudden energy release).

Fault Types

Basic fault types found around the world are normal, reverse, and strike-slip. How do fault types relate to plate boundaries?

• View these animations to learn about the basic fault types. Use your own words and hand movements to describe the different fault types to a friend.
• Read Faults: Where Earthquakes Occur to learn more about the different types of faults.

Determining the Epicenter

How is the location of the earthquake slip determined? The process is called triangulation.

• Watch the Epicenter video to learn how to determine the epicenter of an earthquake.
• Use the online activity Virtual Earthquake by Geology Labs On-Line to practice finding the epicenter of an earthquake.
• Alternatively, do this activity to learn how to triangulate.
• Then, discuss the following questions with a friend:
  1. Why is it necessary to have information from three seismograph stations for triangulation? Why is it not possible to find the epicenter using information from just two stations?
  2. Why is it important to know where the epicenter of an earthquake is located?
  3. What can scientists learn about faults from mapping earthquake epicenters?

Measuring Earthquakes

Earthquakes are generally described by their magnitude (the energy released) and intensity (the damage that is done). Learn how these are measured.

• Read more about measuring earthquakes.
• Watch the Magnitude video from a scientist at the Pacific Tsunami Warning Center about earthquake energy release. Describe the difference between a 6.9 and an 8.5 earthquake.
• Compare the two earthquakes in the Intensity Comparison of the 1906 and 1989 Earthquakes animation. Make some observations about their intensities.

Seismic Waves

An earthquake generates a series of seismic waves that transmit the energy released by an earthquake. They travel through the interior and near the surface of the Earth. Learn about the different types of seismic waves.

• Build your own seismograph to experience the phenomenon firsthand.
• Watch the Seismic Waves animation and answer the following questions:
  1. What are the different kinds of waves?
  2. Which wave moves the fastest?
  3. Which wave causes the most destruction?
• After watching the animation, review with a friend how the buildings fared on the different substrates. On which type of substrate is it safest to build?

4. Bay Area Earthquakes

Bay Area Faults

California lies within an active seismic zone, straddling the Pacific and North American plates, which are grinding past each other. There are many active faults in California that are capable of creating major earthquakes. The Bay Area sits on a series of active faults that include the San Andreas, Calaveras, and Hayward.

• Read more about Bay Area Faults.
• Use the Bay Area Fault Planes image to determine how many fault planes cut through the Bay Area. Why do you think there are so many?
• Watch the Hayward Fault: Predictable Peril video and discuss: Why are scientists so concerned about earthquakes occurring on the Hayward Fault?
• Based on the evidence of the video above, what type of fault is the Hayward Fault? Why do you think so? (Review the fault animations.)

The Great San Francisco Earthquake of 1906

The San Andreas Fault, part of the boundary between the Pacific and North American plates, has been the source of damaging earthquakes in the Bay Area. In 1906 a large earthquake occurred on the San Andreas Fault that led to the destruction of many city blocks in San Francisco.

• Watch The Science Behind the 1906 Earthquake video and collect the following information:
  1. Where was the focus of the 1906 Earthquake?
  2. What do the red and yellow colors represent on the simulation and how are they related?

Personal Accounts of Earthquakes

Below are oral history accounts from the 1906 earthquake. Explore these documents and answer the questions provided. Then, seek out a family member or family friend who experienced the 1989 Loma Prieta earthquake. Compare and contrast events as told from several perspectives.

• Explore these oral history accounts from the 1906 earthquake. 
  1. ​Compare and contrast the first-person narratives.
  2. Why do personal accounts differ from each other?
• Use this guide to conduct your own interviews of family or family friends who experienced the 1989 Loma Prieta earthquake.
• Share your findings of your interviews with your fellow students. Do these personal accounts differ from each other? Why?

5. Get Prepared

Engineering Preparedness

California has experienced many damaging earthquakes. From the damage caused, scientists and engineers have learned how to design buildings that will better withstand the shaking. Over the past few decades, many structures have undergone earthquake retrofitting in the Bay Area and beyond.

• Watch The Shaking Table at UC Berkeley video to learn more about how engineers make our built environment better able to withstand earthquakes.
• View the The New Bay Bridge: Earthquake Makeover video to learn about changes to the new Bay Bridge in the San Francisco Bay Area.

What to Do Before an Earthquake

Creating an emergency plan, preparing an earthquake kit, and safely storing and securing heavy items are a few ways to prepare for the big one!

• Read How to Prepare for an Earthquake.
• Make a list of items for your classroom earthquake kit and create a kit that you store at school.
• Develop an emergency plan. Think about a few places where you spend the majority of your time. This may be at home, at school, in your car, etc.

What to Do During an Earthquake

Earthquakes are unpredictable and can happen at any time. It is important to know what to do when an earthquake occurs whether you are at home, at work or at play.

• Go to the FEMA Ready website and research what to do during an earthquake. Relate this information to your plans for preparing for an earthquake.
• If an earthquake occurred at home, at work, or at play, what would you do? Imagine realistic scenarios and consider where you would drop, cover, and hold on. Do these locations have hazards?

What to Do After an Earthquake

The more prepared you are after an earthquake, the better. Consider the information you have learned regarding what to do before and after an earthquake. It is not known what the situation will actually be after an earthquake. What are necessary steps that you can take to assess the situation and your safety?

• If you don’t already know, take the time to learn how to turn off water and gas in your home.
• Set a safe location to meet your family or friends after an earthquake. How will you get there? What would you bring with you?

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Connections to NGSS Disciplinary Core Ideas

ESS1.C The History of Planet Earth

• (Grade 4) Local, regional, and global patterns of rock formations reveal changes over time due to earth forces, such as earthquakes. The presence and location of certain fossil types indicate the order in which rock layers were formed.
• (Grades 6-8) Tectonic processes continually generate new ocean sea floor at ridges and destroy old sea floor at trenches.
• (Grades 9-12) Continental rocks, which can be older than 4 billion years, are generally much older than the rocks of the ocean floor, which are less than 200 million years old.

ESS2.A Earth Materials and Systems

• (Grades 9-12) Evidence from deep probes and seismic waves, reconstructions of historical changes in Earth’s surface and its magnetic field, and an understanding of physical and chemical processes lead to a model of Earth with a hot but solid inner core, a liquid outer core, a solid mantle and crust. Motions of the mantle and crust occur primarily through thermal convection, which involves the cycling of matter due to the outward flow of energy from Earth’s interior and gravitational movement of denser materials toward the interior.

ESS2.B Plate Tectonics and Large-Scale System Interactions

• (Grade 4) The locations of mountain ranges, deep ocean trenches, ocean floor structures, earthquakes, and volcanoes occur in patterns. Most earthquakes and volcanoes occur in bands that are often along the boundaries between continents and oceans. Major mountain chains form inside continents or near their edges. Maps can help locate the different land and water features areas of Earth.
• (Grades 6-8) Maps of ancient land and water patterns, based on investigations of rocks and fossils, make clear how Earth’s plates have moved great distances, collided, and spread apart.
• (Grades 6-8) The planet’s systems interact over scales that range from microscopic to global in size, and they operate over fractions of a second to billions of years. These interactions have shaped Earth’s history and will determine its future.
• (Grades 9-12) Plate tectonics is the unifying theory that explains the past and current movements of the rocks at Earth’s surface and provides a framework for understanding its geologic history. Plate movements are responsible for most continental and ocean-floor features and for the distribution of most rocks and minerals within Earth’s crust.
• (Grades 9-12) Plate tectonics can be viewed as the surface expression of mantle convection.

ESS3.B Natural Hazards

• (Grade 4) A variety of hazards result from natural processes (e.g., earthquakes, tsunamis, volcanic eruptions). Humans cannot eliminate the hazards but can take steps to reduce their impacts.
• (Grades 6-8) Mapping the history of natural hazards in a region, combined with an understanding of related geologic forces can help forecast the locations and likelihoods of future events.
• (Grades 9-12) Natural hazards and other geologic events have shaped the course of human history; [they] have significantly altered the sizes of human populations and have driven human migrations.

PS4.A Wave Properties

• (Grades 9-12) Geologists use seismic waves and their reflection at interfaces between layers to probe structures deep in the planet.

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This post is part of Exploring Earthquakes, a rich collection of resources co-presented by the California Academy of Sciences and KQED. This material is also available as a free iBooks textbook and iTunes U course.

Don’t miss Earthquake, an interactive exhibit at the Academy exploring the seismic forces that impact us today and featuring the Shake House, an earthquake simulator.

from QUEST http://ift.tt/1RZSf99

Exploring Earthquakes

Geological processes shape life on Earth. They affect its surface, the evolution and distribution of our planet’s species, and impact people’s lives.

Within the past century, scientists have gained significant knowledge about these processes and why earthquakes occur. They’ve learned that Earth’s surface, made up of plates, is constantly moving and that forces between these plates cause earthquakes, which produce energy released as seismic waves. They’ve also studied how this energy release affects our environment.

Earthquakes are part of the larger story of plate tectonics. The constant movement of Earth’s plates builds mountains, moves continents, and creates the landscape in which life evolves or goes extinct.

By studying these processes, scientists can predict where earthquakes will occur, but not when. Even if we don’t know when earthquakes are coming, we can do our best to prepare for them. Knowing what to expect from and how to respond to an earthquake can mitigate its impact and save lives.

The California Academy of Sciences (CAS) and KQED partnered to bring you this rich collection of resources about earthquakes. This material is also available as a free iBooks Textbook in Apple’s iBookstore and as a course of iTunes U. The media collection includes the following information about earthquakes:

What is an Earthquake?

• From Core to Crust: Defining Earth’s Layers [CAS]
• Inside the Earth: Exploring Earth’s Layers [CAS]
• Plate Tectonics: Shaping the Continents [CAS]
• Evidence of Plate Tectonics [CAS]
• Plate Tectonics and Ancient Civilizations [CAS]
• Plate Boundaries: Divergent, Convergent, and Transform [CAS]
• Faults: Where Earthquakes Occur [CAS]

Measuring Earthquakes

• What Are Seismic Waves?
• How to Find the Epicenter of an Earthquake
• Measuring Earthquakes: Intensity and Magnitude
• Building for Earthquakes

Bay Area Earthquakes

• San Francisco Bay Area Earthquakes and Faults
• The Great San Francisco Earthquake of 1906 [CAS]

Earthquake Preparedness

• How to Prepare for an Earthquake [CAS]

Teacher Guide [CAS]

from QUEST http://ift.tt/1qtT2o8

Geological processes shape life on Earth. They affect its surface, the evolution and distribution of our planet’s species, and impact people’s lives.

Within the past century, scientists have gained significant knowledge about these processes and why earthquakes occur. They’ve learned that Earth’s surface, made up of plates, is constantly moving and that forces between these plates cause earthquakes, which produce energy released as seismic waves. They’ve also studied how this energy release affects our environment.

Earthquakes are part of the larger story of plate tectonics. The constant movement of Earth’s plates builds mountains, moves continents, and creates the landscape in which life evolves or goes extinct.

By studying these processes, scientists can predict where earthquakes will occur, but not when. Even if we don’t know when earthquakes are coming, we can do our best to prepare for them. Knowing what to expect from and how to respond to an earthquake can mitigate its impact and save lives.

The California Academy of Sciences (CAS) and KQED partnered to bring you this rich collection of resources about earthquakes. This material is also available as a free iBooks Textbook in Apple’s iBookstore and as a course of iTunes U. The media collection includes the following information about earthquakes:

What is an Earthquake?

• From Core to Crust: Defining Earth’s Layers [CAS]
• Inside the Earth: Exploring Earth’s Layers [CAS]
• Plate Tectonics: Shaping the Continents [CAS]
• Evidence of Plate Tectonics [CAS]
• Plate Tectonics and Ancient Civilizations [CAS]
• Plate Boundaries: Divergent, Convergent, and Transform [CAS]
• Faults: Where Earthquakes Occur [CAS]

Measuring Earthquakes

• What Are Seismic Waves?
• How to Find the Epicenter of an Earthquake
• Measuring Earthquakes: Intensity and Magnitude
• Building for Earthquakes

Bay Area Earthquakes

• San Francisco Bay Area Earthquakes and Faults
• The Great San Francisco Earthquake of 1906 [CAS]

Earthquake Preparedness

• How to Prepare for an Earthquake [CAS]

Teacher Guide [CAS]

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San Francisco Bay Area Earthquakes and Faults

Measuring Earthquakes: Intensity and Magnitude

Scientists measure both the energy released in an earthquake and its damage. In 1902, Italian scientist Giuseppe Mercalli introduced a scale that measures the intensity of an earthquake based on its effects on people and structures. A modified version of his scale is still in use today. The 12-point Modified Mercalli Intensity Scale describes how an earthquake is felt and the damage that it causes. The higher the Mercalli number is, the more damage found in the area. The Modified Mercalli number assigned to a particular location varies based on factors such as the distance from the focus and the area’s geology. For example, houses built on softer sediments may receive greater damage than those built on bedrock.

The amount of energy an earthquake releases is expressed in terms of its magnitude. Unlike intensity, which varies depending on how populated an area is, the magnitude of an earthquake is the same no matter where you are. To measure the magnitude of an earthquake, the American scientist Charles Richter developed a scale in 1935. Known as the Richter scale, it assigns a number based on the height of the waves on a seismogram (the visual output of a seismograph). Seismographs measure ground motion, including the energy released by an earthquake.

In 1979, American scientist Thomas Hanks and Japanese scientist Hiroo Kanamori introduced a new and more precise scale for measuring the magnitude of earthquakes: the moment magnitude scale. This is the scale most scientists use today. Its ratings are based on physical evidence, particularly the geometry of the earthquake. To determine each earthquake’s assigned number, scientists compare the area of the rupture along a fault to the amount of energy released. Scientists prefer the moment magnitude scale over the Richter scale because it can more accurately compare various types of earthquakes—big or small, near or far—at the same scale. Even though earthquakes with moment magnitudes of 5 or 6 can cause damage, in general, only earthquakes with a moment magnitude of 7 or higher are classified as “major” earthquakes.

Additional Resources:
Magnitude/Intensity Comparison
Earthquake Intensity Maps for the 1906 San Francisco Earthquake

---

This post is part of Exploring Earthquakes, a rich collection of resources co-presented by the California Academy of Sciences and KQED. This material is also available as a free iBooks textbook and iTunes U course.

Don’t miss Earthquake, an interactive exhibit at the Academy exploring the seismic forces that impact us today and featuring the Shake House, an earthquake simulator.

from QUEST http://ift.tt/1VpdJid

Scientists measure both the energy released in an earthquake and its damage. In 1902, Italian scientist Giuseppe Mercalli introduced a scale that measures the intensity of an earthquake based on its effects on people and structures. A modified version of his scale is still in use today. The 12-point Modified Mercalli Intensity Scale describes how an earthquake is felt and the damage that it causes. The higher the Mercalli number is, the more damage found in the area. The Modified Mercalli number assigned to a particular location varies based on factors such as the distance from the focus and the area’s geology. For example, houses built on softer sediments may receive greater damage than those built on bedrock.

The amount of energy an earthquake releases is expressed in terms of its magnitude. Unlike intensity, which varies depending on how populated an area is, the magnitude of an earthquake is the same no matter where you are. To measure the magnitude of an earthquake, the American scientist Charles Richter developed a scale in 1935. Known as the Richter scale, it assigns a number based on the height of the waves on a seismogram (the visual output of a seismograph). Seismographs measure ground motion, including the energy released by an earthquake.

In 1979, American scientist Thomas Hanks and Japanese scientist Hiroo Kanamori introduced a new and more precise scale for measuring the magnitude of earthquakes: the moment magnitude scale. This is the scale most scientists use today. Its ratings are based on physical evidence, particularly the geometry of the earthquake. To determine each earthquake’s assigned number, scientists compare the area of the rupture along a fault to the amount of energy released. Scientists prefer the moment magnitude scale over the Richter scale because it can more accurately compare various types of earthquakes—big or small, near or far—at the same scale. Even though earthquakes with moment magnitudes of 5 or 6 can cause damage, in general, only earthquakes with a moment magnitude of 7 or higher are classified as “major” earthquakes.

Additional Resources:
Magnitude/Intensity Comparison
Earthquake Intensity Maps for the 1906 San Francisco Earthquake

---

This post is part of Exploring Earthquakes, a rich collection of resources co-presented by the California Academy of Sciences and KQED. This material is also available as a free iBooks textbook and iTunes U course.

Don’t miss Earthquake, an interactive exhibit at the Academy exploring the seismic forces that impact us today and featuring the Shake House, an earthquake simulator.

from QUEST http://ift.tt/1VpdJid

Building for Earthquakes

An earthquake forecast for the State of California was released by USGS, Southern California Earthquake Center and the California Geological Survey in 2008. It states that there is a greater than 99% probability that one or more earthquakes of at least a 6.7 magnitude will occur in California over the next 30 years. California has experienced many damaging earthquakes in its history. Scientists and engineers have learned how to design buildings that will better withstand future earthquakes. Over the past few decades, many structures have undergone earthquake retrofitting in the Bay Area and beyond.

Engineers have dedicated their careers to studying how to make the buildings we live and work in safer and better able to withstand damage from future earthquakes. Computer simulations help scientists test possible scenarios and see the impact of a future earthquake on the Bay Area. Information such as the proximity of mountains, type of soil, and other factors are used to calculate shaking intensity. This information allows engineers to design safer structures for earthquake prone areas.

Real-world tests on building materials are conducted on large tables that simulate ground shaking using accurate seismic data. The shaking table at the Pacific Earthquake Engineering Research Center at UC Berkeley is the largest multi-directional shaking table in the U.S. and has been the site of important research. Because the shaking table can move vertically and horizontally—and because it includes three rotational components—it can be programmed to simulate seismic waves with various forces, velocities and frequencies. This allows engineers to test how building materials will stand up under different earthquake scenarios. Engineering designs, such as the isolation bearings found below a building, enable engineers to strengthen buildings like San Francisco’s City Hall and the iconic Ferry Building.

The San Francisco-Oakland Bay Bridge was built in 1936. During its first year, nine million vehicles crossed the bridge. That number has now increased to more than 102 million vehicles per year. The bridge consists of two major crossings—the West Span and the East Span, with Yerba Buena Island situated in between. In 1989, the Loma Prieta earthquake caused a portion of the East Span of the bridge to fail, resulting in a decision to retrofit the West Span of the bridge and build a new self-anchored suspension bridge to replace the vulnerable East Span. The new East Span of the Bay Bridge has been designed to withstand the largest earthquake expected to occur at a nearby fault in the next 1,500 years. Instead of having two cables holding up the deck like most other self-anchored suspension bridges, it has one huge cable that loops under the bridge, acting like a sling. The tower in the East Span is made up of four separate legs that are connected by “shear link beams.” These steel beams are designed to move separately and will function like fuses in an electrical circuit during an earthquake, absorbing most of the energy and leaving the bridge intact. One of the piles of the tower’s foundation even contains seismic monitoring equipment to collect data about ground motion during an earthquake.

The San Francisco Public Utilities Commission is hard at work on a $4.6 billion, decade-long construction project to overhaul the Hetch Hetchy water system, which delivers water from the Hetch Hetchy reservoir in Yosemite National Park and five local reservoirs to 2.5 million residents in the Bay Area.

---

This post is part of Exploring Earthquakes, a rich collection of resources co-presented by the California Academy of Sciences and KQED. This material is also available as a free iBooks textbook and iTunes U course.

Don’t miss Earthquake, an interactive exhibit at the Academy exploring the seismic forces that impact us today and featuring the Shake House, an earthquake simulator.

from QUEST http://ift.tt/1qtT1R9

An earthquake forecast for the State of California was released by USGS, Southern California Earthquake Center and the California Geological Survey in 2008. It states that there is a greater than 99% probability that one or more earthquakes of at least a 6.7 magnitude will occur in California over the next 30 years. California has experienced many damaging earthquakes in its history. Scientists and engineers have learned how to design buildings that will better withstand future earthquakes. Over the past few decades, many structures have undergone earthquake retrofitting in the Bay Area and beyond.

Engineers have dedicated their careers to studying how to make the buildings we live and work in safer and better able to withstand damage from future earthquakes. Computer simulations help scientists test possible scenarios and see the impact of a future earthquake on the Bay Area. Information such as the proximity of mountains, type of soil, and other factors are used to calculate shaking intensity. This information allows engineers to design safer structures for earthquake prone areas.

Real-world tests on building materials are conducted on large tables that simulate ground shaking using accurate seismic data. The shaking table at the Pacific Earthquake Engineering Research Center at UC Berkeley is the largest multi-directional shaking table in the U.S. and has been the site of important research. Because the shaking table can move vertically and horizontally—and because it includes three rotational components—it can be programmed to simulate seismic waves with various forces, velocities and frequencies. This allows engineers to test how building materials will stand up under different earthquake scenarios. Engineering designs, such as the isolation bearings found below a building, enable engineers to strengthen buildings like San Francisco’s City Hall and the iconic Ferry Building.

The San Francisco-Oakland Bay Bridge was built in 1936. During its first year, nine million vehicles crossed the bridge. That number has now increased to more than 102 million vehicles per year. The bridge consists of two major crossings—the West Span and the East Span, with Yerba Buena Island situated in between. In 1989, the Loma Prieta earthquake caused a portion of the East Span of the bridge to fail, resulting in a decision to retrofit the West Span of the bridge and build a new self-anchored suspension bridge to replace the vulnerable East Span. The new East Span of the Bay Bridge has been designed to withstand the largest earthquake expected to occur at a nearby fault in the next 1,500 years. Instead of having two cables holding up the deck like most other self-anchored suspension bridges, it has one huge cable that loops under the bridge, acting like a sling. The tower in the East Span is made up of four separate legs that are connected by “shear link beams.” These steel beams are designed to move separately and will function like fuses in an electrical circuit during an earthquake, absorbing most of the energy and leaving the bridge intact. One of the piles of the tower’s foundation even contains seismic monitoring equipment to collect data about ground motion during an earthquake.

The San Francisco Public Utilities Commission is hard at work on a $4.6 billion, decade-long construction project to overhaul the Hetch Hetchy water system, which delivers water from the Hetch Hetchy reservoir in Yosemite National Park and five local reservoirs to 2.5 million residents in the Bay Area.

---

This post is part of Exploring Earthquakes, a rich collection of resources co-presented by the California Academy of Sciences and KQED. This material is also available as a free iBooks textbook and iTunes U course.

Don’t miss Earthquake, an interactive exhibit at the Academy exploring the seismic forces that impact us today and featuring the Shake House, an earthquake simulator.

from QUEST http://ift.tt/1qtT1R9

How to Find the Epicenter of an Earthquake

Scientists use triangulation to find the epicenter of an earthquake. When seismic data is collected from at least three different locations, it can be used to determine the epicenter by where it intersects. Every earthquake is recorded on numerous seismographs located in different directions. Each seismograph records the times when the first (P waves) and second (S waves) seismic waves arrive. From that information, scientists can determine how fast the waves are traveling. Knowing this helps them calculate the distance from the epicenter to each seismograph.

To determine the direction each wave traveled, scientists draw circles around the seismograph locations. The radius of each circle equals the known distance to the epicenter. Where these three circles intersect is the epicenter.

---

This post is part of Exploring Earthquakes, a rich collection of resources co-presented by the California Academy of Sciences and KQED. This material is also available as a free iBooks textbook and iTunes U course.

Don’t miss Earthquake, an interactive exhibit at the Academy exploring the seismic forces that impact us today and featuring the Shake House, an earthquake simulator.

from QUEST http://ift.tt/1qtT1R8

Scientists use triangulation to find the epicenter of an earthquake. When seismic data is collected from at least three different locations, it can be used to determine the epicenter by where it intersects. Every earthquake is recorded on numerous seismographs located in different directions. Each seismograph records the times when the first (P waves) and second (S waves) seismic waves arrive. From that information, scientists can determine how fast the waves are traveling. Knowing this helps them calculate the distance from the epicenter to each seismograph.

To determine the direction each wave traveled, scientists draw circles around the seismograph locations. The radius of each circle equals the known distance to the epicenter. Where these three circles intersect is the epicenter.

---

This post is part of Exploring Earthquakes, a rich collection of resources co-presented by the California Academy of Sciences and KQED. This material is also available as a free iBooks textbook and iTunes U course.

Don’t miss Earthquake, an interactive exhibit at the Academy exploring the seismic forces that impact us today and featuring the Shake House, an earthquake simulator.

from QUEST http://ift.tt/1qtT1R8

Hands-On Earthquake Activities for the Classroom

California is earthquake country. For engineers, that means they need to build buildings and bridges that can stand up to the destructive power of earthquakes. But engineers can’t just wait around for the next big one to hit. Instead, they use a giant shaking table to simulate earthquakes. Your classroom doesn’t have a shaking table, but there are still some great classroom activities to help students better understand earthquakes. Check them out below.

What Causes an Earthquake?
In this lesson from PBS LearningMedia, a mixture of video resources and hands-on activities provides students with a great understanding of what causes earthquakes and how scientists are trying to better predict them. Students learn about plate tectonics, explore the concepts of stress, strain and vibration using silly putty and a sugar cube, and discuss different kinds of earthquake damage.

You Don’t Need a Seismograph to Study Earthquakes
This lesson plan from PBS NewsHour is broken down into three parts. First, students will research specific earthquakes from the last 20 years. Then, using rope and a slinky, students can simulate the waves of an earthquake, known as p waves and s waves. Finally, using styrofoam, toothpicks and glue, students can simulate a transform boundary, which is where two tectonic plates meet.

Volcano’s Deadly Warning
Designed for a high school classroom, this activity from NOVA will teach students to identify the different patterns exhibited by volcanic seismic waves by sketching the wave patterns. To understand how these complex waves are formed, students will combine two simple sine waves. By plotting various points, students will explore the concepts of constructive versus destructive interference.

Build Your Own Seismograph
In this activity, students learn how to build their own seismographs out of everyday items. Then, they test the device’s ability to record a simulated classroom earthquake. Students then present their findings to the class. Curriculum alignment sheets are included, allowing teachers to target any age group from 8-18.

from QUEST http://ift.tt/1Xhq85n

California is earthquake country. For engineers, that means they need to build buildings and bridges that can stand up to the destructive power of earthquakes. But engineers can’t just wait around for the next big one to hit. Instead, they use a giant shaking table to simulate earthquakes. Your classroom doesn’t have a shaking table, but there are still some great classroom activities to help students better understand earthquakes. Check them out below.

What Causes an Earthquake?
In this lesson from PBS LearningMedia, a mixture of video resources and hands-on activities provides students with a great understanding of what causes earthquakes and how scientists are trying to better predict them. Students learn about plate tectonics, explore the concepts of stress, strain and vibration using silly putty and a sugar cube, and discuss different kinds of earthquake damage.

You Don’t Need a Seismograph to Study Earthquakes
This lesson plan from PBS NewsHour is broken down into three parts. First, students will research specific earthquakes from the last 20 years. Then, using rope and a slinky, students can simulate the waves of an earthquake, known as p waves and s waves. Finally, using styrofoam, toothpicks and glue, students can simulate a transform boundary, which is where two tectonic plates meet.

Volcano’s Deadly Warning
Designed for a high school classroom, this activity from NOVA will teach students to identify the different patterns exhibited by volcanic seismic waves by sketching the wave patterns. To understand how these complex waves are formed, students will combine two simple sine waves. By plotting various points, students will explore the concepts of constructive versus destructive interference.

Build Your Own Seismograph
In this activity, students learn how to build their own seismographs out of everyday items. Then, they test the device’s ability to record a simulated classroom earthquake. Students then present their findings to the class. Curriculum alignment sheets are included, allowing teachers to target any age group from 8-18.

from QUEST http://ift.tt/1Xhq85n

What Influences Your Dietary Choices?

Featured Media Resource: VIDEO: Healthy Eating Tips: Do We Control Our Food Choices? (Rutgers Today)
“Food framing” is a strategy of food vendors to attract consumers to specific food choices.

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Do Now U

What influences your dietary choices? #DoNowUDiet

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How to Do Now

To respond to the Do Now U, you can Read More …

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Featured Media Resource: VIDEO: Healthy Eating Tips: Do We Control Our Food Choices? (Rutgers Today)
“Food framing” is a strategy of food vendors to attract consumers to specific food choices.

---

Do Now U

What influences your dietary choices? #DoNowUDiet

---

How to Do Now

To respond to the Do Now U, you can Read More …

Source:: DoNow Science

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How Would You Make the Streets Safer for Cyclists?

What is Structural Engineering?

Structural engineering is a specialized branch of civil engineering that entails analyzing and designing structures, like buildings, bridges and even concert stages.

Engineering is a big discipline that involves a systematic approach to designing solutions to problems experienced in the real world. There are many different fields of engineering, like mechanical engineering, electrical engineering, civil engineering, chemical engineering and systems engineering. Within these fields are various subfields; structural engineering is a subfield of civil engineering.

Structural engineers use mathematics and physics to make sure that a given structure won’t collapse or fall over. When ensuring a structure’s sturdiness, structural engineers perform calculations and look at several factors, such as

• The forces a structure is likely to encounter
• The properties of the materials that make up a structure
• The shapes that make up a structure

For example, a bridge not only has to support itself; it also has to handle a variety of forces, such as downward forces caused by the traffic driving over it, and forces caused by wind, snow or an earthquake.

Structural engineers take properties like strength, weight, flammability and stiffness of materials into consideration. For example, steel is typically heavier and stronger than wood.

Additionally, different shapes lend themselves to different purposes. For instance, square bases can typically hold more weight than triangular bases.

Structural engineers perform calculations to determine the best materials and shapes to use in order to build a sturdy structure. Thank you structural engineers, for doing your part in making sure our structures and nice and sturdy.

This video is a companion video to Engineering Is Converting Buses to Showers for the Homeless. Lava Mae, a non-profit organization in San Francisco, takes old public transportation buses and converts them into showers for the homeless. The conversion involves many different kinds of engineering including mechanical, electrical and structural engineering.

Want more engineering resources? Check out our Engineering Is playlist on YouTube and our Career Spotlight videos featuring a variety of engineers.

from QUEST http://ift.tt/1WJatLX

Structural engineering is a specialized branch of civil engineering that entails analyzing and designing structures, like buildings, bridges and even concert stages.

Engineering is a big discipline that involves a systematic approach to designing solutions to problems experienced in the real world. There are many different fields of engineering, like mechanical engineering, electrical engineering, civil engineering, chemical engineering and systems engineering. Within these fields are various subfields; structural engineering is a subfield of civil engineering.

Structural engineers use mathematics and physics to make sure that a given structure won’t collapse or fall over. When ensuring a structure’s sturdiness, structural engineers perform calculations and look at several factors, such as

• The forces a structure is likely to encounter
• The properties of the materials that make up a structure
• The shapes that make up a structure

For example, a bridge not only has to support itself; it also has to handle a variety of forces, such as downward forces caused by the traffic driving over it, and forces caused by wind, snow or an earthquake.

Structural engineers take properties like strength, weight, flammability and stiffness of materials into consideration. For example, steel is typically heavier and stronger than wood.

Additionally, different shapes lend themselves to different purposes. For instance, square bases can typically hold more weight than triangular bases.

Structural engineers perform calculations to determine the best materials and shapes to use in order to build a sturdy structure. Thank you structural engineers, for doing your part in making sure our structures and nice and sturdy.

This video is a companion video to Engineering Is Converting Buses to Showers for the Homeless. Lava Mae, a non-profit organization in San Francisco, takes old public transportation buses and converts them into showers for the homeless. The conversion involves many different kinds of engineering including mechanical, electrical and structural engineering.

Want more engineering resources? Check out our Engineering Is playlist on YouTube and our Career Spotlight videos featuring a variety of engineers.

from QUEST http://ift.tt/1WJatLX

Are the Benefits of Organic Food Worth the Price?

Featured Media Resource: VIDEO: What Is Organic Food? (Epipheo)
Epipheo explains what organic food is and why “organic” doesn’t always equal “healthy.”

---

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Are the benefits of organic food worth its price? Do you buy organic food? Why or why not? #DoNowUOrganic

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How to Do Now

To respond to the Read More …

Source:: DoNow Science

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Featured Media Resource: VIDEO: What Is Organic Food? (Epipheo)
Epipheo explains what organic food is and why “organic” doesn’t always equal “healthy.”

---

Do Now U

Are the benefits of organic food worth its price? Do you buy organic food? Why or why not? #DoNowUOrganic

---

How to Do Now

To respond to the Read More …

Source:: DoNow Science

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How Seismic Waves Cause Damage During an Earthquake

An earthquake generates a series of seismic waves that travel through the interior or near the surface of the Earth. There are four types of seismic waves.

How will three identically engineered buildings react to an earthquake on different types of substrate?

The first set of waves to be detected by seismographs are P waves, or primary waves, as they’re the fastest. They’re compressional or longitudinal waves that push and pull the ground in the direction the wave is traveling. They usually cause very little damage.

S waves, or secondary waves, come next since they travel more slowly than P waves. They travel in the same direction, but they shake the ground back and forth perpendicular to the direction the wave is traveling. S waves are more dangerous than P waves because they have greater amplitude and produce vertical and horizontal motion of the ground surface.

The slowest waves, surface waves, arrive last. They travel only along the surface of the Earth. There are two types of surface waves: Love and Rayleigh waves.

Love waves move back and forth horizontally.

Rayleigh waves cause both vertical and horizontal ground motion. These can be the most destructive waves as they roll along lifting and dropping the ground as they pass.

Want to learn more about earthquakes? Check out this video about how engineers use a giant shaking table to design earthquake safe structures.

 

 

 

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An earthquake generates a series of seismic waves that travel through the interior or near the surface of the Earth. There are four types of seismic waves.

How will three identically engineered buildings react to an earthquake on different types of substrate?

The first set of waves to be detected by seismographs are P waves, or primary waves, as they’re the fastest. They’re compressional or longitudinal waves that push and pull the ground in the direction the wave is traveling. They usually cause very little damage.

S waves, or secondary waves, come next since they travel more slowly than P waves. They travel in the same direction, but they shake the ground back and forth perpendicular to the direction the wave is traveling. S waves are more dangerous than P waves because they have greater amplitude and produce vertical and horizontal motion of the ground surface.

The slowest waves, surface waves, arrive last. They travel only along the surface of the Earth. There are two types of surface waves: Love and Rayleigh waves.

Love waves move back and forth horizontally.

Rayleigh waves cause both vertical and horizontal ground motion. These can be the most destructive waves as they roll along lifting and dropping the ground as they pass.

Want to learn more about earthquakes? Check out this video about how engineers use a giant shaking table to design earthquake safe structures.

 

 

 

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Should we research dangerous viruses which might cause pandemics ?

Featured Media Resource: [AUDIO] Biologists Choose Sides In Safety Debate Over Lab-Made Pathogens (NPR)
Scientists believe that to protect civilians from the next pandemic, they first have to understand the risks of researching viruses in experiments. However, opponents believe that making new strains of viruses aren’t worth the Read More …

Source:: DoNow Science

from QUEST http://ift.tt/1VgnRIZ

Featured Media Resource: [AUDIO] Biologists Choose Sides In Safety Debate Over Lab-Made Pathogens (NPR)
Scientists believe that to protect civilians from the next pandemic, they first have to understand the risks of researching viruses in experiments. However, opponents believe that making new strains of viruses aren’t worth the Read More …

Source:: DoNow Science

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Simulating Earthquakes with a Shaking Table