Projects

The Science and Mathematics Simulated Interaction Model (SIM) project will design and clinically test simulations for teachers. The hypothesis is that simulations will identify strengths and misconceptions in teachers' understanding of content and pedagogy, increase instructional capacity, and advance student achievement. The SIM will be for pre-service and induction-stage teachers. The simulations will focus on common problems of practice, challenges, dilemmas, issues that mathematics and science teachers encounter at the secondary level.

The Science of Atoms and Molecules is supplemental material, constituting about 10% of the course work and providing a progressive understanding of the centrality of atomic scale phenomena and their implications in each discipline. Upgrading the computational models developed in the Molecular Workbench, the materials allow students to experience the atomic world and build models that can be used to understand and predict macroscopic phenomena.

This project proposes to design, implement, and investigate the impact on students of an innovative curriculum supplement called the Spectrum Laboratory. The Spectrum Lab will be an online, interactive learning environment that enables students to make use of the database of publicly available spectra from research scientists, as well as from students.

This project provides support for the U.S. National Commission on Mathematics Instruction, a primary means for ensuring U.S. participation in mathematics education at the international level. The project will facilitate interaction with mathematicians and mathematics educators from around the world as issues about instructional practices are addressed. The participation of representatives of USNC/MI on the international stage opens venues for collaborative research and opportunities to learn about successful practices from other countries.

This project is developing and testing a set of 12 curriculum modules designed to engage high school students and their teachers in the process of applying computational concepts and methods to problem solving in a variety of scientific contexts. The project perspective is that computational thinking can be usefully thought of as a specialized form of mathematical modeling.

This project addresses the growing need for research to support teachers in developing expertise in responsive decision making in which teachers elicit and build on children's mathematical thinking in the midst of instruction.

This project will develop and study three week-long middle school lab units designed to teach spatial abilities using a blend of physical and virtual (computer-based) models. "ThinkSpace" labs will help students explore 3-dimensional astronomical phenomena in ways that will support both understanding of these topics and a more general spatial ability. Students will learn both through direct work with the lab unit interface and through succeeding discussions with their peers.

This project will support the participation of 55 U.S. K-12 mathematics teachers or supervisors, graduate students, community college/university mathematics teachers, mathematicians, mathematics teacher educators and mathematics education researchers to attend the Thirteenth International Congress for Mathematical Education (ICME-13) to be held in Hamburg, Germany, July 24-31, 2016. The project will also prepare an educational status report (called the Fact Book) for the United States.

This project will develop an online curriculum-based supported by a teacher professional development (PD) program by rebuilding an existing life science unit of Biological Sciences Curriculum Study (BSCS) Middle School Science. The project is designed to be an exemplar of fully digital Next Generation Science Standards (NGSS) aligned resources for teachers and students, creating an NGSS-aligned learning environment combining disciplinary core ideas with science and engineering practices and cross-cutting concepts.

The goal of this project is to accelerate the progress of early-career and pre-service science teachers from novice to expert-like pedagogical reasoning and practice by developing and studying a system of discourse tools. The tools are aimed at developing teachers' capabilities in shaping instruction around the most fundamental science ideas; scaffolding student thinking; and adapting instruction to diverse student populations by collecting and analyzing student data on their thinking levels.

Identifying with engineering is critical to help students pursue engineering careers. This project responds to this persistent large-scale problem. The I-Engineering framework and tools address both the learning problem (supporting students in learning engineering design) and the identity problem (supporting students in recognizing that they belong in engineering). 

The study includes two and a half years of preparation and support for all the mathematics instructional leaders (ILs) within a large urban school district with a substantial minority student enrollment. These ILs will implement the Problem-Solving Cycle model with the mathematics teachers in their schools. Researchers will analyze the preparation and support that ILs need, the quality of their implementation, and the impact of the PD process on ILs, teachers, and students.

This project explores the use of cyberinfrastructure to significantly enhance the delivery and quality of professional development for grades 8-12 engineering, technology, and design educators. The goal of the project is to study whether the use of highly interactive cyberinfrastructure increases the educator's teaching competencies and how to effectively teach. Student achievement is measured by comparing state assessments in: the curriculum's technology, engineering, and design assessment, end-of-grade mathematics assessment, and end-of-grade science assessment.

This research and development project provides resources for ninth-grade mathematics students and teachers by developing, piloting, and field-testing intervention modules designed as supplementary materials for Algebra 1 classes (e.g., double-period algebra). Rather than developing isolated skills and reviewing particular topics, these materials aim to foster the development of mathematical habits of mind—in particular, the algebraic habit of abstracting from calculations, a key unifying idea in the transition from arithmetic to algebra.

This project will adapt an effective in-person teacher professional development model to an online approach. A defining feature of the Science Teachers Learning from Lesson Analysis (STeLLA) Professional Development program is its use of videos of classroom instruction and examples of student work to promote teacher learning. Adapting the STeLLA program to an online learning model can reach a broader and more diverse audience, such as teachers working in rural school districts and underserved communities.

Given the changes in instructional practices needed to support high quality mathematics teaching and learning based on college and career readiness standards, school districts need to provide professional learning opportunities for teachers that support those changes. The project is based on the TRUmath framework and will build a coherent and scalable plan for providing these opportunities in high school mathematics departments, a traditionally difficult unit of organizational change.

Given the changes in instructional practices needed to support high quality mathematics teaching and learning based on college and career readiness standards, school districts need to provide professional learning opportunities for teachers that support those changes. The project is based on the TRUmath framework and will build a coherent and scalable plan for providing these opportunities in high school mathematics departments, a traditionally difficult unit of organizational change.

The goals of this nine-week summer program are to develop undergraduates' knowledge and skills in biology education research, encourage undergraduates to pursue doctoral study of biology teaching and learning, expand the diversity of the talent pool in biology education research, strengthen and expand collaborations among faculty and students in education and life sciences, and contribute to the development of theory and knowledge about biology education in ways that can inform undergraduate biology instruction.

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 explores how immersive field science experiences and carefully designed digital resources can help secondary teachers make science more engaging and relatable for students. The research team will study how teachers incorporate what they learn from real-world science experiences into their classroom teaching and whether online materials can replicate some of the same benefits. By improving both immersive and digital professional learning experiences, the project aims to increase access to and decrease the cost of high-quality instructional supports, especially for teachers who cannot attend traditional field-based learning.

The purpose of this project is to investigate issues in the design and implementation of effective virtual learning communities (VLCs) for teachers and to examine the relation between teachers' reflective engagement with VLCs and their students' mathematics learning outcomes. Findings from this project will be used to build and share effective ways to support teacher learning online.

Understanding Space Through Engineering Design investigates how engaging K-5 children from underrepresented populations in the design of packages, maps, and mechanisms supports the development of spatial reasoning and spatial mathematics. The prime conjecture is that engineering design makes spatial mathematics more tangible and purposeful, and that systematic support for spatial reasoning and mathematics, in turn, influences the nature of children's designs and their understanding of how those designs work.

Increased focus on school accountability and teacher performance measures have resulted in STEM instruction that emphasizes content and procedural knowledge over critical thinking and real-world applications. Yet, critical thinking and application are essential in developing functional scientific literacy skills among students. This need is perhaps most pressing in economically depressed urban settings. One strategy to promote STEM engagement and learning is to make clear and meaningful connections between STEM concepts, principles, and STEM-related issues relevant to the learner. Socioscientific issues (SSI) and the Social Justice STEM Pedagogies (SJSP) framework can provide a powerful avenue for promoting the desired kinds of engagement. This collaborative research project is designed to investigate the effectiveness of a professional development (PD) program for STEM teachers to develop their pedagogical content knowledge in teaching SSI and SJSP.

Increased focus on school accountability and teacher performance measures have resulted in STEM instruction that emphasizes content and procedural knowledge over critical thinking and real-world applications. Yet, critical thinking and application are essential in developing functional scientific literacy skills among students. This need is perhaps most pressing in economically depressed urban settings. One strategy to promote STEM engagement and learning is to make clear and meaningful connections between STEM concepts, principles, and STEM-related issues relevant to the learner. Socioscientific issues (SSI) and the Social Justice STEM Pedagogies (SJSP) framework can provide a powerful avenue for promoting the desired kinds of engagement. This collaborative research project is designed to investigate the effectiveness of a professional development (PD) program for STEM teachers to develop their pedagogical content knowledge in teaching SSI and SJSP.

Increased focus on school accountability and teacher performance measures have resulted in STEM instruction that emphasizes content and procedural knowledge over critical thinking and real-world applications. Yet, critical thinking and application are essential in developing functional scientific literacy skills among students. This need is perhaps most pressing in economically depressed urban settings. One strategy to promote STEM engagement and learning is to make clear and meaningful connections between STEM concepts, principles, and STEM-related issues relevant to the learner. Socioscientific issues (SSI) and the Social Justice STEM Pedagogies (SJSP) framework can provide a powerful avenue for promoting the desired kinds of engagement. This collaborative research project is designed to investigate the effectiveness of a professional development (PD) program for STEM teachers to develop their pedagogical content knowledge in teaching SSI and SJSP.