STEM education is about creating a student-centered, inquiry-based classroom where students discover the natural (and real-world) connection between science, technology, engineering, and math. As educators, it is our job to keep the flame of curiosity burning bright in our students in our classrooms and throughout their lives.
This webinar will explore the most effective strategies for Inquiry-Based Instruction with a focus on how STEM education connects to the Common Core State Standards.
You will learn:
Strategies for implementing inquiry-based instruction with an emphasis on critical thinking skills.
Effective ways to apply STEM competencies to impact lesson planning and assessment with a focus on increasing real-world application of content knowledge.
How STEM education connects to the instructional shifts embedded in the Common Core State Standards.
2. Agenda
How STEM connects to the instructional shifts embedded
in the Common Core State Standards.
Effective ways to apply STEM competencies to impact
lesson planning and assessment with a focus on increasing
application of content knowledge.
Strategies for implementing inquiry-based instruction with
an emphasis on critical thinking skills.
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3. STEM – Common Core Connections
Science – Technology – Engineering – Math
View the standards through a lens of inquiry-based
instruction
Focus on cross-curricular connections, problem solving, &
disciplinary literacy
Real-world application and analysis of content knowledge
Student-centered learning environment
4. STEM – Common Core Connections
The instructional shifts in Common Core ELA and Math are
calling for increased rigor.
“Rigor is more than what you teach, it’s how you teach,
and how students show you they understand content.”
Barbara Blackburn, Ph.D
http://www.barbarablackburnonline.com/rigor/
“Rigorous mathematics refers to a deep, authentic
command of mathematical concepts.”
Making the Shifts - Sandra Alberti
http://www.ascd.org/publications/educationalleadership/dec12/vol70/num04/Making-the-Shifts.aspx
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5. Next Generation Science Standards:
Performance Expectations
1.
2.
3.
4.
5.
6.
7.
8.
Asking Questions and Defining Problems
Developing and Using Models
Planning and Carrying Out Investigations
Analyzing and Interpreting Data
Using Mathematics and Computational Thinking
Constructing Explanations and Designing Solutions
Engaging in Argument from Evidence
Obtaining, Evaluating, and Communicating Information
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6. CCSS Standards for
Mathematical Practice
NGSS: Science Performance
Expectations
Make sense of problems and
persevere in solving them.
Model with mathematics.
Use appropriate tools
strategically.
1.
Reason abstractly and
quantitatively.
Look for and make use of
structure.
Look for and express regularity in
repeated reasoning.
Attend to precision.
Construct viable arguments and
critique the reasoning of others.
1.
2.
2.
3.
3.
4.
5.
Asking Questions and Defining
Problems
Developing and Using Models
Planning and Carrying Out
Investigations
Analyzing and Interpreting Data
Using Mathematics and
Computational Thinking
Constructing Explanations and
Designing Solutions
Engaging in Argument from
Evidence
Obtaining, Evaluating, and
Communicating Information
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7. STEM in the “Real” World
“The meaning of ‘knowing’ has shifted from being able to
remember and repeat to being able to find and use it.”
-National Research Council, 2007
What does this mean for a typical “teacher-centered”
classroom?
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8. STEM Education
A transformation from the typical teacher-centered
classroom to:
Student-centered learning
Driven by:
problem-solving
discovery
exploratory learning
active engagement
9. CER Model
Designing Science Inquiry: Claim + Evidence + Reasoning = Explanation
Eric Brunsell
http://www.edutopia.org/blog/science-inquiry-claim-evidence-reasoning-eric-brunsell
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10. 5 Step Process
What are you curious about? What do you want to know?
This is your driving question.
What will you need to answer your question? Start
researching and experimenting!
This is your evidence.
Analyze and reflect on your data. Are you on the right track?
This is your reasoning.
Did you find the answer to your question?
If so, this is your claim.
How will you communicate your findings?
This is your explanation.
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11. Dan Meyer’s Water Tank
What Can You Do With This: Water Tank?
http://blog.mrmeyer.com/?p=5990
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12. Use the 5 Step Process
1. What do you want to
know?
2. What will you need to
answer your question?
3. Analyze and reflect on your
data. Are you on the right
track?
4. Did you find the answer to
your question?
5. How will you communicate
your findings?
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13. Reflect
What critical thinking skills are we helping students
develop?
How can this process provide more rigor in our instruction?
How can this process connect to other content areas?
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14. CER Model
Designing Science Inquiry: Claim + Evidence + Reasoning = Explanation
Eric Brunsell
http://www.edutopia.org/blog/science-inquiry-claim-evidence-reasoning-eric-brunsell
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16. What does this graffiti image mean?
What information do you need to answer this question?
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17. Evidence and Reasoning to Support your Claim
Evidence
“Banksy” is a United Kingdombased graffiti artist, political
activist, film director, and
painter.
Reasoning
This graffiti was drawn on
Israel's West Bank barrier
The barrier is a wall/fence
under construction by the State
of Israel
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18. Based on evidence & reasoning, what is your claim?
What does this image mean?
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19. Questions to Spur Inquiry
1.
2.
3.
4.
5.
What do you think?
Why do you think that?
How do you know?
Can you tell me more?
What questions do you still have?
5 Powerful Questions Teaches Can Ask Students
October 31, 2013 - Rebecca Alber
http://www.edutopia.org/blog/five-powerful-questions-teachers-ask-students-rebecca-alber
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20. Reflect
How could this model change…
The way we plan our lessons?
Organize our classroom?
The teacher’s role in the classroom?
The students’ role in the classroom?
Our view of “testing” for mastery of content/concepts?
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21. Bloom’s Taxonomy: Revised
Creating
Generating new ideas, products, or ways of viewing things
Designing, constructing, planning, producing, inventing
Evaluating
Justifying a decision or course of action
Checking, hypothesizing, critiquing, experimenting, judging
Analyzing
Breaking information into parts to explore understandings and relationships
Comparing, organizing, deconstructing, interrogating, finding
Applying
Using information in another familiar situation
Implementing, carrying out, using, executing
Understanding
Explaining ideas or concepts
Interpreting, summarizing, paraphrasing, classifying, explaining
Remembering
Recalling information
Recognizing, listing, describing, retrieving, naming, finding
22. Tinkering
“Tinkering is the way that real science happens, in all its
messy glory,” says Sylvia Martinez, co-author of the new
book, Invent to Learn: Making, Tinkering, and Engineering
the Classroom
Martinez is one of the leaders of the “makers’ movement,”
a nationwide effort to help kids discover the value of
getting their hands dirty and their minds engaged. The next
generation of scientists—and artists, and inventors, and
entrepreneurs—may depend on it.
How Do We Inspire Young Inventors?
Annie Murphy Paul | November 25, 2013
http://blogs.kqed.org/mindshift/2013/11/how-do-we-inspire-young-inventors
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23. Tinkering and the 5 E’s Inquiry Cycle
Each Open MAKE event
constitutes the culmination of a
whole month dedicated to
exploring a different theme,
centering activities, exhibits, and
artists around a new material.
Engage
Evaluate
Elaborate
Explore
http://tinkering.exploratorium.edu/blog
Explain
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24. Audri's Monster Trap
He is 7 years old and wants to be a
theoretical physicist when he grows up
and has big plans to study robotics at
MIT.
http://www.youtube.com/watch?v=IMboI4cOAuQ
Hypothesis:
10-20 Failures
1-2 Successes
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25. STEM Competencies
Skills:
Abilities:
Critical Thinking: ability to use
logic and reasoning
Problem Sensitivity: The ability
to tell when something is wrong
or is likely to go wrong.
Active Learning: Understanding
the implications of new
information for problemsolving and decision-making.
Deductive Reasoning: The ability
to apply general rules to specific
problems.
Complex Problem Solving:
develop and evaluate options
and implement solutions.
Inductive Reasoning: The ability
to combine pieces of information
to form general rules or
conclusions
http://cew.georgetown.edu/stem/
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26. Thank You!
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upcoming webinars, and more.
• Catapult Learning on Twitter @catapultlearn
• Share your successes! If you put our methods into
action, let us know about it. Use the hashtag
#catapulting
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