Projects

This project is building a set of software tools, including a tool for annotating screen recordings of activities in games, a teacher data dashboard for information about students' in-game learning, and tools to help teachers customize activities in games to better align with curricular standards. The project will find out whether these new tools can enhance teaching and/or learning. 

The Graphing Research on Inquiry with Data in Science (GRIDS) project will investigate strategies to improve middle school students' science learning by focusing on student ability to interpret and use graphs. GRIDS will undertake a comprehensive program to address the need for improved graph comprehension. The project will create, study, and disseminate technology-based assessments, technologies that aid graph interpretation, instructional designs, professional development, and learning materials.

This project  will develop a video recording and analysis system called VideoReView (VRV) that allows grade four science teachers to record, tag, and analyze video in their classroom in real time. The investigators will then study and enhance the system in the context of professional learning communities of teachers. 

This project will develop and evaluate a module for use in a 7th grade classroom that promotes student development of 21st Century skills with a particular focus on student development of scientific reasoning. The technology-enhanced curriculum will be designed to engage learners in deep and meaningful investigations to promote student learning of content in parallel with 21st century skills.

This project will develop and investigate the opportunities and limitations of Focus on Energy, a professional development (PD) system for elementary teachers (grades 3-5). The PD will contain: resources that will help teachers to interpret, evaluate and cultivate students' ideas about energy; classroom activities to help them to identify, track and represent energy forms and flows; and supports to help them in engaging students in these activities.

Identifying with engineering is critical to help students pursue engineering careers. This project responds to this persistent large-scale problem. The I-Engineering framework and tools address both the learning problem (supporting students in learning engineering design) and the identity problem (supporting students in recognizing that they belong in engineering). 

This is an exploratory project that will research and develop resources and a model for professional learning needed to meet the demand of implementing the Next Generation Science Standards (NGSS). The Exploratorium Teacher Institute will engage middle school science teachers in a one-year professional learning program to study how familiar routines and classroom tools, specifically hands-on science activities, can serve as starting points for teacher learning.

This project investigates how real time formative feedback can be automatically composed from the results of computational analysis of student design artifacts and processes with the envisioned SmartCAD software. The project conducts design-based research on SmartCAD, which supports secondary science and engineering with three embedded computational engines capable of simulating the mechanical, thermal, and solar performance of the built environment.

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 brings together leaders in simulation design and accessibility to develop and study interactive science simulations for diverse middle school students including those with sensory, mobility, or learning disabilities. The resulting simulations and research findings will help to address the significant disparity that exists between the achievement in science by students with and without disabilities.

This project builds upon the widely used K-12 Misconception Oriented Standards-based Assessment Resource for Teachers (MOSART). The project is developing 500 new test items that are intended to assess disciplinary core ideas in chemistry and physics aligned to Next Generation Science Standards. The new measures will be used to measure the knowledge acquired in a year of study by 10,000 students and 200 teachers in chemistry and physics.

For this project, researchers will iteratively develop simulations to include sonifications, non-speech sounds that represent visual information, aimed at enhancing accessibility for all learners, but particularly for those with visual impairments to produce sonified simulations, professional development resources, design guidelines and exemplars, and publications.

This project assesses the impact of scaling-up the teaching of physics and engineering to women students in grade levels 11 and 12, particularly in reference to retention. The aim is to mobilize high school physics teachers to "attract and recruit" female students into physics and engineering careers. The project will advance physics identity research by testing research-based approaches/interventions with larger groups of teachers and connecting research to practice in ways that are both widely deployable and practical for teachers to implement.

This project assesses the impact of scaling-up the teaching of physics and engineering to women students in grade levels 11 and 12, particularly in reference to retention. The aim is to mobilize high school physics teachers to "attract and recruit" female students into physics and engineering careers. The project will advance physics identity research by testing research-based approaches/interventions with larger groups of teachers and connecting research to practice in ways that are both widely deployable and practical for teachers to implement.

This project assesses the impact of scaling-up the teaching of physics and engineering to women students in grade levels 11 and 12, particularly in reference to retention. The aim is to mobilize high school physics teachers to "attract and recruit" female students into physics and engineering careers. The project will advance physics identity research by testing research-based approaches/interventions with larger groups of teachers and connecting research to practice in ways that are both widely deployable and practical for teachers to implement.

This project assesses the impact of scaling-up the teaching of physics and engineering to women students in grade levels 11 and 12, particularly in reference to retention. The aim is to mobilize high school physics teachers to "attract and recruit" female students into physics and engineering careers. The project will advance physics identity research by testing research-based approaches/interventions with larger groups of teachers and connecting research to practice in ways that are both widely deployable and practical for teachers to implement.

Project Accelerate blends the supportive structures of a student's home school, a rigorous online course designed specifically with the needs of under-served populations in mind, and hands-on laboratory experiences, to make AP Physics accessible to under-served students. The project could potentially lead to the success of motivated but under-served students who attend schools where the opportunity to engage in a rigorous STEM curriculum is not available.

This project focuses on the research and develop an engineering education technology and pedagogy that will support project-based learning of science, engineering, and computation concepts and skills underlying the strategically important "smart" and "green" aspects of the infrastructure. The project will develop transformative technologies and curriculum materials to turn the campus of a high school or a geographical information system such as Google Maps into an engineering laboratory with virtually unlimited opportunities for learning and exploration.

This project proposes to design, implement, and investigate the impact on students of an innovative curriculum supplement called the Spectrum Laboratory. The Spectrum Lab will be an online, interactive learning environment that enables students to make use of the database of publicly available spectra from research scientists, as well as from students.

This project will engage science teachers in a sustained professional development (PD) program embedded in an afterschool science program designed for a linguistically diverse group of English learners (ELs).

The goal of this study is to improve elementary science teaching and learning by developing, testing, and refining a framework and set of tools for strategically incorporating forms of uncertainty central to scientists' sense-making into students' empirical learning.

The fundamental purpose of this project is to examine and gather initial validity evidence for assessments designed to measure and build kindergarten-fifth grade science teachers' content knowledge for teaching (CKT) about matter and its interactions in teacher education settings.

The main goal of this project is to better understand how to build and sustain the capacity of elementary science teachers in grades 3-5 to instruct and formatively assess students in ways that are aligned with contemporary science education frameworks and standards. To achieve this goal, the project will use classroom-based science assessment as a focus around which to build teacher capacity in science instruction and three-dimensional learning in science.

This project will address the need for engineering resources by applying an innovative pedagogy called Imaginative Education (IE) to create middle school engineering curricula. In IE, developmentally appropriate narratives are used to design learning environments that help learners engage with content and organize their knowledge productively. This project will combine IE with transmedia storytelling.

This project will address the need for engineering resources by applying an innovative pedagogy called Imaginative Education (IE) to create middle school engineering curricula. In IE, developmentally appropriate narratives are used to design learning environments that help learners engage with content and organize their knowledge productively. This project will combine IE with transmedia storytelling.