Projects

This is a four-year project to develop, implement, and study an experimental model of secondary science pre-service teacher education designed to prepare novice school teachers to provide effective science instruction to English language learners (ELLs). The project incorporates the principles underlying the Next Generation Science Standards with a focus on promoting students' scientific sense-making, comprehension and communication of scientific discourse, and productive use of language.

This working conference will help university professors who teach elementary mathematics methods courses learn to use Complex Instruction, a research-proven pedagogy for building mathematical content knowledge and supporting the learning of diverse students.

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 exploratory project builds on twelve years of successful experience with the summer program for secondary mathematics teachers at PCMI. It addresses the following two needs in the field of professional development for secondary mathematics teachers: increase content knowledge and understanding of the Common Core State Standards for Mathematics; and investigate and develop alternative models to conduct content-based professional development that meets the recommendations of the MET-II report.

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 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 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 research and development project is premised on the notion that recent technological developments have made it feasible to represent classroom work in new ways. In addition to watching recorded videos of classroom interactions or reading written cases, teacher educators and teachers can now watch animations and image sequences, realized with cartoon characters, and made to depict activities that happened, or could have happened, in a mathematics classroom.

A two day workshop/colloquium will be hosted at Northwestern University and is focused on the use of video and online learning in support of the College and CAREER Readiness Standards.

This is a three-day conference designed to support the development and use of K-12 formative and summative assessments aligned with the Framework for K-12 Science Education (NRC, 2012).

Social Dynamics is an exploratory project to investigate how face-to-face teaching leveraging the use of an online social network learning platform (SNLP) can increase middle school students' science learning and enhance their development of contextual identities related to science.

This is a collaborative project to develop, test, and analyze sets of technology-supported diagnostic classroom assessments for middle school (grades 6-8) physical science. Assessments are aligned with the performance assessment and evidence-centered design methodologies suggested in the Framework for K-12 Science Education (NRC, 2012).

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.

This project is designing and conducting a crowd-sourced open innovation challenge to young people of ages 13-18 to mitigate levels of greenhouse gases. The goal of the project is to explore the extent to which the challenge will successfully attract, engage and motivate teen participants to conduct sustained and meaningful scientific inquiry across science, technology and engineering disciplines.

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 is a 2-day conference that will examine current strategies, issues and future challenges related to teacher professional development regarding integrating inquiry-oriented science instruction and English Language Development (ELD) for K-5 students. The conference convenes 40 researchers and professional development practitioners who examine theory and practice in inquiry-based science instruction and ELD.

The project will use a comprehensive mixed methods design to develop theoretically-grounded measures of student engagement in middle school math and science classes that reflect a multidimensional construct within an ethnically and socioeconomically diverse sample of urban youth. The project conceptualizes student engagement as a multidimensional construct including behavioral, emotional, and cognitive components. This multidimensional perspective of student engagement provides a rich characterization of how students act, feel, and think.

This is a collaborative project to develop, test, and analyze sets of technology-supported diagnostic classroom assessments for middle school (grades 6-8) physical science. Assessments are aligned with the performance assessment and evidence-centered design methodologies suggested in the Framework for K-12 Science Education (NRC, 2012).

The goal of the project is to inform the development of an impact-based research methodology (IBR) to enable a more direct and overt connections between academic research on games and the development of educational products and services that are sustainable and scalable.

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 is developing and validating an assessment instrument that addresses the life sciences for students and teachers in grades 9 through 12 based on the Misconception Oriented Standards-based Assessment Resource for Teachers (MOSART).

This is a collaborative project to develop, test, and analyze sets of technology-supported diagnostic classroom assessments for middle school (grades 6-8) physical science. Assessments are aligned with the performance assessment and evidence-centered design methodologies suggested in the Framework for K-12 Science Education (NRC, 2012).

This project explores the potential for enhancing students' interest and ability in STEM disciplines by broadening fourth grade students' understanding and interest in the spatial perspectives inherent in geography and other science disciplines. The project tests a set of hypotheses that posit that the use of GIS in the classroom results in a measureable improvement in students' spatial reasoning and motivation.

This exploratory project develops and tests graphical scaffolds which facilitate high school students' coordination of connecting evidence with alternative explanations of particular phenomena, as well as their collaborative argumentation about these phenomena. At the same time, the project examines how high school students use these tools to construct scientifically accurate conceptions about major topics in Earth and space sciences and deepens their abilities to be critically evaluative in the process of scientific inquiry.

This two-year project will develop, pilot, validate, and publish a Teacher's Guide to the Science and Mathematics Resources of the ELPD Framework. This guide and related materials will translate the key science and mathematics concepts, ideas, and practices found within the ELPD Framework into classroom resources for direct use by teachers, schools, and districts to support English learners (ELs).