Projects

The project proposes a longitudinal study that investigates the development of an understanding of measurement across seven grades-from pre-K through Grade 5. Specifically, the project will establish clear cognitive accounts of the development of students' strategic and conceptual knowledge of measurement on increasingly demanding sets of length, perimeter, and area measurement tasks.

Project MSSELL will conduct a two-year randomized trial longitudinal evaluation of an enhanced standards-based science curriculum model. In Year 1, the project will refine and pilot the model based on learnings from its previous developmental phase and implementation with K-3 grade students. In Years 2 and 3, the enhanced model will be implemented and studied with fifth- and sixth-grade students.

This project seeks to improve the science achievement and the academic English language proficiency of middle school Spanish-speaking English language learners (ELLs). This project will conduct a randomized trial longitudinal evaluation of an enhanced standards-based science curriculum model, consisting of five major components: (a) English language acquisition strategies integrated into the science curriculum, (b) technology-assisted instruction, (c) bi-weekly teacher professional development, (d) family involvement, and (e) paraprofessionals in working with individual ELLs.

This project will work in partnership with the Santa Clara Unified School District (SCUSD) to adapt a previously designed Professional Learning (PL) model based on the District's objectives and constraints to build the capacity of teacher leaders and a program coordinator to implement the adapted PL program. The project is examining the sustainability and scalability of a PL model that supports the development of teachers' pedagogical content knowledge and instructional practices. The project is contributing knowledge about how to build capacity in districts to lead professional learning in science that addresses the new teaching and learning standards and is responsive to the needs of their local context.

This project will work in partnership with the Santa Clara Unified School District (SCUSD) to adapt a previously designed Professional Learning (PL) model based on the District's objectives and constraints to build the capacity of teacher leaders and a program coordinator to implement the adapted PL program. The project is examining the sustainability and scalability of a PL model that supports the development of teachers' pedagogical content knowledge and instructional practices. The project is contributing knowledge about how to build capacity in districts to lead professional learning in science that addresses the new teaching and learning standards and is responsive to the needs of their local context.
 

This project will develop and study a prototype online learning environment that supports student learning via Engaging Practices for Inquiry with Collections in Bioscience (EPIC Bioscience), which uses authentic research investigations with digitized collections from natural history museums. 

This project will develop a research-practice partnership to plan and pilot a linguistically and culturally relevant computer science curriculum in middle school with the goal of broadening the participation of emergent bilingual (or English learner) students and Latino/a students in computer science education.

Semiconductors are essential components of electronic devices, enabling advances in important applications and systems such as communication, healthcare, and national security. In order to sustain the U.S.'s global competitiveness in the semiconductor industry, there is a growing demand for a skilled semiconductor workforce. High schoolers are among the most frequent users of electronic devices. However, many do not know how these devices are designed and manufactured. To address the knowledge gaps and workforce needs equitably, this project will develop a semiconductor curriculum with high-school-aged students from diverse backgrounds, and with partners in higher education, K-12, and industries, enhanced with artificial intelligence (AI) and other innovative technologies.

This project targets first- and second-grade children who struggle to develop a deeper understanding of the mathematical strand of number and operation. The research team will (a) identify the various specific cognitive obstacles of first- and second-grade students who are struggling in number and operation, and (b) explore how instructional tasks designed to address specific cognitive obstacles affect the learning trajectory of struggling learners in number and operation.

This comprehensive systematic review and meta-analysis synthesizes evidence surrounding math and science remote education programs from the past 15 years. The goal is to understand the effectiveness of math and science remote education programs; how their effectiveness varies by program characteristics (e.g., fully online vs. hybrid, synchronous vs. asynchronous, and student-instructor ratio); and whether their effects vary with student sample characteristics.

This project is developing technology-rich science curriculum exemplars for grades 3-6 based on Universal Design for Learning (UDL) principles. The project is testing the effectiveness of the approach and providing an exemplar that can inspire additional content and further development. A set of professional development materials to support teacher implementation of UDL science curriculum in the classroom is planned. Probes are used for lab investigations and computational models are used for experimentation in virtual environments.

The purpose of this project is to develop and refine an innovative Google-platform based application called CORGI for use with middle school students in physical, life, and earth science classrooms. The new version, CORGI_2, will include supports for content learning and higher order thinking and will pair with the cloud-based applications of the Google environment to offer multiple means of representation, response and engagement as well as videos, models, supports for decoding, and supports for background knowledge.

The Accessing Science Ideas (ASI) project is developing and researching content enhancements that support science learning of middle school students with executive function and related learning disabilities.  The goal of ASI research is to measure the extent to which curricular units with content enhancements lead to increased student understanding of science concepts, improved reasoning, and greater confidence.

This project will synthesize existing literature on modeling-based instruction (MBI) in K-12 science education over the last three decades. It will rigorously code and examine the literature to conceptualize the landscape of the theoretical frameworks of MBI approaches, identify the effective design features of modeling-based learning environments with an emphasis on technology-enhanced ones, and identify the most effective MBI practices that are associated with successful student learning through a meta-analysis.

Despite the importance of addressing climate change, existing K-12 curricula struggle to make the urgency of the situation personally relevant to students. This project seeks to address this challenge in climate change education by making the abstract, global, and seemingly intractable problem of climate change concrete, local, and actionable for young people. The goal of this project is to develop and test actLocal, an online platform for K–12 teachers, students, and the public to easily create localized climate change adaptation simulations for any location in the contiguous United States. These simulations will enable high school students and others to implement and evaluate strategies to address the impacts of climate change in their own communities.

This project focuses on developing the Adapted Measure of Math Engagement (AM-ME), a culturally sustaining self-report measure of Black and Latina/o middle school students’ mathematics engagement. By developing a measure of mathematics engagement that centers Black and Latina/o students’ experiences, this project offers insight into creating inclusive mathematics learning environments and culturally sustaining understandings of what it means to be engaged in mathematics.

This project focuses on developing the Adapted Measure of Math Engagement (AM-ME), a culturally sustaining self-report measure of Black and Latina/o middle school students’ mathematics engagement. By developing a measure of mathematics engagement that centers Black and Latina/o students’ experiences, this project offers insight into creating inclusive mathematics learning environments and culturally sustaining understandings of what it means to be engaged in mathematics.

EarthX is a design-based research project that supports the integration of Earth science into high school biology, chemistry, and physics courses in Baltimore City Public Schools, while also supporting the district’s transition to three-dimensional (3D), ambitious and equitable science teaching aligned with the Next Generation Science Standards (NGSS). EarthX builds on the success of the Integrating Chemistry and Earth Science (ICE) DRK-12 project, which developed innovative chemistry course curriculum materials and PD strategies, to support Earth science integration into biology and physics course curriculum development and 3D teaching. EarthX will develop, test, and refine embedded and unit assessments for all three courses, along with providing an online system for assessment administration; real-time reporting to teachers and students; and provision of data to PD leaders, administrators, and researchers for multiple purposes. Assessments will be 3D, featuring core concepts from both Earth science and the course discipline combined with a science or engineering practice and a crosscutting concept.

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 research and development project develops and tests in the classroom three fifth-grade and two second-grade science units that combine both socio-cultural and socio-cognitive perspectives in order to more fully engage both students and teachers in authentic inquiry and tests the units in second- and fifth-grade classrooms.

This project is carrying out a research and development initiative to increase the success rates of our most at-risk high school students—ninth-grade students enrolled in algebra classes but significantly underprepared for high school mathematics. It will also result in new understandings about effective approaches for teaching mathematics to struggling students and about effective ways for implementing these approaches at scale, particularly in urban school districts.

The project team will conduct an efficacy study of a new comprehensive science curriculum for middle grades 6-8 called Amplify Science Middle School (ASMS). This school science curriculum integrates disciplinary core ideas, science and engineering practices, and crosscutting concepts. The overarching aim of the study will be to understand the impact of the curriculum on student achievement, classroom implementation, and teacher practice in relation to the recommendations of "A Framework for K-12 Science Education" and the Next Generation of Science Standards.

Using an experimental design, this project examines the effects of online professional development courses on high school biology teachers' content and pedagogical knowledge, and on their students' knowledge. The project is testing the impact of using digital resouces and is using hierarchal linear modeling techniques to analyze data. It will contribute to the knowledge base of what impacts student achievement by testing the efficacy of online professional development for science teachers.

This project will study if, how, and under what circumstances an integration of literacy strategies, hands-on inquiry-based investigations, and planetarium experiences supports the development of science practices (noticing, recognizing change, making predictions, and constructing explanations) in early elementary level students. The project will generate knowledge about how astronomy-focused storybooks, hands-on investigations, and planetarium experiences can be integrated to develop age-appropriate science practices in very young children.

This project aims to create a web-based STEM Career Exploration and Readiness Environment (CEE-STEM) that will support opportunities for youth ages 16-24 who are neither in school nor are working, in rebuilding engagement in STEM learning and developing STEM skills and capacities relevant to diverse postsecondary education/training and employment pathways.