Projects

Understanding Science provides an accurate portrayal of the nature of science and tools for teaching associated concepts. This project has at its heart a public re-engagement with science that begins with teacher preparation. To this end, its immediate goals are (1) improve teacher understanding of the nature of the scientific enterprise and (2) provide resources and strategies that encourage and enable K-16 teachers to incorporate and reinforce the nature of science throughout their science teaching.

This project is developing a set of instructional materials that engages students and teachers in the science of coupled natural human (CNH) systems. Teacher guides, a website and multimedia resources accompany the four student modules (which focus on an urban watershed, an urban/agricultural system, Amazonia and a polar system).

This project is developing a system for producing automated professional mentoring while students play computer games based on STEM professions. The project explores a specific hypothesis about STEM mentoring: A sociocultural model as the basis of an automated tutoring system can provide a computational model of participation in a community of practice, which produces effective professional feedback from nonplayercharacters in a STEM learning game.

This project is designed to enhance an existing interdisciplinary high school science curriculum—Astrobiology in the Secondary Classroom (ASC)—in an innovative way and conduct research to determine the effectiveness of these materials in three different underrepresented student populations—African Americans, Hispanics, and Native Americas—experiencing an achievement gap in STEM areas at five sites. Improvements will focus on program alignment and increased use of data sets made available by research scientists.

This project is carrying out a research and development initiative to increase the success rates of our most at-risk high school students—ninth-grade students enrolled in algebra classes but significantly underprepared for high school mathematics. It will also result in new understandings about effective approaches for teaching mathematics to struggling students and about effective ways for implementing these approaches at scale, particularly in urban school districts.

This project augmenting the traditional professional development model with an online professional development platform—the Active Physics Teacher Community—that provides just-in-time support for teachers as they are enacting targeted units of the Active Physics curriculum. Teachers are helped in preparing lessons by providing them with formal instruction related to the lessons they are teaching in the classroom. In addition, teachers can participate in a moderated forum where they can share experiences.

The Accessing Science Ideas (ASI) project is developing and researching content enhancements that support science learning of middle school students with executive function and related learning disabilities.  The goal of ASI research is to measure the extent to which curricular units with content enhancements lead to increased student understanding of science concepts, improved reasoning, and greater confidence.

This project seeks to improve the science achievement and the academic English language proficiency of middle school Spanish-speaking English language learners (ELLs). This project will conduct a randomized trial longitudinal evaluation of an enhanced standards-based science curriculum model, consisting of five major components: (a) English language acquisition strategies integrated into the science curriculum, (b) technology-assisted instruction, (c) bi-weekly teacher professional development, (d) family involvement, and (e) paraprofessionals in working with individual ELLs.

Project MSSELL will conduct a two-year randomized trial longitudinal evaluation of an enhanced standards-based science curriculum model. In Year 1, the project will refine and pilot the model based on learnings from its previous developmental phase and implementation with K-3 grade students. In Years 2 and 3, the enhanced model will be implemented and studied with fifth- and sixth-grade students.