Projects

Schools and teachers face unprecedented challenges in meeting the ambitious goals of integrating core interdisciplinary science ideas with science and engineering practices as described in new standards. This project developed a middle school ecology unit and related teacher professional development to help high-need and urban middle school students, including English Language Learners, understand these ideas and related practices.

This project will research the development and application of new Next Generation curriculum exemplars for middle school science that align with the expectations of NGSS by (1) constructing diagnostic tools to assess the alignment of curricula; (2) using the tool for existing curricula in order to field test it; and (3) systematically investigating the effectiveness of the tool.

This project will develop, test, and refine a curriculum supplement (a hands-on technology) that (1) promotes childrens' understanding of number (counting, comparing, and ordering) and fair sharing (equipartitioning); (2) uses interactive media on an emerging handheld platform (touch screen tablets), integrating new multi-touch activities with existing hands-on activities; (3) enhances opportunities for learning with interactive media through shared use with adult guides and peers; and (4) provides professional and technical support materials for preschool educators.

This project is developing, iteratively refining and evaluating a science curriculum for Pre-K classrooms with units on Plant Growth, How Things Move, and What Makes Shadows by integrating traditional classroom resources (large and small group activities, hands-on activities, read-alouds) with digital media (touch screen tablets, photos and short videos, and games/simulations).

The purpose of this project is to create a research-based model of how students with learning disabilities (LDs) develop multiplicative reasoning via reform-oriented pedagogy; convert the model into a computer system that dynamically models every students’ evolving conceptions and recommends tasks to promote their advancement to higher level, standard-based multiplicative structures and operations; and study how this tool impacts student outcomes.

To support equitable access to place-based science learning opportunities, Maine Mathematics and Science Alliance in collaboration with BSCS Science Learning, will develop and test a model to support 3rd-5th grade teachers in incorporating locally or culturally relevant place-based phenomena into rigorously tested curricular units that meet the expectations of the NGSS. The project team will develop two units that could be used in any region across the country with built-in opportunities and embedded supports for teachers to purposefully adapt curriculum to include local phenomena. In-person and virtual professional learning experiences will further help teachers who have limited district support for science to incorporate place-based approaches. Participating teachers will range from rural and urban settings in California, Colorado, and Maine to ensure the end products of this project are relevant, scalable, appropriate for a wide range of students across the country.

This project is implementing a program of professional development for teachers and web interface that links scientists with urban classrooms. Scientist mentors work with students and teachers through the web to carry out an original "authentic" inquiry project in plant science. The classroom intervention involves high school biology students working in assigned teams to generate their own research questions in plant science centered on core biology concepts from the National Science Education Standards.

This project is initiating an innovative approach to pre-K students' development of quantitative reasoning through measurement. This quantitative approach builds on measurement concepts and algebraic design of the pre-numeric stage of instruction found in the Elkonin-Davydov (E-D) elementary mathematics curriculum from Russia. The project team is adapting and refocusing the conceptual framework and learning tasks of the E-D pre-numeric stage for use with four-year-olds.

The objective of this project is to develop a toolkit of resources and practices that will help inservice middle grades mathematics teachers support mathematical argumentation throughout the school year. A coherent, portable, two-year-long professional development program on mathematical argumentation has the potential to increase access to mathematical argumentation for students nationwide and, in particular, to address the needs of teachers and students in urban areas.

The purpose of Project Delta is two-fold: (1) to extend an existing library of 17 interacting CD-ROM digital learning environments on numbers and operations by adding an algebra strand, and (2) to evaluate the impact of the new algebra materials on teacher development. Each of the digital environments features classroom sessions that allow for exploration of a mathematics topic, children learning over time, and teachers? instructional techniques.

Project M² is producing and disseminating curriculum materials in geometry and measurement for students in grades K-2. This builds on success of the M³ U.S. Department of Education curriculum grant for students in Grades 3-5. (www.projectm3.org). Project M² units are advanced units for all students designed using research-based practices in mathematics, early childhood, and gifted education. Curricular materials focus on promising discourse and hands-on inquiry of rich problem-situations.  

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.

This project explores the potential for enhancing students' interest and ability in STEM disciplines by broadening fourth grade students' understanding and interest in the spatial perspectives inherent in geography and other science disciplines. The project tests a set of hypotheses that posit that the use of GIS in the classroom results in a measureable improvement in students' spatial reasoning and motivation.

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.

In this project, a video and audio network links elementary school teachers with researchers and educators at Purdue to form a community of practice dedicated to implementing engineering education at the elementary grades. The research plan includes identifying the attributes of face-to-face and cyber-enabled teacher professional development and community building that can transform teachers into master users and designers of engineering education for elementary learners.

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.

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.

This project will develop a Universal Design for Learning, project-based inquiry science program that includes virtual learning environments, virtual laboratories, and digital scaffolds and supports that promote scientific learning for incarcerated youth.

This project has two goals:

1) to discover methods that can efficiently obtain information about the effects of high school programs on eventual college success. Methods we are considering include obtaining transcripts from post-secondary institutions, surveying high school graduates, and obtaining information from the National Student Clearinghouse.

2) to explore how students who studied Contemporary Mathematics in Context (Core Plus) or the Integrated Mathematics Program (IMP) fare in post secondary institutions.

This project studies mathematics professional development leaders' understandings and practices associated with developing mathematically rich learning environments. It investigates this issue by considering: How can leaders cultivate professional development environments in which teachers have a greater opportunity to grapple with and deeply understand mathematics? The project studies how explicit attention to the cultivation of sociomathematical norms influences leaders' understanding of the process of creating mathematically rich environments and the impacts on their practices.

This project is focusing on the redesign of popular commercial video games to support students’ understanding of Newtonian mechanics. In support of this goal, SURGE develops and implements design principles for game-based learning environments, integrating research on conceptual change, cognitive processing-based design, and socio-cognitive scripting. These enhanced games bridge the gap between student learning in non-formal game environments and the formalized knowledge structures learned in school by leveraging and integrating the strengths of each.

The goals of STEM instruction are to educate a populace that is scientifically and mathematically literate and who can solve real-world problems by applying science and mathematics. This exploratory project is designed to study the effectiveness of professional development focused on the integration of mathematics and science instruction, mediated by technology tools, to improve middle school teachers' ability to teach scientific inquiry and mathematical problem solving.

Science in the Learning Gardens (SciLG) designs and implements curriculum aligned with Next Generation Science Standards (NGSS) and uses school gardens as learning contexts in grade 6 (2014-2015), grade 7 (2015-2016) and grade 8 (2016-2017) in two low-income urban schools. The project investigates the extent to which SciLG activities predict students’ STEM identity, motivation, learning, and grades in science using a theoretical model of motivational development.

This project is developing and implementing a rigorous eighth grade physical science program that utilizes engineering design, LEGO™ robotics and mechanics, and a problem-based learning approach to teach mechanics, waves, and energy.

This project aims to develop, pilot, and evaluate a model of instruction that advances the scientific literacy of high school students by involving them in science journalism, and to develop research tools for assessing scientific literacy and engagement. We view scientific literacy as public understanding of and engagement with science and technology, better enabling people to make informed science-related decisions in their personal lives, and participate in science-related democratic debates in public life.