Post on 18-Jun-2020
Models of Professional Development to Support
Implementation of the Next Generation Science Standards
Analysis of Practice and the PD Research TerrainChristopher Wilson
Director of Research, BSCSCommon Ground 2016
April 28, 2016
REL Mid-Atlantic
One of 10 RELs,REL Mid-Atlantic serves: • Delaware• District of Columbia• Maryland• New Jersey• Pennsylvania
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REL Mid-Atlantic Goals
• To help stakeholders, state and local education agencies, communities, and researchers:‒ Gain access to and use high-
quality research‒ Use research, data, and data
analysis to improve policy and practice
• To respond to high-priority education needs of the region
For more information: www.relmidatlantic.org
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Focus Questions for Today’s Session
• What challenges do the Next Generation Science Standards present for teaching and learning?
• What do we know about effective teacher professional development (PD)?
• How can an analysis-of-practice approach to PD challenge and contribute to our understandings of the consensus model of effective PD?
• How can future research on PD produce stronger understandings of what makes for effective science teacher learning opportunities?
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Today’s Presenter
• Director of Research at Science Education Curriculum Study (BSCS)
• Ongoing research focuses on measuring the effectiveness of educational interventions in science and how to develop and measure reasoning in science
• Current work includes the impacts of a year-long lesson-analysis-based PD program on teacher science content knowledge
• Recently awarded the JRST award for the most significant article published in 2013 by the Journal of Research in Science Teaching
• Previously a visiting assistant professor at the Center for Curriculum Materials in Science in the College of Education at Michigan State University
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BSCS MissionTo transform science teaching and learning through
research and development that strengthens learning environments and inspires a global community of scientifically literate citizens.
© 2016 BSCS
Previous Science Standards
Previous standards include:
• Benchmarks for Science Literacy from the American Association for the Advancement of Science (AAAS)1
• National Science Education Standards from the National Research Council (NRC)2
1American Association for the Advancement of Science, 19932National Research Council, 1996
Motivation for New Standards
Major advances in:• Science
National Academies Press, 2012
Motivation for New Standards
Major advances in:• Science• The teaching and learning of science
National Academies Press, 2012
Motivation for New Standards
Global Competitiveness Workforce Development Diversity in Science
Other Standards Initiatives Elevating Engineering Scientific Literacy
What Are the NGSS?
• The Next Generation Science Standards (NGSS) are based on the Framework for K-12 Science Education developed by the National Research Council (NRC)1
• The framework provides an evidence-based foundation for standards by drawing on current research on the ways students learn science effectively – and the science all K-12 students should know.
1National Academies Press, 2012
NGSS Partners
Developers and Authors
• 26 lead states• K-12 educators• Experts in:
• Science education• Students with disabilities• English language acquisition• State-level standards• Assessment• Workforce development
NGSS Adoption as of Feb. 2016
http://www.nasbe.org/project/next-generation-science-standards/
Three Dimensions of Learning
• Dimension 1. Science and Engineering Practices• Emphasis on engaging in scientific investigation
• Dimension 2: Cross-Cutting Concepts• Concepts that have applications across all domains
of science (e.g., patterns, causes and effect, stability and change)
• Dimension 3: Disciplinary Core Ideas• Must have broad importance and provide key tools
Next Generation Science Standards, 2013
Learning at the Nexus
Disciplinary Core Ideas
Science Practices
Cross-Cutting
Concepts
How do we ensure learning at the nexus?
Conceptual Shifts and the NGSS
1. K–12 science education should reflect the interconnected nature of science as it is practiced and experienced in the real world.
2. The NGSS are student performance expectations, NOT curriculum.
3. The science concepts in the NGSS build coherently from K–12.
4. The NGSS focus on deeper understanding and application of content.
5. Science and engineering are integrated in the NGSS, from K–12.
6. The NGSS are designed to prepare students for college, career, and citizenship.7. The NGSS and Common Core State Standards (English Language Arts and Mathematics) are aligned.
Which of these conceptual shifts represent the greatest challenges for you with respect
to teaching and learning?
Science ed. should reflect interconnected nature NGSS are student performance expectations The science concepts build coherently from K-12 NGSS focus on deeper understanding Science and engineering are integrated NGSS prepares students for college, career, etc. NGSS and CCSS are aligned
NGSS and Professional Development
• How can we support teachers in making these conceptual shifts and effectively implementing the NGSS?
Consensus Model of Effective Professional Development
(Yoon et al., 2007; Desimone, 2009; Wilson, 2013)
Effective Professional Development . . . • Focuses on specific subject matter content • Engages teachers in active learning • Is coherent (aligned with teachers’ prior
knowledge and beliefs; aligned with reform documents and school policy and practice)
• Is of sufficient duration• Involves the collective participation of teachers
(all teachers in a school, grade level, or dept.)
Research Supporting the Consensus Model
• Relies heavily on teacher self-report • Rarely looks at impact on student learning• When the research does look at student
learning, the results are mixed
Our Assertions
• The consensus model is not enough to guide the development of PD opportunities that will support the kinds of teacher change needed to help students reach the NGSS.
• Stronger lines of research on effective PD, especially in science education, are needed.
Science Teachers Learning from Lesson Analysis: STeLLA
STeLLA is:A one-year professional development program for elementary teachers in the context of videocase-based analysis of practice.
Science Teachers Learning from Lesson Analysis: STeLLA
STeLLA is:A cluster randomized trial of PD with strong findings.
Sample77 Schools
STeLLA42 Schools
Comp35 Schools
Science Teachers Learning from Lesson Analysis: STeLLA
STeLLA is:A 10+ year line of research on PD, involving studies:
• At elementary, middle, and high schools• Of in-service and preservice teachers• Of face-to-face and online PD• Across the NSF cycle of innovation• Of PD leadership development• At different scales, up to districtwide sustainability
STeLLA Line of Research
STeLLA 1 ViSTA ViSTA Plus
STeLLA 2 EMAT
RESPeCT STeLLA HS MN STeLLA
TIMSS Video Study
How People Learn
Lesson Analysis
STeLLA Design Features
• Engages teachers actively in collaborative, practice-based inquiries
• Treats content as central and intertwined with pedagogical issues
• Enables teachers to see these issues embedded in real classroom contexts
• Focuses on content and curriculum teachers will be teaching
• Guided by an articulated model of teacher learning and clear teacher learning goals
Describing the STeLLA Program
STeLLA Design Principles1. Theory of teacher learning2. Conceptual framework3. Program form4. Program resources
STeLLA Theory of Teacher Learning
STeLLA Theory of Teacher Learning
Program elements that embody this theory:1) Learning progression starting with highly scaffolded
experience moving towards greater independence 2) Experiences that create a “need to know” dissonance3) Use of experts who plan for and guide teacher learning
STeLLA Theory of Teacher Learning
Science Content
Knowledge
Pedagogical Content
Knowledge
Teaching Science
Analyzing Teaching and
Learning
ability touse in . . .
STeLLA Program Substance:STeLLA Conceptual Framework
and STeLLA Teaching Strategies
STeLLA Program Form
One academic year(~90 hours of PD)
Two-week summer institute
Monthly study group meetings
Small learning communities
Key STeLLA ComponentsVideo analysis tasks: Teachers analyze videocases from other teachers’ and each other’s classrooms
Videocases include: sequence of lesson
videos student and teacher
interview videos student written work student pre- and post-
tests
Key STeLLA ComponentsAnalysis of Practice Cycle and Norms
FOCUS ON STUDENT
THINKING AND SCIENCE CONTENT
STORYLINE
Lesson Analysis• Video of other teachers using
STeLLA strategies establish a common vision of the strategies and classroom possibilities.
• Video of participants teaching common lessons provide a rich initial experience to analyze each teacher’s enactment of the strategies.
Lesson Analysis Protocol
Analysis Guide D: Selecting and Using Content Representations
Main learning goal:_____________________________________________________ ____________________________________________________________________ Description of content representation:______________________________________ ____________________________________________________________________ Part 1: Selecting the content representation: Is the content representation … YES NO
1. Scientifically accurate?
2. Closely matched to the main learning goal?
3. Presenting science ideas in ways that are comprehensible to students?
4. Reinforcing or introducing student misconceptions?
5. Addressing common student misconceptions?
6. Distracting students from the main learning goal with too many details or new terms?
Part 2: Engaging students in using the content representation. Is the content representation used in a way that involves students in … YES NO
1. Modifying or creating the content representation?
2. Analyzing the meaning of the content representation?
3. Critiquing the content representation?
Part 3: Suggestions for improvement_____________________________________
STeLLA Lesson Plans
Student Pre- and Post-Tests
Features Analysis Charts
STeLLA Planning Tools
Content/PCK Background Readings
Common Student Ideas
Lesson Analysis: The Basics
• Viewing Basic #1: Look past the trivial, the little things that “bug” you.
• Viewing Basic #2: Avoid the “this doesn’t look like my classroom” trap.
• Viewing Basic #3: Avoid making snap judgments about the teaching or learning in the classroom you are viewing.
• Analysis Basic #1: Focus on student thinking and the science content storyline.
• Analysis Basic #2: Look for evidence to support any claims.
• Analysis Basic #3: Look more than once.
• Analysis Basic #4: Consider alternative explanations and teaching strategies.
Focus Question
• What does the teacher do to make student thinking visible?
What does research on STeLLA tell us?
STeLLA is:
A one-year professional development program for elementary teachers in the context of videocase-based analysis-of-practice.
STeLLA is also:
a Scale-Up Study
NSF DRK-12 Award
DRL-0918277
Population: 77 schools, 144 4th and 5th grade teachers of ~2800 students
Sample77 Schools
STeLLA42 Schools
Comp35 Schools
Treatments
STeLLALesson Analysis +
Content Deepening
88.5 hours(2-week summer institute
& monthly meetings)
COMPARISONContent Deepening
88.5 hours(2-week summer institute
& monthly meetings)
Same learning goals
Theory of Change and Outcome Measures
STeLLA Professional
Development Program
Teacher Science Content
Knowledge
Teacher Pedagogical
Content Knowledge
Student Science Content
Knowledge
Teaching Practice
Theory of Change and Outcome Measures
STeLLA Professional
Development Program
Teacher Science Content
Knowledge
Student Science Content
Knowledge
Teacher Pedagogical
Content Knowledge
Teaching Practice
Theory of Change and Outcome Measures
STeLLA Professional
Development Program
Teacher Science Content
KnowledgeStudent Science Content
KnowledgeTeacher Pedagogical
Content Knowledge
Teaching Practice
Results
Teacher Science Content
Knowledge
p<0.001Hedges’ g=0.66
Teaching Practice
p<0.001Hedges’ g=2.05
Teacher Pedagogical
Content Knowledge
p<0.001Hedges’ g=1.17
Student Science Content
Knowledge
p<0.001Hedges’ g=0.68
Student Effect
Student Science Content
Knowledge
Practical Significance
• ES = 0.68• Larger than average effect for elementary school
interventions with this type of outcome (avg. = 0.33)
• Nearly a two year advantage• 23 percentile points• Advantage in reasoning
Impact on Reasoning
• Easy item
FSPO7: In what order do a hawk, grass, and rabbit form a food chain in a meadow? A. Hawk Grass RabbitB. Grass Hawk RabbitC. Rabbit Grass HawkD. Grass Rabbit Hawk
Impact on Reasoning
• Difficult item
WSPO23: Which of the following statements about condensation is true?A. During condensation, water turns from a liquid to a gas.B. During condensation, energy is lost.C. During condensation, water gets heavier.D. During condensation, water is created.
Impact on Reasoning
• Items STeLLA students perform better on
SSPO11: Which position shows summer in Earth’s Southern Hemisphere?A. AB. BC. CD. D
FSPO6: The diagrams below show three food chains. Each food chain uses 100 pounds of green plants as a source of food. In which of the three food chains is the most energy available to people?
ESPO24: Which of the following figures best shows the location of the earth's tectonic plates?
Pedagogical Content Knowledge (Teacher)
(~20 minutes per video)
In Ms. Dieken's fifth grade class, students are trying to explain different scenarios that were provided to their groups (e.g., condensation on the outside of a cold soda can). The teacher instructs the groups to explain their respective scenarios in terms of evaporation, condensation, and water molecules.
View the clip below and then spend 5–10 minutes describing and analyzing anything you notice regarding the science content, the teaching, and/or the students. Explain the issues and/or questions that the video raised for you. Use complete sentences.
You can use the paper copy of the video transcript while you are watching. Looking at the transcript after you watch the video can help you review what you have just watched.
Please type your response in the box below.
Pedagogical Content Knowledge
Before Professional Development“There seemed like many students in the classroom as it was quite noisy. I thought that the teacher was helping the students a little too much to complete their sentences. When the teacher was trying to say something, the students kept interrupting and not letting her complete her sentences. However, the same thing was happening when the students were trying to say something. I thought that the students should be raising hands when they want to say something so that they might be able to share their ideas and listen to others to get more ideas. Since this was their 3rd lesson I would like to see how much they could explain things on their own, and then help them to complete what they are trying to explain.”
Pedagogical Content Knowledge
After Professional Development“The teacher in clip three engages students in activities that highlight science ideas and that are explicitly linked to science ideas. The teacher links weather, erosion, and deposition as processes that wear down the Earth’s surface. The main learning goal is apparent even if it is not directly stated. The main learning goal is weathering, erosion, deposition, and earthquakes are contributing factors that change the Earth’s surface. The teacher asks elicit, probing and paraphrasing, and challenge questions throughout the lesson to get a better understanding of student knowledge and to push their understanding further. More probing and challenge questions are asked in the group circle. Examples of challenge questions can be found at 49:41, 50:05, and 50:11. The activities including quick writing, peer sharing, and group sharing are linked to science ideas and also link science ideas to other science ideas in the discussions. The content representations are scientifically accurate and aid in students’ accurate understanding of the science ideas. The lesson is content rich including specific vocabulary and facts. Mr. Potter also does a great job synthesizing and summarizing at the end of the lesson.”
Impact on Practice
• Hardest to change• Teachers are using STeLLA strategies in the
classroom,not just in their science teaching
Next Steps
• Dissemination• Mediation analysis: folding in teacher PCK and teacher
practice measures to examine how teacher learning and practice predict student learning
• Moderation analysis with student demographics• Examining which STeLLA strategies were most
predictive of student learning • Studies in different contexts• Qualitative analyses• PD leader studies
STeLLA Contributes to Knowledge about Effective PD: Beyond the Consensus Model
• The PD program is guided by a theory of teacher learning.• The program substance is organized around a conceptual
framework.• Science content learning is intertwined with analysis of
practice.• Analytical tools and videocases support collaborative, deep
analysis of science teaching, student learning, and science content.
• There is an internal coherence of program form and substance.
• Learning is directed and scaffolded by knowledgeable PD leaders.
© 2015 BSCS
Conclusions
• The consensus model is not enough to guide the design of professional development opportunities that will support NGSS.
• The STeLLA line of research contributes to building a research-based model of effective PD—beyond the consensus model.
• More strong lines of research on effective PD are needed.
© 2015 BSCS
This material is based upon work supported, in part, by the National Science Foundation under Grants DRL-0918277. Any opinions, findings, and conclusions or recommendations expressed in this material are those of the author(s) and do not necessarily reflect the views of the National Science Foundation
Contact
Chris WilsonChristopher Wilson
Director of Research, BSCScwilson@bscs.org
Kasia RazynskaMaryland State Coordinator,
REL Mid-Atlantic krazynska@relmidatlantic.org