Standards

Supporting Teachers in Responsive Instruction for Developing Expertise in Science (Collaborative Research: Linn)

This project takes advantage of advanced technologies to support science teachers to rapidly respond to diverse student ideas in their classrooms. Students will use web-based curriculum units to engage with models, simulations, and virtual experiments to write multiple explanations for standards-based science topics. The project will also design planning tools for teachers that will make suggestions relevant research-proven instructional strategies based on the real-time analysis of student responses.

Partner Organization(s): 
Award Number: 
1813713
Funding Period: 
Sat, 09/01/2018 to Wed, 08/31/2022
Full Description: 

Many teachers want to adapt their instruction to meet student learning needs, yet lack the time to regularly assess and analyze students' developing understandings. The Supporting Teachers in Responsive Instruction for Developing Expertise in Science (STRIDES) project takes advantage of advanced technologies to support science teachers to rapidly respond to diverse student ideas in their classrooms. In this project students will use web-based curriculum units to engage with models, simulations, and virtual experiments to write multiple explanations for standards-based science topics. Advanced technologies (including natural language processing) will be used to assess students' written responses and summaries their science understanding in real-time. The project will also design planning tools for teachers that will make suggestions relevant research-proven instructional strategies based on the real-time analysis of student responses. Research will examine how teachers make use of the feedback and suggestions to customize their instruction. Further we will study how these instructional changes help students develop coherent understanding of complex science topics and ability to make sense of models and graphs. The findings will be used to refine the tools that analyze the student essays and generate the summaries; improve the research-based instructional suggestions in the planning tool; and strengthen the online interface for teachers. The tools will be incorporated into open-source, freely available online curriculum units. STRIDES will directly benefit up to 30 teachers and 24,000 students from diverse school settings over four years.

Leveraging advances in natural language processing methods, the project will analyze student written explanations to provide fine-grained summaries to teachers about strengths and weaknesses in student work. Based on the linguistic analysis and logs of student navigation, the project will then provide instructional customizations based on learning science research, and study how teachers use them to improve student progress. Researchers will annually conduct at least 10 design or comparison studies, each involving up to 6 teachers and 300-600 students per year. Insights from this research will be captured in automated scoring algorithms, empirically tested and refined customization activities, and data logging techniques that can be used by other research and curriculum design programs to enable teacher customization.


 Project Videos

2021 STEM for All Video Showcase

Title: Web-based Personalized Science Units Empowering Anti-Racism

Presenter(s): Marcia Linn, Sarah Bichler, Kelly Billings, Allison Bradford, Libby Gerard, Rui Li, & Jonathan Lim-Breitbart

2020 STEM for All Video Showcase

Title: STRIDES: Customizing Online Curricula for Distance Learning

Presenter(s): Libby Gerard, Sarah Bichler, Phillip Boda, Allison Bradford, Emily Harrison, Jennifer King Chen, Jonathan Lim-Breitbart, Marcia Linn, & Korah Wiley


Building Middle School Students' Understanding of Heredity and Evolution

This project will develop and test the impact of heredity and evolution curriculum units for middle school grades that are aligned with the Next Generation Science Standards (NGSS). The project will advance science teaching by investigating the ways in which two curriculum units can be designed to incorporate science and engineering practices, cross-cutting concepts, and disciplinary core ideas, the three dimensions of science learning described by the NGSS. The project will also develop resources to support teachers in implementation of the new modules.

Lead Organization(s): 
Award Number: 
1814194
Funding Period: 
Sat, 09/01/2018 to Wed, 08/31/2022
Full Description: 

This project will develop and test the impact of heredity and evolution curriculum units for middle school grades that are aligned with the Next Generation Science Standards (NGSS). The project will advance science teaching by investigating the ways in which two curriculum units can be designed to incorporate science and engineering practices, cross-cutting concepts, and disciplinary core ideas, the three dimensions of science learning described by the NGSS. The project will also develop resources to support teachers in implementation of the new modules. The planned research will also examine whether student understanding of evolution depends on the length and time of exposure to learning about heredity prior to learning about evolution.

This Early Stage Design and Development project will develop two new 3-week middle school curriculum units, with one focusing on heredity and the other focusing on evolution. The units will include embedded formative and summative assessment measures and online teacher support materials. These units will be developed as part of a curriculum learning progression that will eventually span the elementary grades through high school. This curriculum learning progression will integrate heredity, evolution, data analysis, construction of scientific explanations, evidence-based argumentation, pattern recognition, and inferring cause and effect relationships. To inform development and iterative revisions of the units, the project will conduct nation-wide beta and pilot tests, selecting schools with broad ranges of student demographics and geographical locations. The project will include three rounds of testing and revision of both the student curriculum and teacher materials. The project will also investigate student understanding of evolution in terms of how their understanding is impacted by conceptual understanding of heredity. The research to be conducted by this project is organized around three broad research questions: (a) In what ways can two curriculum units be designed to incorporate the three dimensions of science learning and educative teacher supports to guide students' conceptual understanding of heredity and evolution? (b) To what extent does student understanding of evolution depend on the length and timing of heredity lessons that preceded an evolution unit? And (c) In what ways do students learn heredity and evolution?

An Integrated Approach to Early Elementary Earth and Space Science

This project will study if, how, and under what circumstances an integration of literacy strategies, hands-on inquiry-based investigations, and planetarium experiences supports the development of science practices (noticing, recognizing change, making predictions, and constructing explanations) in early elementary level students. The project will generate knowledge about how astronomy-focused storybooks, hands-on investigations, and planetarium experiences can be integrated to develop age-appropriate science practices in very young children.

Award Number: 
1813189
Funding Period: 
Sat, 09/01/2018 to Mon, 08/31/2020
Full Description: 

State science standards increasingly emphasize the importance of engaging K-12 students directly in natural phenomena and providing opportunities to construct explanations grounded in evidence. Moreover, these state science standards introduce earth and space science content in the early elementary grades. This creates a critical need for new pedagogies, materials, and resources for science teachers in all grades, but the need is particularly urgent in grades K-3 where teachers have had little preparation to teach science, let alone astronomy. There is also growing consensus that when learning opportunities in formal and informal settings are closely aligned, children's science literacy is developed in ways greater than either setting can achieve alone. The investigators will study if, how, and under what circumstances an integration of literacy strategies, hands-on inquiry-based investigations, and planetarium experiences supports the development of science practices (noticing, recognizing change, making predictions, and constructing explanations) in early elementary level students. This project will generate knowledge about how astronomy-focused storybooks, hands-on investigations, and planetarium experiences can be integrated to develop age-appropriate science practices in very young children (noticing, recognizing change, making predictions, and constructing explanations).

Emergent research on the development of children's science thinking indicates that when young children are engaged with science-focused storybooks and activities that each highlight the same phenomenon, children notice and gather evidence, make predictions and claims based on evidence, and provide explanations grounded in the experiences provided to them. This project has two phases. In Phase 1, first and third grade teachers will be recruited. They will help identify specific learner needs as these relate to the earth and space science standards in their grade band, assist in the development and pilot testing of a prototype instructional sequence and supporting activities taking place within their classrooms and at a local planetarium. In Phase 2, the revised learning sequence and research protocol will be implemented with the same teachers and a new cohort of children. The mixed method research design includes video observations, teacher interviews, and teacher and student surveys. Data analysis will focus on science practices, connections across contexts (e.g., school and planetarium), and instructional adaptations. The project involves a research-practice collaboration between the Astronomical Society of the Pacific, Rockman & Associates, the Lawrence Hall of Science at the University of California, Berkeley, and West Chester University.


Project Videos

2020 STEM for All Video Showcase

Title: Chasing Shadows and Eating the Moon

Presenter(s): Brian Kruse, Kristin Bass, John Erickson, Julia Plummer, Karen Schwarz, Linda Shore, & Theresa Summer


Promoting Engineering Problem Framing Skill-Development in High School Science and Engineering Courses

This project will develop curricular activities and assessment guidance for K-12 science and engineering educators who seek to incorporate engineering design content into their biology, chemistry, and physics classes.

Lead Organization(s): 
Partner Organization(s): 
Award Number: 
1812823
Funding Period: 
Wed, 08/01/2018 to Sat, 07/31/2021
Full Description: 

This collaborative project involving Ohio Northern University, Ohio State University, and Olathe Northwest High School will develop curricular activities and assessment guidance for K-12 science and engineering educators who seek to incorporate engineering design content into their biology, chemistry, and physics classes. This work is important because students' limited exposure to engineering activities can negatively impact their decisions to enroll in STEM courses and to pursue engineering careers. Further, many states are adopting or considering adopting the Next Generation Science Standards (NGSS), a set of classroom standards which integrate engineering content into traditional science disciplines. While high school teachers under these standards are expected to incorporate the cross-cutting engineering content into their courses, they generally receive little high-quality support for doing so. If successful, the project could provide a powerful model of how to support busy and resource-constrained STEM teachers, and create broader student interest in STEM careers.

Drawing from best practices on instructional design, the project's main objectives are to: (1) design, field-test, and evaluate the impact of 12 NGSS-aligned, engineering problem-framing design activities on students enrolled in grades 9-12 science courses and (2) design and conduct high-quality, sustained professional development that fosters participating high school science teachers' ability to deploy the NGSS concepts-linked activities. Data sources include student design artifacts, video of classroom instruction, and surveys assessing student and teacher attitudes toward engineering, student design self-efficacy and teacher self-efficacy for teaching engineering content. These data will be analyzed to determine what teachers learned from the professional development activities, how those activities informed their teaching and in turn, how students' engagement with the engineering activities relates to their engineering design skills and attitudes. In terms of intellectual merit, the project aims to develop a learning progression of students' engineering design problem-framing skills by characterizing any observed change in students' design work and attitudes over time.

Testing the Efficacy of the Strategic Observation and Reflection (SOAR) for Math Professional Learning Program

The purpose of this project is to develop, implement and test a professional development program, SOAR for Math, to build capacity for mentors and teachers to improve English learner's academic language development and mathematical content understanding.

Award Number: 
1814356
Funding Period: 
Sat, 09/01/2018 to Wed, 08/31/2022
Full Description: 
Professional development is an important way for teachers who are currently in classrooms to learn about new best practices in mathematics teaching and learning and improve their practice. Little is known about what types of professional development (PD) and teacher mentoring programs support teachers' improved practices and ultimately lead to gains in student learning. The purpose of this project is to develop, implement and test a professional development program, SOAR for Math, to build capacity for mentors and teachers to improve English learner's academic language development and mathematical content understanding.
 
This study will test the efficacy of the Strategic Observation and Reflection (SOAR) for Math professional development program. The mixed methods study is designed to answer several research questions: (1) What is the impact of teachers' participation in SOAR for Math on student achievement outcomes for current and recent grade 3-6 English learner students in treatment schools? (2) What is the impact of SOAR for Math on treatment school teachers' knowledge and practices related to their academic language and literacy development instruction for current and recent English learner students, specifically scores on the Knowledge/Use Scale? (3) What is the impact of SOAR for Math on treatment mentors' knowledge and practices related to their academic language and math instruction? A randomized controlled trial will be conducted in 80 elementary schools in one California school district. Schools serving third- through sixth-grade general education students will be eligible to participate. The research team will randomly assign 40 schools to provide SOAR for Math training to mentor teachers and 40 schools to comprise a control group receiving business-as-usual professional development. Two mentors per school will participate in the study. Measures will include state math scores and a variety of observations and questionnaires to assess fidelity of implementation. Data will be analyzed using hierarchical linear modeling to account for the nested data structure.

Design and Development of Transmedia Narrative-based Curricula to Engage Children in Scientific Thinking and Engineering Design (Collaborative Research: Ellis)

This project will address the need for engineering resources by applying an innovative pedagogy called Imaginative Education (IE) to create middle school engineering curricula. In IE, developmentally appropriate narratives are used to design learning environments that help learners engage with content and organize their knowledge productively. This project will combine IE with transmedia storytelling.

Lead Organization(s): 
Award Number: 
1814033
Funding Period: 
Sun, 07/15/2018 to Thu, 06/30/2022
Full Description: 

Engineering is an important component of the Next Generation Science Standards (NGSS). However, resources for supporting teachers in implementing these standards are scarce. This project will address the need for resources by applying an innovative pedagogy called Imaginative Education (IE) to create middle school engineering curricula. In IE, developmentally appropriate narratives are used to design learning environments that help learners engage with content and organize their knowledge productively. To fully exploit the potential of this pedagogy, this project will combine IE with transmedia storytelling. In transmedia storytelling, different elements of a narrative are spread across a variety of formats (such as books, websites, new articles, videos and other media) in a way that creates a coordinated experience for the user. Once created, the curricula will be implemented in classrooms to research its impact on (1) increasing learners' capacities to engage in both innovative and direct application of engineering concepts, and (2) improving learners' science, technology, engineering, and mathematics (STEM) identity. 

This research will be led by Smith College and Springfield Technical Community College in collaboration with Springfield (MA) Public Schools (SPS). Additional expertise in evaluating the findings will be provided by the Collaborative for Educational Services and an external advisory board of leaders in STEM education and transmedia storytelling. The project will result in the development of a transmedia learning environment that includes two NGSS-aligned, interdisciplinary engineering units and seven lessons that integrate science and engineering. The research study will be implemented in four phases in eight SPS middle schools. Approximately 900 students will participate each year. In Phase 1, the project team will collaborate with SPS teachers to create engineering units, lessons, and standards-based achievement measures. In Phase 2, teachers in the treatment group will participate in professional development (PD) workshops covering IE, transmedia learning environments, structure of the curriculum, and connections to NGSS. In Phase 3 the curricula will be implemented in treatment classrooms and both treatment and control group students will be assessed. In Phase 4, testing and assessment will continue in SPS schools and will be expanded to rural and suburban classrooms. Teachers in these classrooms will use online multimedia PD that will ensure scalability and mirrors the structure and content of in-person PD. Data analysis will provide evidence of whether this imaginative and transmedia educational approach improves students' capacities for using engineering concepts and enhances their STEM identity.


Project Videos

2020 STEM for All Video Showcase

Title: Transforming Engineering Education for Middle Schools (TEEMS)

Presenter(s): Isabel Huff, Kaia Cormier, Glenn Ellis, Sonia Ellis, Crystal Ford, Kate Lytton, Becky Mazur, Beth McGinnis-Cavanaugh, Jeremy Pina, & Al Rudnitsky

2019 STEM for All Video Showcase

Title: Transforming Engineering Education for Middle School (TEEMS)

Presenter(s): Beth McGinnis-Cavanaugh, Sonia Ellis, & Crystal Ford


Design and Development of Transmedia Narrative-based Curricula to Engage Children in Scientific Thinking and Engineering Design (Collaborative Research: McGinnis-Cavanaugh)

This project will address the need for engineering resources by applying an innovative pedagogy called Imaginative Education (IE) to create middle school engineering curricula. In IE, developmentally appropriate narratives are used to design learning environments that help learners engage with content and organize their knowledge productively. This project will combine IE with transmedia storytelling.

Partner Organization(s): 
Award Number: 
1813572
Funding Period: 
Sun, 07/15/2018 to Thu, 06/30/2022
Project Evaluator: 
Collaborative for Educational Services (CES)
Full Description: 

Engineering is an important component of the Next Generation Science Standards (NGSS). However, resources for supporting teachers in implementing these standards are scarce. This project will address the need for resources by applying an innovative pedagogy called Imaginative Education (IE) to create middle school engineering curricula. In IE, developmentally appropriate narratives are used to design learning environments that help learners engage with content and organize their knowledge productively. To fully exploit the potential of this pedagogy, this project will combine IE with transmedia storytelling. In transmedia storytelling, different elements of a narrative are spread across a variety of formats (such as books, websites, new articles, videos and other media) in a way that creates a coordinated experience for the user. Once created, the curricula will be implemented in classrooms to research its impact on (1) increasing learners' capacities to engage in both innovative and direct application of engineering concepts, and (2) improving learners' science, technology, engineering, and mathematics (STEM) identity. 

This research will be led by Smith College and Springfield Technical Community College in collaboration with Springfield (MA) Public Schools (SPS). Additional expertise in evaluating the findings will be provided by the Collaborative for Educational Services and an external advisory board of leaders in STEM education and transmedia storytelling. The project will result in the development of a transmedia learning environment that includes two NGSS-aligned, interdisciplinary engineering units and seven lessons that integrate science and engineering. The research study will be implemented in four phases in eight SPS middle schools. Approximately 900 students will participate each year. In Phase 1, the project team will collaborate with SPS teachers to create engineering units, lessons, and standards-based achievement measures. In Phase 2, teachers in the treatment group will participate in professional development (PD) workshops covering IE, transmedia learning environments, structure of the curriculum, and connections to NGSS. In Phase 3 the curricula will be implemented in treatment classrooms and both treatment and control group students will be assessed. In Phase 4, testing and assessment will continue in SPS schools and will be expanded to rural and suburban classrooms. Teachers in these classrooms will use online multimedia PD that will ensure scalability and mirrors the structure and content of in-person PD. Data analysis will provide evidence of whether this imaginative and transmedia educational approach improves students' capacities for using engineering concepts and enhances their STEM identity.


Project Videos

2020 STEM for All Video Showcase

Title: Transforming Engineering Education for Middle Schools (TEEMS)

Presenter(s): Isabel Huff, Kaia Cormier, Glenn Ellis, Sonia Ellis, Crystal Ford, Kate Lytton, Becky Mazur, Beth McGinnis-Cavanaugh, Jeremy Pina, & Al Rudnitsky

2019 STEM for All Video Showcase

Title: Transforming Engineering Education for Middle School (TEEMS)

Presenter(s): Beth McGinnis-Cavanaugh, Sonia Ellis, & Crystal Ford


Developing a Generalized Storyline that Organizes the Supports for Evidence-based Modeling of Long-Term Impacts of Disturbances in Complex Systems

This project will support students to develop evidence-based explanations for the impact of disturbances on complex systems.

Lead Organization(s): 
Award Number: 
1813802
Funding Period: 
Sun, 07/15/2018 to Thu, 06/30/2022
Full Description: 

This project will support students to develop evidence-based explanations for the impact of disturbances on complex systems. The project will focus on middle school environmental science disciplinary core ideas in life, Earth, and physical sciences. There are a wide variety of complex systems principles at work in disturbance ecology. This project serves as a starting point on supporting students to coordinate different sources of information to parse out the direct and indirect effects of disturbances on components of a system and to examine the interconnections between components to predict whether a system will return to equilibrium (resilience) or the system will change into a new state (hysteresis). These same complex systems principles can be applied to other scientific phenomena, such as homeostasis and the spread of infectious disease. This project will bring the excitement of Luquillo Long Term Ecological Research (LTER) to classrooms outside of Puerto Rico, and has a special emphasis on low performing, low income, high minority schools in Chicago. Over 6000 students will directly benefit from participation in the research program. The units will be incorporated into the Journey to El Yunque web site for dissemination throughout Chicago Public Schools (CPS) and the LTER network. The units will be submitted for review at the Achieve network, thus extending the reach to teachers around the country. The project will impact science teachers and curriculum designers through an online course on storyline development. This project aims to improve students' ability to engage in argument from evidence and address what the literature has identified as a significant challenge, namely the ability to evaluate evidence. Researchers will also demonstrate how it is possible to make progress on implementing Next Generation Science Standards in low performing schools. Through the web-based platform, these results can be replicated across many other school districts.

Researchers will to use the scientific context of the LTER program to develop a generalized storyline template for using evidence-based modeling to teach basic principles of disturbance ecology. Though a co-design process with middle school teachers in CPS, researchers will test the application of learning principles to a generalized storyline template by developing and evaluating three units on disturbance ecology - one life science, one Earth system science, and one physical science. Through a task analysis, researchers have identified three key areas of support for students to be successful at explaining how a system will respond to a disturbance. First, students need to be able to record evidence in a manner that will guide them to developing their explanation. Causal model diagrams have been used successfully in the past to organize evidence, but little is known about how students can use their causal diagrams for developing explanations. Second, there have been a wide variety of scaffolds developed to support the evaluation of scientific arguments, but less is known about how to support students in organizing their evidence to produce scientific arguments. Third, evidence-based modeling and scientific argumentation are not tasks that can be successfully accomplished by following a recipe. Students need to develop a task model to understand the reason why they are engaged in a particular task and how that task will contribute to the primary goal of explanation.

Extending and Investigating the Impact of the High School Model-based Educational Resource (Collaborative Research: Passmore)

This project builds on a line of work that has developed and studied the Model Based Educational Resource (MBER), a year-long curriculum for high school biology. The project will generate rigorous causal evidence on how this approach to biology teaching and learning can support student learning, and foundational information on how to support high school teachers in improving their teaching. It will also provide resources to expand and update MBER to reflect the changing high school science landscape by integrating Earth Science standards into the year long sequence.

Partner Organization(s): 
Award Number: 
1814263
Funding Period: 
Wed, 08/01/2018 to Sun, 07/31/2022
Full Description: 

This project builds on a line of work that has developed and studied the Model Based Educational Resource (MBER), a year-long curriculum for high school biology. In classrooms using MBER, modeling serves as an anchoring practice that keeps the inquiry tied to the goal of making sense of the world, helping teachers to engage their students in a range of cognitive and social activities that lead to deep understanding of scientific ideas. This project will generate rigorous causal evidence on how this approach to biology teaching and learning can support student learning, and foundational information on how to support high school teachers in improving their teaching. This funding will also provide resources to expand and update MBER to reflect the changing high school science landscape by integrating Earth Science standards into the year long sequence. The study will address the general research question: What is the impact of the Model Based Educational Resource (MBER) on high school students' science achievement, and what factors influence that impact? In addition to generating important research findings, the materials revised and studied in this project will be open-source and freely available to teachers and schools.

This study addresses a significant gap in the research on next generation curriculum materials. While there is emerging agreement about the importance of instructional materials in supporting teachers in effectively engaging students in the practices of science, there is very little empirical evidence to support such claims. The goal of this project is to study the impact of the MBER program through a cluster randomized trial and expand the promise of efficacy and feasibility established in previous work. This study will be able to make causal claims by using an experimental design in which 32 high school teachers serve as their own controls, and by using multi-level modeling in the analysis. This study will advance the field's knowledge about the impact of innovative materials on student learning, measured by both project-level assessments and the state science test. Exploratory research questions will examine a) how using the MBER program develops teachers' vision of the Next Generation Science Standards, b) how student learning is mediated by the fidelity of implementation of the materials, c) how teachers interact with materials designed to be modified for their classroom context, and d) to what extent the MBER materials provide equitable opportunities to learn and close achievement gaps.

Science Communities of Practice Partnership

This project will study implementation of an effective professional learning model for elementary science teachers that includes teacher leaders, administrators and university educators in a system perspective for improving science instruction in ways that make it sustainable.

Award Number: 
1813012
Funding Period: 
Wed, 08/01/2018 to Sun, 07/31/2022
Full Description: 

This project will study implementation of an effective professional learning model for elementary science teachers that includes teacher leaders, administrators and university educators in a system perspective for improving science instruction in ways that make it sustainable. The working model involves reciprocal communities of practice, which are groups of teachers, leaders and administrators that focus on practical tasks and how to achieve them across these stakeholder perspectives. The project will provide evidence about the specific components of the professional development model that support sustainable improvement in science teaching, will test the ways that teacher ownership and organizational conditions mediate instructional change, and will develop four tools for facilitating the teacher learning and the accompanying capacity building. In this way, the project will produce practical knowledge and tools necessary for other school districts nationwide to create professional learning that is tailored to their contexts and therefore sustainable.

This study posits that communication among district teachers, teacher leaders, and administrators, and a sense of ownership for improved instruction among teachers can support sustainable change. As such, it tests a model that fosters communication and ownership through three reciprocal communities of practice--one about district leadership including one teacher per school, coaches and university faculty; another about lesson study including teachers, coaches and faculty; and a third about instructional innovation including teachers and administrators, facilitated by coaches. The research design seeks to inform what the communities of practice add to the effects in a quasi-experimental study involving 72 third to fifth grade teachers and 6500 students in four urban school districts. Mixed methodologies will be used to examine shifts in science teaching over three years, testing the professional development model and the mediating roles of reform ownership and organizational conditions.

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