Projects

This project aims to (1) determine ways in which Evidence-Centered Design enhances the quality of large-scale, technology-based science assessments for middle school grades and high school equivalency; (2) implement resulting procedures in operational test development; (3) evaluate the efficiency, effectiveness and generalizability of these procedures, and (4) disseminate findings to the assessment community.

In response to the critical need for scholars with deep content knowledge in chemistry and the specialized training to conduct CER, this capacity building project prepares scholars whose research marries expertise in instrument design with extensive literature on chemistry misconceptions, resulting in the development of concept inventories as reliable and valid measures of student learning for use by chemistry teachers (both high school and post-secondary) and chemistry education researchers.

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 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 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 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.

This project collects evidence supporting the validity of test instruments and initial characterization of high school teachers' background and use of materials and pedagogies. The project is constructing and validating multiple forms of test instruments that can be used for the evaluation of interventions (e.g. professional development, implementation of new curricula) and the measurement of aspects of teacher knowledge (e.g. subject matter, knowledge of student misconceptions).

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 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 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).

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 uses a mixed-methods design to test the hypothesis that key approaches to high school reform grease the mathematics and science pipelines for all students in reforming high schools. This study is intended to provide understanding of pipeline progression in reforming high schools and strategies successful schools employ to ensure timely pipeline progress for all students, particularly those historically underrepresented and underserved in mathematics and science and post-secondary education.

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.

This project covers participants' costs to attend a national conference series focusing upon supporting incipient science education research projects. A primary objective is to provide a venue in which researchers can describe their lines of inquiry and to then receive guidance and input about refining those ambitions. The other primary objective is to promote an innovative conference design in which a structured presentation format serves as an incubator for scholarly work.

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 teacher professional enhancement program brings K-12 educators and polar researchers together in hands-on field experiences in the Arctic and Antarctic. Project activities and products foster the integration of research and education to produce a legacy of long-term teacher-researcher collaborations, improvement of teacher content knowledge and teaching practices, shareable online learning resources based on real-world science, improved student knowledge of and interest in the Arctic and Antarctic, and broad public engagement in polar science.

This project is developing a data literacy curriculum for 7th grade students which is composed of four two-week units to be taught in social studies, mathematics, science and English courses. The curriculum utilizes data on water use and quality in Ohio, chosen because other communities will have comparable data to modify the curriculum to meet their needs. Central to the curriculum are the issue of fairness and how data are used to make societal decisions.

This project is creating a suite of instruments for measuring fidelity of implementation of several science and mathematics instructional materials programs and a User's Guide for customizing those instruments to other programs. The instruments are grounded in a shared conceptual framework that organizes "critical components" that the programs share. The suite was piloted and field tested in over 50 schools in Chicago.

This project is documenting how middle and secondary school science teachers first develop a perspective on science learning, translate that perspective into their own teaching practice and finally make explicit links to their colleagues. The research is investigating the impact of professional development based on model-based reasoning, supported by Lesson Study and an apprentice-like program in teacher leadership.

This project will develop 15 modules for high school students that connect biology, computation, and mathematics with corresponding teacher materials and professional development activities. The modules will draw on an approach to biological phenomena as involving information processing, in three illustrative areas conducive to learning at the high school level: Bioinformatics and Computational Biology, Mathematical Methods in Epidemiology, and Mathematical Methods in Ecology.

This project is developing a learning progression in scientific inquiry about the nature of matter. The effort will result in a research-guided system of curriculum, assessment and professional development focusing on the transition from a macroscopic to a microscopic understanding of matter that occurs in upper elementary and middle school. The project has a close collaboration with scientists and urban schools.

The project is testing a learning progression for modeling that spans the elementary and middle grades. Modeling instruction will be organized around concepts in life sciences that cumulate to a strong conceptual understanding of micro and macro evolution. The work takes place in two districts with underserved children. A curriculum strand is being created, assessments developed and a longitudinal research study conducted. The project also includes an extensive professional development model and accompanying dissemination strategy.

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.