Projects

CISIP is a professional development program that enables English and science teachers to help students to learn content and communicate scientifically. The CISIP program: Translates How Students Learn Science in the Classroom and Common Core State Standards for student success; targets learning within a classroom discourse community that focuses on argumentation; and takes a team of science and English teachers at schools from middle level through university who collaborate.

This project aims to: (1) develop, implement and study the impact of a subject matter-focused, Problem-based Learning professional development model; and to (2) design ways of incorporating Problem-Based Learning (PBL) into key subject matter and teacher preparation courses taken by pre-service teachers, and study the impact on pre-service teachers' learning. This project is designed with and for teams of K-12 science and mathematics teachers from school districts of mid-Michigan.

This project builds upon the prototype Physics Teaching Web Advisory (Pathway), which was designed to demonstrate the ability to address issues related to the lack of preparation of many physics teachers, and to provide resources that can enliven even the most expert physics teachers' classrooms. Pathway combines state-of-the-art digital video library technology, pedagogical advances and materials contributed by master teachers.

This project is based on the assumption that teachers often make modifications to curriculum; reordering, skipping or adding lessons, changing an "exploration" into a lecture, and so on. This project pursues three related questions: What types of modifications do teachers make (and why), which types of modifications best help students learn, and how do teachers' modifications change in response to professional development activities designed to help them become more attuned to students' thinking?

This project produced and is testing a website with tools to help teachers identify when students’ science learning may be limited by how they construe the underlying causal structure of the concepts. It demonstrates students’ difficulties and a pedagogical approach to help them recast their explanations to align them with the causal structure in the scientifically accepted explanations. The site focuses on middle school with in-depth examples in density and ecosystems.

This project integrates the informal and formal science education sectors, bringing their combined resources to bear on the critical need for well-prepared and diverse urban science teachers. The study is designed to examine and document the effect of this integrated program on the production of urban science teachers. This study will also research the impact of internships in science centers on improving classroom science teaching in urban high schools.

This project is designed to assist K-3 teachers in teaching life and physical science for conceptual understanding. It integrates videos, stills and voice-over into one multimedia web-based tool. The program provides teachers with experiences in understanding details related to the \"how\" of high quality science teaching. The professional development activities illuminate what happens in planning and in arranging science classrooms to promote student learning.

This project focuses on critical needs in the preparation and long-term development of pre-service, undergraduate, K-6 teachers of science. The project investigates the impact on these students of undergraduate, standards-based, reform entry level science courses developed by faculty based on their participation in the NASA Opportunities for Visionary Academics processional development program to identify: short-term impacts on undergraduate students and long-term effects on graduated teachers; characteristics of reform courses and characteristics of effective development efforts.

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).

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 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.

This project partners high school science teachers and students with particle physicists working in experiments at the scientific frontier. These experiments are searching for answers to fundamental questions about the origin of mass, the dimensionality of spacetime and the nature of symmetries that govern physical processes. Among the experimental projects at the energy frontier with which the project is affiliated is the Large Hadron Collider, which is poised at the horizon of discovery.

This project develops resources to facilitate the involvement of college and university physics departments in the professional development of K-12 teachers of physics and physical science. Research investigates how students and teachers learn content and reasoning skills for applying concepts to real world situations; how teachers can learn content in a way that helps them promote student learning; and how teachers can learn to assess student understanding in a way that promotes student learning.

This project has pioneered simulation-based assessments of model-based science learning and inquiry practices for middle school physical and life science systems. The assessment suites include curriculum-embedded, formative assessments that provide  immediate, individualized feedback and graduated coaching with supporting reflection activities as well as summative end-of-unit benchmark assessments. The project has documented the instructional benefits, feasibility, utility, and technical quality of the assessments with over 7,000 students and 80 teachers in four states.

This project supports five graduate students with backgrounds in the natural and learning sciences as they achieve masters-level expertise in a science discipline and pursue coursework and complete dissertations in science education research. The program prepares them to 1) collaborate with educational and developmental psychologists and discipline-based science education researchers, and 2) to develop and teach courses that break down the traditional barriers between science teaching methods courses and science content courses for teachers.

This project provides support for a two-day workshop that would bring about 60 participants together to discuss the issues, challenges and opportunities in "Materials Education" and devise strategies for synergizing all stakeholders involved for further progress. Discussions will be focused on 4 topics: (1) Educating the public about the relevance of materials research; (2) Materials education for K-12 students and teachers; (3) Revolutionizing undergraduate education toward flexible curriculum; (4) Materials education for graduate students.

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.

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.

Current curriculum materials for elementary science students and teachers fail to provoke the following essential questions during science instruction: What is evidence? Why do you need evidence? The goal of this project is to identify whether and how elementary school students formulate answers to these questions and develop concepts of evidence and understandings of the nature of scientific evidence.

SmartGraphs activities run in a web browser; there is no software to download or install. SmartGraphs allows students to interact with on-screen graphs to learn about linear equations, the motion of objects, population dynamics, global warming, or other STEM topics that use scatter plots or line graphs. Teachers and students may also use and share existing activities, which are released under a Creative Commons license (see http://www.concord.org/projects/smartgraphs#curriculum).

This project is exploring how curricula and assessment using dynamic, interactive scientific visualizations of complex phenomena can ensure that all students learn significant science content. Dynamic visualizations provide an alternative pathway for students to understand science concepts, which can be exploited to increase the accessibility of a range of important science concepts. Computer technologies offer unprecedented opportunities to design curricula and assessments using visual technologies and to explore them in research, teaching, and learning.

This project will contribute to the understanding of how high school physics can have a positive impact on students' self-perceptions, impacting important educational outcomes in this subject matter. Its focus is on the development of a positive physics identity (self-perceptions with respect to physics in terms of competence, performance, interest, and recognition by others) among high school students, particularly females, as a means to increase current and future engagement with the subject.

This project will bring together two promising innovations: a high school course entitled Energizing Physics and the BEAR assessment system. The goal of this study is to develop and test a formative assessment system for Energizing Physics that has the potential to enable all students to learn physics, so they can succeed in college.

The project designs and implements technologies that combine artificial intelligence in the form of intelligent tutoring systems with multimedia interfaces (i.e., an electronic science notebook and virtual labs) to support children in grades 4-5 learning science. The students use LEONARDO's intelligent virtual science notebooks to create and experiment with interactive models of physical phenomena.

Colorado’s PhET project and Stanford’s AAALab will develop and study learning from interactive simulations designed for middle school science classrooms. Products will include 35 interactive sims with related support materials freely available from the PhET website; new technologies to collect real-time data on student use of sims; and guidelines for the development and use of sims for this age population. The team will also publish research on how students learn from sims.