Projects

This project develops resources to facilitate the involvement of college and university physics departments in the professional development of K-12 teachers of physics and physical science. Research investigates how students and teachers learn content and reasoning skills for applying concepts to real world situations; how teachers can learn content in a way that helps them promote student learning; and how teachers can learn to assess student understanding in a way that promotes student learning.

The goal of this project is to improve the implementation of rigorous instructional materials in middle-grades mathematics at scale through a system of practical measures and routines for collecting and using data that both assesses and supports implementation.

This project will study the aspects of genetics instruction that affect students' beliefs in neurogenetic essentialism, which is implicated in lowering girls' sense of STEM abilities, feeling of belonging in STEM classes, and interest in pursuing further education in STEM fields. The goal of the project is to answer important questions about how to teach genetics at the high school level in a manner that is scientifically accurate but does not have these detrimental side effects.

Coding is a key part of computer science, and promoting opportunities that engage learners in coding is vital to the U.S. workforce development. This project builds upon prior research that created a free coding app, OctoStudio, which is widely available for use in elementary and secondary schools. The goals of the project are twofold: First, the team will develop and design features that broaden the technology so that it is more accessible for more users. Second, the team will explore the usability of these new features across potential users. The new features will have potential to allow blind and low vision users to meaningfully engage in coding, which ultimately benefits society by broadening the STEM workforce and bringing coding to a greater population of students.

The goal of this project is to expand high school student participation in the peer-review process and in publishing in JEI, a science journal dedicated to mentoring pre-college students through peer-reviewed publication. By publishing pre-college research in an open access website, the project will build understanding of how engaging in these activities can change high school students' perceptions and practices of scientific inquiry.

This is a continuing research project that supports (1) creation of what are termed "ink inscriptions"--handwritten sketches, graphs, maps, notes, etc. made on a computer using a pen-based interface, and (2) in-class communication of ink inscriptions via a set of connected wireless tablet computers. The primary products are substantiated research findings on the use of tablet computers and inscriptions in 4th and 5th grade math and science, as well as models for teacher education and use.

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 uses sea urchin embryos to provide a curriculum module for inquiry-based biology. The curriculum is provided via a new open access website. It addresses several of the National Science Content Standards and provides a range of activities suitable for all levels of high school biology. It will provide instructional support materials such as video demonstrations, animations, time lapse videos and image galleries relevant to each exercise, as well as professional development materials.

This project develops, implements, and evaluates new multimedia laboratory activities designed to engage students in science, technology, engineering, and mathematics (STEM). The project specifically targets artistically gifted students who are often steered towards more traditionally creative areas (e.g., arts and humanities) and away from STEM. The goals to help students understand that scientific principles permeate the creative and performing arts and that creativity and expression are also embraced by STEM.

This project will design, develop, and test a new curriculum unit for high school chemistry courses that is organized around the question, "How does chemistry shape where I live?" The new unit will integrate relevant Earth science data, scientific practices, and key urban environmental research findings with the chemistry curriculum to gain insights into factors that support the approach to teaching and learning advocated by current science curriculum standards.

This project builds and tests applications tied to the school curriculum that integrate the sciences with mathematics, computational thinking, reading and writing in elementary schools. The investigative core of the project is to determine how to best integrate computing across the curriculum in such a way as to support STEM learning and lead more urban children to STEM career paths.

This project is developing and testing curriculum materials and a professional development model designed to explore the potential for introducing engineering concepts in grades 3 - 5 through design challenges based on stories in popular children's literature. The research team hypothesizes that professional development for elementary teachers using an interdisciplinary method for combining literature with engineering design challenges will increase the implementation of engineering in 3-5 classrooms and have positive impacts on students.

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 is developing curricular materials that utilize best teaching practices in improving student understanding of statistics and data science for use in high school Algebra I, Algebra II, and Geometry courses.  Although teachers are encouraged to integrate statistics and data science in these kinds of high school courses, teachers do not have sufficient access to resources to accomplish this effectively. The distinctive feature of these curricular materials is the use of simulation-based inference methods, data visualization, and the entire statistical investigation process to improve students’ understanding of the relevance and power of statistics because these approaches are central to statistical thinking and practice.

This project will investigate the integration of engineering design, practices, and thinking into middle school life science curriculum while providing opportunities for students to foster knowledge of and increase interest in life and biosciences. The project will specifically respond to the need to create, implement, and evaluate a model intervention that will advance the knowledge base for establishing and retaining underrepresented minorities in STEM fields.

The project aims to develop and research Intelligent Science Stations, a new genre of interactive science experiences. The Intelligent Science Stations will provide students in kindergarten to 4th grade with hands-on science experiences, augmented by an intelligent agent that offers feedback based on artificial intelligence computer vision. This innovative approach offers evidence-based, personalized support and feedback to children, while also assisting teachers in integrating more inquiry-based science learning into their classrooms. By modeling behaviors like asking questions, making predictions, and explaining scientific phenomena, the interactive AI system helps teachers enhance their classroom experiences.

While simulations are powerful tools for scientific inquiry, most students need scaffolding to engage productively in simulation-based inquiry. This project will develop and study an automated feedback system designed to support middle school students' simulation-based inquiry into wildfires, floods, and hurricanes. The system, called Hazbot, will leverage advanced artificial intelligence (AI) technologies—including machine learning and large language models (LLMs)—to provide timely, personalized feedback as students investigate the three different natural hazards.

Students who fail algebra in the ninth grade are significantly less likely than their peers to graduate from high school on time. This project intends to test a common support strategy for at-risk students that provides an extra period of algebra, commonly known as a "double dose" condition. The Intensified Algebra (IA) is an intervention that addresses both the academic and non-academic needs of students.

This exploratory project seeks to understand the role that a network of tablet computers may play in elementary and middle school math and science classrooms. The project uses classroom observations, student interviews, teacher interviews, and student artifacts to identify the advantages and disadvantages of these resources, to understand what challenges and benefits they offer to teachers, and to offer recommendations for future hardware, software, and curriculum development.

This project examines the first-year implementation of a program that will provide low-cost netbook computers and specialized software to fifth and sixth grade students in four schools in Southern California. The PIs collect baseline and early implementation data to determine effects of the intervention on students' academic achievement in science, academic writing in science, and interest in further STEM study.

Research has shown that when teachers have strong content and pedagogical content knowledge that they can provide better quality mathematics instruction to their students and improve student outcomes. The goal of this project is to enhance elementary school teachers’ capacity to improve students’ mathematics learning through a scaled professional development program that uses artificial intelligence (AI) to create a personalized, active learning environment for teachers.

This project designs, constructs, and field-tests a web-based, online collaborative environment for supporting the teaching and learning of inquiry-based high school physics. Based on an interactive digital workbook environment, the team is customizing the platform to include scaffolds and other supports for learning physics, fostering interaction and collaboration within the classroom, and facilitating a design-based approach to scientific experiments.

This award will support teacher practitioners from the U.S. to attend the 2020 International Mind, Brain, and Education Society (IMBES) conference. The IMBES conference is an opportunity for scholars and educators to come together to engage in reciprocal dialogue about research and practice in biology, education, and the cognitive and developmental sciences.

This curriculum development and professional development program includes residential summer institutes with academic-year online communication for in-service teachers involved in professional development of their colleagues. During each summer institute, teachers will be introduced to sets of STEM Polar Connections Modules that will emphasize the process of scientific inquiry and will explore a variety of proven techniques for effective teaching, including inquiry-based teaching, cooperative learning, and methods for formative assessment of student learning.

The goal of this workshop is to advance the construction of new knowledge through international cooperation with Chinese counterparts in the teaching and learning of math and science at the elementary level in four areas: curriculum design and assessment; teacher preparation and professional development; effective use of the former; and reaching gifted and underserved populations. Approximately 120 people will attend, including 50 senior U.S. researchers, 25 early career researchers, 15 graduate students and 5 undergraduates.