Projects

A principled framework is created for the development of learning progressions in science that can demonstrate how their use can transform the way researchers, educators and curriculum developers conceptualize important scientific constructs. Using the construct of transformation of matter, which requires understanding of both discrete learning goals and also the connections between them, a hypothetical learning progression is constructed for grades 5-12.

This project is designing, developing, and testing a model that delivers effective teacher PD to in-service and preservice teachers to enable the successful implementation of engineering curricula. Research is performed to evaluate the impacts of the curricular materials and the teacher PD framework on classroom instructional practices and student learning, interests, and attitudes and to evaluate which curriculum components are most effective in promoting student learning and interest as a function of gender and ethnicity.

This project is demonstrating the use of cyber-enabled technologies to build and share adaptable interventions for pre- and in-service teacher growth that effectively make use of major video collections and have high promise of success at multiple sites. The cyber infrastructure being significantly extended through this project is supporting development and documentation of additional interventions for teacher professional development using this video collection, as well as other videos that might be added in the future.

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.

The Conference Board for the Mathematical Sciences (CBMS) is collaborating with the U.S. Department of Education to host a forum in Washington, DC designed to launch action for change in mathematics education based on the recommendations of the National Mathematics Advisory Panel. This forum will focus specifically on the following four areas: teachers and teacher education, learning processes, instructional material, and standards of evidence—research policies and mechanisms.

This project focuses on the challenge of using assessment of relevant STEM content to improve K-12 teaching and learning. CLEAR takes advantage of new technologies and research findings to investigate ways that science assessments can both capture and contribute to cumulative, integrated learning of standards-based concepts in middle school courses. The project will research new forms of assessment that document students' accumulation of knowledge and also serve as learning events.

In its first five years, this project established a durable and vibrant learning community of high school teachers, high school students, university students, scientists, faculty, and associated stake-holders that continues to attract science and math students, using the project’s cutting-edge science and advanced cyberinfrastructure as compelling elements of study. This project continues by providing an education and research partnership derived from basic research in particle physics, grid computing, and advanced networking.

We are analyzing the intended algebra curriculum as represented in a variety of high-school mathematics textbooks – Core Plus Mathematics Project (CPMP), Discovering Mathematics (Key Curriculum Press), EDC's Center for Mathematics Education, Glencoe, Interactive Mathematics Program (IMP), and University of Chicago School Mathematics Project (UCSMP). The textbook analysis is based on two dimensions frequently used for curriculum analysis: a content dimension and a cognitive dimension.

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.

This project investigates how vignette illustrations minimize the impact of limited English proficiency on student performance in science tests. Different analyses will determine whether and how ELL and non-ELL students differ significantly on the ways they use vignettes to make sense of items; whether the use of vignettes reduces test-score differences due to language factors between ELL and non-ELL students; and whether the level of distance of the items moderates the effectiveness of vignette-illustrated items.

This project is developing a week-long unit of activities focused on the cryosphere, implementing the activities with students, and studying the activities’ effectiveness. The overarching goals of this project are to build a sequence of scaffolded investigations that will help students more fully understand the cryosphere; and investigate the effectiveness of the sequence of and investigations at helping students understand how and why a component of the Earth system varies over time.

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.

This project investigated the potential opportunities and challenges for educators to incorporate explorations of a variety of large data sets into science, math and, to a lesser extent, social science classes at the secondary level.

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.

This project addresses the need for new electronic materials and associated processes for applications in microelectronics, optics and sensors. Materials growth methods, electrical, chemical and physical characterization, pattern generation, device fabrication, and theory/modeling are invoked to ensure holistic and interdisciplinary approaches to the development and investigation of novel materials and devices.

This exploratory project seeks to understand the role that a network of tablet computers may play in elementary and middle school math and science classrooms. The project uses classroom observations, student interviews, teacher interviews, and student artifacts to identify the advantages and disadvantages of these resources, to understand what challenges and benefits they offer to teachers, and to offer recommendations for future hardware, software, and curriculum development.

This project supports up to eight fellows per year to participate in the Albert Einstein Distinguished Educator Fellows Program. This program provides opportunities for teachers to work on educational issues and/or programs in a federal agency or congressional office. It promotes professional growth; fosters the exchange of ideas that are relevant to STEM education at the national and state levels through conferences, workshops, and presentations; provides opportunities for teachers' input; and awards outstanding teachers.

This project is developing a science teacher education model focused on the establishment of a diagnostic learning environment through formative assessment as a powerful instructional practice for promoting learning of all students (grades 5–12) on the topic of energy with the goal of increasing the understanding of the processes through which teachers develop the requisite knowledge, skills, and dispositions for effective deployment of a formative assessment instructional cycle.

This exploratory project seeks to understand the role that a network of tablet computers may play in elementary and middle school math and science classrooms. The study will use classroom observations, student interviews, teacher interviews and student artifacts to identify the advantages and disadvantages of these resources, understand what challenges and benefits they offer to teachers, and offer recommendations for future hardware, software, and curriculum development.

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.

The SAVE Science project is creating an innovative system using immersive virtual environments for evaluating learning in science, consistent with research- and policy-based recommendations for science learning focused around the big ideas of science content and inquiry for middle school years. Motivation for this comes not only from best practices as outlined in the National Science Education Standards and AAAS' Project 2061, but also from the declining interest and confidence of today's student in science.

This project aims to determine whether curricula designed to support teacher and student learning have positive impacts on teacher knowledge, attitudes, and instructional practices; to what degree educative curricula help teachers with more and less experience teaching ELLs and how level of teaching experience relates to teacher knowledge, attitudes, and instructional practices; and the effects of the educative curricula in high implementation settings on ELLs knowledge and attitudes in science, and developing English proficiency.

This project performs integrated research on emergent materials and phenomena in magnetoelectronics. The aim of the research activities is to advance understanding of the emergent materials and phenomena and to develop highly sophisticated experimental and theoretical tools required to study them. Project activities include an innovative education research program aimed at cognition of materials science concepts, K-12 outreach and visitation programs, undergraduate research programs, and graduate-education enhancement programs.

This project uses computer-based models of interacting organisms and their environments to support a learning progression leading to an appreciation of the theory of evolution and evidence that supports it. The project has created a research-based curriculum centered on progressively complex models that exhibit emergent behavior. The project will help improve the teaching of complex scientific topics and provide a reliable means of directly assessing students' conceptual understanding and inquiry skills.

SRI International developed a formative assessment intervention that integrates classroom network technologies and contingent curriculum activities to help middle school teachers adjust instruction to improve student learning of Earth science concepts. The intervention was tested as part of a quasi-experimental study within an urban school district in Colorado that includes ethnically and economically diverse student populations. Findings indicate significant student learning gains for students in implementation classes as compared to students in comparison classes.