Projects

This project addresses the need for a computationally-enabled STEM workforce by equipping teachers with the skills necessary to prepare students for future endeavors as computationally-enabled scientists and citizens, and by investigating the most effective ways to provide this instruction to teachers. The project also addresses the immediate challenge presented by NGSS to prepare middle school science teachers to implement rich computational thinking experiences within science classes.

This project will produce insights into the challenges teachers face in modifying their teaching in the substantial and complex ways demanded by the Next Generation Science Standards. This project will develop and study a program of professional development to help middle and high school science teachers support their students to learn to argue scientifically. 

This project uses a new theoretical framework that specifies criteria for developing scientific thinking skills that include the value that people place on scientific aims, the cognitive engagement needed to evaluate scientific claims, and the scientific skills that will enable one to arrive at the best supported explanation of a scientific phenomenon. The project will work with high school biology teachers to investigate their own understanding of scientific thinking, how it can be improved through professional development, and how this improvement can translate into practice to support student learning.

This project designs materials and an accompanying support system to enable the development of expertise in the teaching of mathematics at the elementary level. The project has four main components: online professional development modules; practice-based assessments; resources for facilitators; and web-based technologies to deliver module content to diverse settings. Three modules are being developed and focus on fractions, reasoning and explanation, and geometry. Each module is organized into ten 1.5 hour sessions.

This project is developing a comprehensive science curriculum for grades 6-8. The materials are organized around driving questions that provide a context to motivate students as they use their knowledge and skills in scientific practices, and contain hands-on experiences, technology tools and reading materials that extend students' first-hand experiences of phenomena and support science literacy.

This project will design a comprehensive science curriculum for grades 6-8, in which learning performances drive the design of activities and assessments in order to specify how students should be able to use the scientific ideas and skills outlined in standards. The materials contain hands-on experiences, technology tools and reading materials that extend students' first-hand experiences of phenomena and support science literacy.

The project will develop and research an innovative model for rural science teacher professional development via technology-mediated lesson study (TMLS). This approach supports translating professional learning into classroom practice by developing a technology-based, social support system among rural teachers.

This project will develop, evaluate, and compare the effectiveness of newly-designed online learning platform with traditional face-to-face PD in supporting rural high school science teachers' implementation of an existing biology curriculum aligned with the Next Generation Science Standards (NGSS).

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).

The project will design an assessment based on learning progressions for the concept of function - a critical concept for algebra learning and understanding. The goal of the assessment and learning progression design is to specifically incorporate findings about the learning of students traditionally under-served and under-performing in algebra courses.

This project will promote pre-K teachers' use of specific teaching strategies that have been shown to enhance young children's learning and social skills. To enhance teachers' use of these practices, the project will develop a new practitioner-friendly version of the Classroom Quality Real-time Empirically-based Feedback (CQ-REF) tool for instructional coaches who work with pre-K teachers. The CQ-REF tool will guide coaches' ability to observe specific teacher practices in their classrooms and then provide feedback to help teachers evaluate their practices and set goals for improvement, addressing the need for accessible, real-time feedback on high quality pre-K classroom teaching.

This project is focused on creating, testing, refining, and studying a computer-based, individualized, interactive learning system for intermediate/middle school students or by teachers in classrooms. This learning system is called Individualized Dynamic Geometry Instruction and will contain four instructional modules in geometry and measurement that reflect the recommendations of the Common Core State Standards.

This study examines changes in preservice and inservice K-8 teachers' understandings of science and pedagogy across a reform-based Professional Development Continuum. It researches how teachers' knowledge develops across inquiry learning experiences and how undergraduate learning experiences and the contexts of classroom practice shape new teachers' understandings and practice. The study is expected to inform models of STEM teacher education that account for the interwoven intellectual and personal dimensions of the challenging transition to inquiry-based teaching.

The main purpose of this project is to develop instructional materials for a year-long, fifth grade curriculum for all students, including ELLs. The planned curriculum will promote language-focused and three-dimensional science learning (through blending of science and engineering practices, crosscutting concepts, and disciplinary core ideas), aligned with the Framework for K-12 Science Education, the Next Generation Science Standards, and the Conceptual Framework for Language use in the Science Classroom.

The main purpose of this project is to develop instructional materials for a year-long, fifth grade curriculum for all students, including ELLs. The planned curriculum will promote language-focused and three-dimensional science learning (through blending of science and engineering practices, crosscutting concepts, and disciplinary core ideas), aligned with the Framework for K-12 Science Education, the Next Generation Science Standards, and the Conceptual Framework for Language use in the Science Classroom.

The project will develop and refine an electronic Test of Early Numeracy (e-TEN) in English and Spanish that will assess informal and formal knowledge of number and operations in domains including verbal counting, numbering, numerical relationships, and mental addition/subtraction. The overarching goal of the assessment design is to create a measure that is more accurate, more accessible to a wider range of children, and easier to administer than existing measures.

Research has shown that the emotions elementary school teachers and their students experience when engaging in mathematics activities play an important role in mathematics teaching and learning. Yet, the field lacks mathematics-specific professional learning opportunities for elementary teachers that focus on the role of teachers’ and learners’ emotions in the way they experience mathematics in the classroom. This project will address these gaps by developing and testing the Orienting Positive Emotions in New Teachers for Mathematics (OPEN for Math) professional learning program.

This project is developing and evaluating a test form that diagnoses teachers' capacities in two closely connected cases of reasoning about multiplicative relations among quantities: fractions and proportions. Teachers' responses to test items will be informative about their capacities to reason about content in ways that support student’s thinking. The project is developing instruments using a new class of psychometric models called Diagnostic Classifcation Models (DCMs) that are based on categorical latent variables.

This project aims to develop a software diagnostic tool for integrating diagnostic interviews, group administered assessments, and student data in real-time so that teachers can enter and view student status information. This project would concentrate on rational number learning in grades 3-8. The design is based on a model of learning trajectories developed from existing research studies.

This project is creating and studying a blended professional development model (face-to-face and online) for mathematics teachers and special educators (grades 4-7) with an emphasis on teaching struggling math students in the areas of fractions, decimals, and positive/negative numbers (Common Core State Standards). The model's innovative design differentiates professional learning to address teachers' wide range of prior knowledge, experiences, and interests.

This project helps teachers learn to use NSDL resources in ways that meaningfully affect their practice in STEM content areas while increasing their skills as designers of learning activities. The objectives of this three-year project are to: design and implement a teacher development model and STEM content development model; contribute teacher-designed learning activities to NSDL; and use evaluation and research to measure impact on teaching.

This project represents a new approach to quality assessment of K-12 science and engineering learning experiences. By updating and expanding the Dimensions of Success (DoS) observation tool initially established for informal science learning settings to middle school science and engineering classrooms (DoS-MSSE), the project will create and implement a sustainable and scalable system of support for teachers who are learning how to implement the Next Generation Science Standards (NGSS) Framework for K-12 effectively and equitably.

This project will provide curricular and pedagogical support by developing and evaluating teacher-ready curricular Digital Internship Modules for Engineering (DIMEs). DIMES will be designed to support middle school science teachers in providing students with experiences that require students to use engineering design practices and science understanding to solve a real-world problem, thereby promoting a robust understanding of science and engineering, and motivating students to increased interest in science and engineering.

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 is examining the nature of mathematical discourse in middle school mathematics classrooms; the ways in which middle school mathematics teachers’ beliefs impact the discourse when working to enact reform-oriented instruction; and how this information can be used to incorporate practitioner research using concepts and tools of discourse analysis to improve mathematics instruction. The educational goal is to design a long-term professional development program that will continue beyond funding with other cohorts of teachers.