Projects

The goal of the grant is to establish a culture of inquiry with all partners in order to develop interdiciplinary, authentic STEM learning environments. Design-based research provides iterative cycles of implementation to explore and refine the approach as a transformative model for STEM programs. The model supports a sustainable approach by building the capacity of schools to focus on design issues related to content, pedagogy, and leadership.

This project is developing modules for middle school and high school students in Earth and Space Science classes, testing the hypothesis that students who use computational models, analyze real-world data, and engage in building scientific reasoning and argumentation skills are better able to understand Earth science core ideas and how humans impact Earth's systems. The resulting online curriculum modules and teacher guides provide exciting examples of next generation Earth science teaching and learning materials.

This Exploratory Project is developing two prototype innovative instructional modules for grades 9-12 modules, and testing them extensively for usability and impact. These modules will emphasize the role of mathematics and computer science in planning for sustainability.

The core research questions of the project are: (1) What is the nature of high-leverage student thinking that teachers have available to them in their classrooms? (2) How do teachers use student thinking during instruction and what goals, orientations and resources underlie that use? (3) What is the learning trajectory for the teaching practice of productively using student thinking? and (4) What supports can be provided to move teachers along that learning trajectory?

The goal of this project is to develop and validate a middle school physical science assessment strand composed of four suites of simulation-based assessments for integrating into balanced (use of multiple measures), large-scale accountability science testing systems. It builds on the design templates, technical infrastructure, and evidence of the technical quality, feasibility, and instructional utility of the NSF-funded Calipers II project. The evaluation plan addresses both formative and summative aspects.

This exploratory project examines how teachers of second grade students scaffold the development of student conceptual models and their understanding of the nature of scientific models and modeling processes in physical science conceptual areas associated with the particulate nature of matter. This foundational research provides descriptive exemplars that can be shared in both the research literature and in practitioner publications as examples of what cognitively rich pedagogy can achieve.

The goal of this Transforming STEM Learning project is to comprehensively describe models of 20 inclusive STEM high schools in five states (California, New Mexico, New York, Ohio, and Texas), measure the factors that affect their implementation; and examine the relationships between these, the model components, and a range of student outcomes. The project is grounded in theoretical frameworks and research related to learning conditions and fidelity of implementation.

As part of a SAVI, researchers from the U.S. and from Finland will collaborate on investigating the relationships between engagement and learning in STEM transmedia games. The project involves two intensive, 5 day workshops to identify new measurement instruments to be integrated into each other's research and development work. The major research question is to what degree learners in the two cultures respond similarly or differently to the STEM learning games.

In this project, researchers are working with 4th and 5th grade teachers to improve their mathematics instruction by experimenting with different ways to implement the MQI model of professional development. The professional development experiences are intentionally aligned with the Mathematical Quality of Instruction (MQI) observation instrument. This research can inform models of professional development by providing more information about various ways that the same model of professional development can be implemented.

This CAREER proposal has four objectives: 1) examine the nature of mathematics teachers' learning opportunities for instructional improvement, 2) examine how work contexts influence the quality of teacher learning opportunities, 3) examine the impact of teacher learning opportunities on changes in student mathematics achievement over four years, and 4) work with district and school administrators to promote instructional improvement and student achievement by effectively providing learning opportunities to mathematics teachers.

This project will document factors explaining variations in science achievement across schools enrolling ethnically and linguistically diverse students. The research question is: what leadership and organizational features at the school level are associated with mitigating science achievement gaps? Researchers, in collaboration with school districts, will identify school leadership practices that can be connected with reductions in achievement gaps related to student ethnicity, English fluency, and social status.

The main goal of this mathematics education research project is to determine through experimentation specific teaching strategies that can be used to support middle school students in drawing connections between mathematical representations (fractions and ratios). The potential instructional strategies were identified from the Third International Mathematics and Science Study (TIMSS) video analyses study as the ones that best distinguished high performing countries from low performing countries.

This is a Faculty Early Career Development project aimed at developing, implementing, and assessing a model that introduces novice elementary school teachers to community-based engineering design as a strategy for teaching and learning in urban schools. Reflective of the new Framework for K-12 Science Education, the model addresses key crosscutting concepts, disciplinary core ideas, and scientific and engineering practices. It builds on theoretical perspectives and empirical foundations, including situated learning, engineering design cognition, and children's resources and funds of knowledge, including cultural and linguistic diversity.

This project will develop and study a professional development framework that is designed to help high school geometry teachers attend more carefully to student prior knowledge, interpret the learning implications of student prior knowledge, and adjust teaching practices accordingly. Participating teachers will participate in study groups that analyze animations of productive teaching practices; they will collaborate in planning, implementing, and analyzing geometry lessons; and they will critique videos of their own classroom instruction.

The goal of this project is to extend the theoretical and methodological construct of noticing to develop the concept of reciprocal noticing, a process by which teacher and student noticing are shared. The researcher argues that through reciprocal noticing the classroom can become the space for more equitable mathematics learning, particularly for language learners.

The development of six curricular projects that integrate mathematics based on the Common Core Mathematics Standards with science concepts from the Next Generation Science Standards combined with an engineering design pedagogy is the focus of this CAREER project.

This project provides elementary teachers, grades 3-5 with a pedagogical framework and related resources for distinguishing quality science teaching. The study focuses on developing and testing a framework, the Quality Science Teaching Continuum (QSTC), to determine its capacity to serve as a potent formative and collaborative tool with which teachers can reflect on their science teaching practices and recognize student behaviors that are indicators of engagement and science learning.

This project uses learning analytics and educational data mining methods to examine how elementary students learn in an online game designed to teach fractions using the splitting model. The project uses data to examine the following questions: 1) Is splitting an effective way to learn fractions?; 2) How do students learn by splitting?; 3) Are there common pathways students follow as they learn by splitting?; and 4) Are there optimal pathways for diverse learners?

This project expands and augments a currently-funded NSF Noyce Track II teacher recruitment and retention grant with Quality Talk (QT), an innovative, scalable teacher-facilitated discourse model. Over the course of four years, the work will address critical needs in physics and chemistry education in 10th through 12th grade classrooms by strengthening the capacity of participating teachers to design and implement lessons that support effective dialogic interactions.

This project contributes to the small research base by exploring the validity of Technology-Enhanced Items (TEIs) in the context of elementary geometry. The project addresses three research questions: 1) To what extent are TEIs a valid measurement of geometry standards in the elementary grades?; 2) To what extent do TEIs provide an improved measurement compared to SR items?; and 3) What are the general characteristics of mathematics standards that might be better measured through TEIs?

This is a large-scale, cross-sectional, and longitudinal study aimed at understanding and supporting the teaching of science and engineering practices and academic language development of middle and high school students (grades 7-10) with a special emphasis on English language learners (ELLs) and a focus on biotechnology.

This project aims to assist in the development and study of WeInvestigate, an application that will run on a mobile device. The application will help support learners as they engage in artifact construction using multiple media while two or more learners can be synchronously collaborating either face-to-face or at a distance. WeInvestigate is leveraging the research that learning in collaboration with others associated with higher engagement and learning outcomes.

This collaborative, exploratory, learning strand project focuses on improving reflective decision-making among elementary school students during the planning and re-design activities of the engineering design process. Five teacher researchers in three elementary schools provide the classroom laboratories for the study. Specified units from Engineering is Elementary, a well-studied curriculum, provide the engineering content.

The proposed project initiates new research and an integrated education plan to address specific problems in middle school mathematics classrooms by investigating (1) how to effectively differentiate instruction for middle school students at different reasoning levels; and (2) how to foster middle school students' algebraic reasoning and rational number knowledge in mutually supportive ways.

Technical assistance is being provided to key leaders in state education agencies (SEAs) to: 1) build SEA leaders' knowledge about effective mathematical professional development research; 2) deepen their understanding about necessary supports and structures that should be in place; and 3) enable SEA leaders to incorporate what they learn and analyze to their existing mathematics college- and career-readiness standards implementation plans.