Although science is increasingly recognized as a key dimension of early learning, findings to date indicate that young children, especially those enrolled in public preschool programs serving historically excluded communities, have limited opportunities to engage in high quality science investigations. The lack of professional learning resources available to teachers makes it challenging for them to feasibly and effectively promote science in their classrooms. To address this need, this four-year design and development project brings together public preschool teachers, families from culturally and linguistically diverse communities, early learning and STEM researchers, and designers of media to co-design a Professional Learning Hub for Early Science.
Projects
Scientific sensemaking is core to learning and doing science. Oral and written language, visual and numerical representations, physical models, and other forms of communication are vital to scientific sensemaking, yet research has not yet fully explored how science curricula can be customized to account for the unique communicative repertoires of individual learners within elementary science classes. This project will address this important gap in practice by developing a suite of tools that elementary teachers can use to customize existing open-source, standards-aligned science curricula, such that these curricula are better able to support students with a range of communicative strengths, including multilingualism.
Scientific sensemaking is core to learning and doing science. Oral and written language, visual and numerical representations, physical models, and other forms of communication are vital to scientific sensemaking, yet research has not yet fully explored how science curricula can be customized to account for the unique communicative repertoires of individual learners within elementary science classes. This project will address this important gap in practice by developing a suite of tools that elementary teachers can use to customize existing open-source, standards-aligned science curricula, such that these curricula are better able to support students with a range of communicative strengths, including multilingualism.
Progress in science is motivated and directed by uncertainties. Yet even though uncertainty is a crucial fulcrum for scientific thought, school students are taught science within an overarching assumption that scientific knowledge is certain. This project explores the intellectual leverage of enabling middle school students to experience how scientific work grapples with uncertainty. The overall goal of this project is to understand how teachers can create equitable learning environments for culturally and linguistically diverse learners using Student Uncertainty for Productive Struggle as a pedagogical model in middle school science classrooms.
The project is studying the impact of the mathematics and science intensive pre-service preparation program for elementary school teachers. The project includes assessments of pre-service teachers' math and science content, teacher performance, self-report surveys, and teacher interviews. Each of the study dimensions (Knowledge Dimension, Teaching Performance, and Perspectives on the Program) will be assessed at three time points across this longitudinal study, providing a model for elementary teacher development of STEM teaching.
This project studies the influence of a professional development program on teachers' PCK and the related impact of PCK on student learning .The proposal team will design and deliver a professional development program for science teachers that is based on the use of curriculum materials, professional development, integrates efforts to improve secondary science teachers' content knowledge, pedagogical knowledge and skill, and helps them to apply this knowledge to the context of their own classroom.
This project identifies pivotal experiences of career science teachers that have promoted their advancement along the teacher professional continuum. The goal of the project is to develop an instrument that informs researchers about professional development opportunities that successful, empowered science teachers recall as having impacted their teaching and their overall sense of professionalism. The project is using a methodology in which teachers draw behavior over time graphs while telling their stories of empowerment.
The project plans to develop and study a series of metacognitive strategies that support learning and engagement for struggling middle school students during makerspace experiences. The study will focus narrowly on establishing a foundational understanding of how to ameliorate barriers to engaging in design learning through the use of metacognitive strategies. The project plans to translate and apply research on the use of metacognitive strategies in supporting struggling learners to develop approaches that teachers can implement to increase opportunities for students who are the most difficult to reach academically.
This study examines a pre-service model for preparing minority students to teach upper elementary/middle level science. The treatment consists of (1) recruitment efforts by collaborating universities; (2) a pre-service science content course (3) internship in an after school program serving minority students; (4) field placements in minority-serving development schools; and (5) mentoring during the induction year.
The website includes an innovative qualitative methodology using drawings as data and offers lesson plans and an action research guide for teachers.
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.
This project will support a conference series, including an in-person gathering and virtual follow-up meetings, that will bring together teachers, researchers, education leaders, and instructional material designers to build a shared understanding of how to integrate the use of high-quality instructional materials with the benefits of localizing these materials to better address students’ contexts and backgrounds. By fostering dialogue, sharing models, and setting priorities for future research and design, the project seeks to build knowledge about inclusive, effective, and culturally responsive approaches to science instruction that will advance equitable science education in K–12 classrooms.
This effectiveness study focuses on the scale-up of a model of curricular and teacher professional development intervention aimed at improving science achievement of all students, especially English language learners (ELLs). The model consists of three basic components: (a) inquiry-oriented science curriculum, (b) teacher professional development for science instruction with these students, and (c) school resources for science instruction.
Project staff are examining and improving elementary school teachers’ knowledge, beliefs, and practices involving their teaching of science to English language learners (ELL) within the policy context of high-stakes testing and accountability in science. The four major research and development areas are (1) teachers’ initial knowledge, beliefs, and practices; (2) professional development intervention; (3) policy contexts; and (4) change over time in teachers and ELL students.
The purpose of this project is to design and empirically evaluate a second grade science program, Scientific Explorers, aimed at promoting an early foundation for learning science among all students, including students at risk for or with learning disabilities in reading and mathematics. To support students as they engage in scientific tasks associated with Earth's Systems, this project will engineer the Scientific Explorers program around a guided inquiry framework, and develop and empirically validate a science assessment that measures students' knowledge and application of core science concepts and practices related to Earth's Systems.
The PuM project develops and conducts research on a learning continuum for seamless instruction in middle school physical science and high school physics. The ultimate goal is to use physics as the context to develop mathematics literacy, particularly with students from underrepresented populations and special needs students. The research component analyzes the effects of the curriculum on students' learning while simultaneously investigating teachers' pedagogical content knowledge in a variety of forms.
This project will examine the relationship between teacher professional development associated with newly developed modules in urban ecology and the achievement and engagement of long-term English learners (LTEL). Existing Urban Ecology learning modules will be enhanced to accommodate the needs of LTELs, and teachers will participate in professional development aimed at using the new materials to effectively integrate academic science discourse and literacy development for LTELs.
This project will study learning associated with elementary teachers' engagement in professional learning and elementary students' learning related to quantum science, quantum thinking, and careers. The knowledge base required for elementary teachers and students to learn quantum will be identified in order to explore and compare how elementary students and teachers conceptualize and make sense of quantum science concepts.
This project partners high school science teachers and students with particle physicists working in experiments at the scientific frontier. These experiments are searching for answers to fundamental questions about the origin of mass, the dimensionality of spacetime and the nature of symmetries that govern physical processes. Among the experimental projects at the energy frontier with which the project is affiliated is the Large Hadron Collider, which is poised at the horizon of discovery.
This project is examining an innovative model of situated Professional Development (PD) and the contribution of controlled teaching experiences to teacher learning and, as a result, to student learning. The project is carrying out intensive research about an existing special PD summer institute (QuEST) that has been in existence for more than five years through a state Improving Teacher Quality Grants program.
This project anticipates the needs of learners in 10 years by developing and testing two learning simulations that are immersive, interactive, and participatory and use augmented reality in the outdoors. Students work in teams to investigate phenomena and solve problems in a gaming environment using wireless handheld GPS units. Using a design-based, mixed-methods approach, the researchers examine the relationships among augmented reality, learning in science, socio-emotional outcomes, and the demographic characteristics of rural, underserved students.
This workshop convenes leading practitioners and scholars of innovation to collectively consider how education in the US might be reconfigured to both support and teach innovation as a core curriculum mission, with a focus on STEM education. Workshop participants identify and articulate strategies for creating and sustaining learning environments that promise the development of innovative thinking skills, behaviors and dispositions and that reward students, faculty and administrator for practicing and tuning these skills.
This project brings together leaders in simulation design and accessibility to develop and study interactive science simulations for diverse middle school students including those with sensory, mobility, or learning disabilities. The resulting simulations and research findings will help to address the significant disparity that exists between the achievement in science by students with and without disabilities.
This project is creating age-appropriate physical science curriculum that uses balls rolling on student-constructed ramps for children age 3-8 years. Students are expected to develop practical understanding of the movement of objects along ramps and pathways that leads to knowledge about concepts of forces and motion. They will improve their ability to engage in scientific inquiry and solve engineering problems related to ramp structures, and develop positive attitudes about science and themselves as science learners.
This project is developing 24 activities that span three years of a Physics high school science curriculum. The activities cover four themes: motion and energy, charge, structure, and light. This study aims to determine the extent to which exposure to these activities in one year influences performance on activities in a subsequent year and the extent to which students can recall concepts from prior years and apply them to new activities in a different discipline.
Building upon prior research on Head Start curriculum, this phase of Readiness through Integrative Science and Engineering (RISE) will be expanded to include classroom coaches and community experts to enable implementation and assessment of RISE in a larger sample of classrooms. The goal is to improve school readiness for culturally and linguistically diverse, urban-residing children from low-income families, and the focus on science, technology, and engineering will address a gap in early STEM education.