Projects

This project combines Unity (a cross-platform game engine and integrated development environment) with cutting-edge haptic technology to provide upper elementary students with a new way of accessing core science content. The core research question that undergirds this exploratory project is: How does the addition of haptic feedback influence users' understandings of core, often invisible, science content?

This project is examining an innovative model of situated Professional Development (PD) and the contribution of controlled teaching experiences to teacher learning and, as a result, to student learning. The project is carrying out intensive research about an existing special PD summer institute (QuEST) that has been in existence for more than five years through a state Improving Teacher Quality Grants program.

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.

This exploratory proposal is researching and developing professional learning activities to help high school teachers use available and emerging social media to teach scientific argumentation. The project responds to the growing emphasis on scientific argumentation in new standards.

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.

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.

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.

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 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.

This study is based on a theoretical model that embeds engineering design within social, cultural, and linguistic activity, seeking to understand (a) how adolescent English learners draw from various linguistic, representational, and social resources as they work toward solving community-based engineering design challenges; (b) the problems they face in working on the challenges and how they seek to overcome those problems; and (c) adolescents' willingness to conceptualize themselves as future engineers.

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.

This project is developing evidence about the efficacy of the Engineering is Elementary curriculum under ideal conditions by studying the student and teacher-level effects of implementation. The project seeks to determine the core elements of the curriculum that support successful use. The findings from this study have broad implications for how engineering design curricular can be developed and implemented at the elementary level.

This study examines the impact of the newly revised Advanced Placement (AP) Biology and Chemistry courses on students' understanding of and ability to utilize scientific inquiry, on students' confidence in engaging in college-level material, and on students’ enrollment and persistence in college STEM majors. The project provides estimates of the impact of students' AP-course taking on their progress into postsecondary educational experiences and their intent to continue to prepare to be future engineers and scientists.

This project is developing teaching modules that engage high school students in learning and using mathematics. Using geo-spatial technologies, students explore their city with the purpose of collecting data they bring back to the formal classroom and use as part of their mathematics lessons. This place-based orientation helps students connect their everyday and school mathematical thinking. Researchers are investigating the impact of place-based learning on students' attitudes, beliefs, and self-concepts about mathematics in urban schools.

The RISE project is creating curriculum resources for dual language learners (DLLs) in science, technology and engineering (STE). Participants include teachers in pre-K programs in the Boston area selected to target Hispanic and Chinese students and their families. The curriculum will be based on the Massachusetts framework, one of only a few states with pre-K standards. The evaluation will monitor both the progress of the research and development and the dissemination to the target audiences.

This collaborative project is developing instruments to assess secondary teachers' Mathematical Habits of Mind (MHoM). These habits bring parsimony, focus, and coherence to teachers' mathematical thinking and, in turn, to their work with students. This work fits into a larger research agenda with the ultimate goal of understanding the connections between secondary teachers' mathematical knowledge for teaching and secondary students' mathematical understanding and achievement.

In this project, investigators will convene a group of 15 African American science educators, scientists, and doctoral student scholars and assign them to small work groups to design and conduct multi-site micro-research studies on learning activities that promote science learning and teaching. Work groups will investigate different learning and teaching approaches used in K-12 rural and urban school settings to identify effects on student science learning using quantitative, qualitative, or mixed design studies.

The project at Spelman College includes activities that develop computational thinking and encourage middle school, African-American girls to consider careers in computer science. Over a three-year period, the girls attend summer camp sessions of two weeks where they learn to design interactive games. Experts in Computational Algorithmic Thinking as well as undergraduate, computer science majors at Spelman College guide the middle-school students in their design of games and exploration of related STEM careers.

Research has shown that engaging students, including students from underrepresented groups, in appropriately structured reasoning activities, including argumentation, may lead to enhanced learning. This project will provide information about how teachers learn to support collective argumentation and will allow for the development of professional development materials for prospective and practicing teachers that will enhance their support for productive collective argumentation.

This project will investigate the implementation of a Teacher Residency Academy model to recruit, license, induct, employ, and retain middle school and secondary science teachers for high-need schools that serve more than 119,000 diverse students. The Alliance will: create a high-quality, rigorous, and clinically-based teacher preparation program for aspiring middle and secondary science teachers; recruit and support diverse science educators and contribute to the knowledge base regarding the implementation of a clinically-based science teacher.

This project will iteratively design, develop, field test, refine, and rigorously study a six-unit, facilitated, online professional development (PD) course focusing on energy-related concepts in the context of alternative energy. The primary audience is high school science teachers teaching out of their field of endorsement and serving students underrepresented in the sciences. The project will investigate whether the PD will precipitate changes in teacher knowledge and practice that result in higher student achievement.

This project will modify the teacher preparation program for preK-8 teachers. The program is designed to help pre-service teachers learn mathematics well, learn to access students' cultural funds of knowledge, and learn to encourage students' mathematical thinking. The developers are designing (a) modules that can be used in teacher preparation courses, (b) a mentoring program for new teachers, and (c) on-line networks to facilitate collaboration among participating teachers and institutions.

This five-year project investigates how to provide continuous assessment and feedback to guide students' understanding during science inquiry-learning experiences, as well as detailed guidance to teachers and administrators through a technology-enhanced system. The assessment system integrates validated automated scorings for students' written responses to open-ended assessment items into the "Web-based Inquiry Science Environment" (WISE) program.

The American Museum of Natural History in New York City, in partnership with New York University, and in collaboration with five high-needs schools, is developing, implementing, and researching a five-year pilot Master of Arts in Teaching (MAT) program in Earth Science. The program is delivered by the Museum's scientific and education teams and its evaluation covers aspects of the program from recruitment to first year of teaching.