Projects

This project addresses middle school students’ learning of science through the improvement of their inquiry science skills. The main goal is to develop a rigorous, technology-based assessment system for standards-aligned assessment of inquiry skills in six physical science content areas (i.e., Properties of Matter; Elements, Compounds, and Mixtures; Motion of Objects; Forms of Energy; and Heat Energy). Assessments are aligned with the Massachusetts Curricular Framework and National Science Education Standards.

This project uses media such as Science Bulletin Snapshots to engage students with current research and to foster scientific understanding and civic engagement. Through environmental case studies, students learn to develop hypotheses, analyze scientific data, and make conclusions. To address the objectives, the project will create inquiry-based case studies to situate several central ecological principles, as determined by national and state standards, into the context of environmental issues.

This project employs sensing technologies to help transform students' physical actions during play into a set of symbolic (computer) representations in a physics simulation and to engage the children in a developmentally appropriate and powerful form of scientific modeling. The students are in grades K–1 at UCLA's elementary school, and the intervention is based on the existing content unit on Force and Motion.

Researchers are developing a practice-based curriculum for the professional education of preservice and practicing secondary mathematics teachers that focuses on reasoning and proving; has narrative cases as a central component; and supports the development of knowledge of mathematics needed for teaching. This curriculum is comprised of eight constellations of activities that focus on key aspects of reasoning and proving such as identifying patterns; making conjectures; providing proofs; and providing non-proof arguments.

This project examines the nature of adaptive expertise in mathematics education, exploring relationships between this concept from cognitive psychology and effective middle school mathematics instruction. One goal of the project is to operationalize adaptive expertise in mathematics classroom using three dimensions: cognitive models of professional competence, instructional practices, and professional learning. Then, researchers seek to determine whether teachers who are more effective at raising student achievement are more or less adaptive.

The primary purpose of this international conference was for participants in the US to exchange views and discuss the latest research findings on (primary) science assessment. The conference focused on research around building assessment systems that help teachers diagnose student learning in the classroom but also link meaningfully to large-scale accountability systems (in districts or national levels). The project resulted in a report, proceedings, journal publications.

This project aims to (1) investigate whether or not it is possible to successfully scale-up and adapt the Capacity Building Systems Model used in the Gadsden Mathematics Initiative and improve mathematics achievement for all students in a larger school district, and (2) replicate success in broadening the participation of underrepresented groups in entering STEM field by closing the achievement gap and raising the achievement level of underrepresented students in mathematics.

This project seeks to advance knowledge in K-12 STEM education and assessment practices by building capacity for Assessment for Learning, improving assessments and teacher preparation courses, and providing models for pre-service teacher preparation through enhanced teaching modules. Three goals are: (1) faculty from three centers form a learning community, (2) recruit 5 STEM research scholars to conduct research on measurement and evaluation, and (3) expose pre-service teachers to assessment models in their coursework.

This project is comparing and evaluating different models for the delivery of online professional development aimed at elementary science teachers. The focus is on asynchronous (anytime, anywhere) and minimally facilitated models, because these approaches hold promise for reaching large numbers of teachers in a cost-effective way. The research capitalizes on experiences with BCM's award-winning, high traffic website for educators, BioEd Online.

This study is aimed at exploring the components and impact of a teacher professional development model on teacher performance and student achievement and motivation in STEM disciplines at schools serving large numbers of minority students. It also aims to research and evaluate the impact of teachers who provide students with school experiences that are geared toward fostering high academic achievement.

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 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.

Using an experimental design, this project examines the effects of online professional development courses on high school biology teachers' content and pedagogical knowledge, and on their students' knowledge. The project is testing the impact of using digital resouces and is using hierarchal linear modeling techniques to analyze data. It will contribute to the knowledge base of what impacts student achievement by testing the efficacy of online professional development for science teachers.

This study explores the ways middle school mathematics teachers implement standards-based curriculum materials in urban schools. It takes the view that instructional materials are cultural tools and examines how teachers use these tools to plan and implement the curriculum in their classrooms. The study is using a mixed methods approach that combines surveys of teachers in 30 schools in the Newark Public Schools district and closer observations of teachers in selected case schools.

This project develops, implements, and evaluates new multimedia laboratory activities designed to engage students in science, technology, engineering, and mathematics (STEM). The project specifically targets artistically gifted students who are often steered towards more traditionally creative areas (e.g., arts and humanities) and away from STEM. The goals to help students understand that scientific principles permeate the creative and performing arts and that creativity and expression are also embraced by STEM.

This grant examines the changes teachers and students go through in their first year of implementing a New Technology High School project-based curriculum for ninth graders in two high schools. This first year of implementation is part of a phased-in implementation for subsequent grades. The NTHS approach calls for moving from more traditional approaches to mathematics and science education to project-based curricula that posits mathematics and science in the context of real-world issues and problems.

The ReaL Earth Inquiry project empowers teachers to employ real-world local and regional Earth system science in the classroom. Earth systems science teachers need the pedagogic background, the content, and the support that enables them to engage students in asking real questions about their own communities. The project is developing online "Teacher-Friendly Guides" (resources), professional development involving fieldwork, and inquiry-focused approaches using "virtual fieldwork experiences."  

This project aims to improve professional development programs for pre-service teachers (PSTs) as a way to improve student learning in mathematics and science. PSTs engage in a series of teaching cycles, and then engage in lesson study groups to develop, teach, and analyze a whole-class lesson. The cycle is completed by reexamining students' knowledge in teaching experiments with pairs of students. These teaching cycles are called Iterative Model Building (IMB).

This project focuses on the assessed impact of a teacher professional development (TPD) program around the applied sciences. Specifically, researchers seek to examine the measurable impact of an established teacher professional development program currently offered through the UC Davis Edward Teller Education Center. The Center delivers teacher training and curricula and draws upon an instructor cohort that pairs a regional master teacher and relevant LLNL scientists in curriculum development and delivery.

This project uses new psychometric techniques to create a technological tool that could evaluate how well students in the 4th-8th mathematics and science classrooms respond to complex performance tasks. The purpose of this tool is to improve the instruction of teachers in mathematics and science. It will produce real-time individualized diagnoses of instructional needs to help teachers plan instruction that specifically addresses the learning needs of each student in that class.

This project revises and tests integrated STEM modules and an accompanying professional development component that promote differentiated instruction in order to facilitate high school teachers' instruction of 21st century skills and integrated STEM content. STEM Fusion is a multi-tiered project focusing on the refinement of draft professional resources and the development of teacher skills related to differentiated instruction within integrated STEM instruction.

This project develops ecosystems-focused instructional materials that use sensor data and technology to help second and third graders become more proficient at data modeling and scientific argumentation. The goals are to provide elementary teachers with a research-based curriculum that engages students in exploring and visualizing environmental data and using the data to construct scientific arguments, and to contribute to the cognitive development literature on children's ideas about and abilities for scientific argumentation.

This project aims to find principles of instruction for developing students' visual models in science, including design principles for curriculum development, technological tools, and new pedagogical principles. The project concentrates on methods teachers use to guide class discussions while using innovative model-based curricula in middle school biology and in high school physical science.

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.  

The project proposes a longitudinal study that investigates the development of an understanding of measurement across seven grades-from pre-K through Grade 5. Specifically, the project will establish clear cognitive accounts of the development of students' strategic and conceptual knowledge of measurement on increasingly demanding sets of length, perimeter, and area measurement tasks.