Science

Multimedia environments provide multiple resources for expression, collaboration, and knowledge-creation. Yet there is much to be learned about the design of such environments, the forms of collegial discourse that take place, and the benefits of participation. To this end, we study the 2017 STEM for All Video Showcase, a multimodal environment, that enabled educational researchers to share and discuss short videos depicting their federally-funded work to improve STEM education.

From 2012–2015, Advanced Placement (AP) science courses underwent a large-scale curricular reform to include more scientific inquiry and reasoning, reduce emphasis on broad content coverage, and focus on depth of understanding, with corresponding changes in high-stakes AP examinations. In this study, we explored how teachers prepared for and adapted to this reform over a three-year period. Data included four waves of individual interviews with 22 AP Biology and Chemistry teachers across the United States. Data were qualitatively analyzed using emic and etic coding.

Recent reforms in science education have supported the inclusion of engineering in K-12 curricula. To this end, many science classrooms have incorporated engineering units that include design tasks. Design is an integral part of engineering and helps students think in creative and interdisciplinary ways. In this study, we examined middle-school students’ naturally occurring design conversations in small design teams and their learning of science as a result of engaging in an engineering and science unit.

To develop students’ capacity for science and to engage them productively in science and engineering practices, science education reform efforts have focused on supporting teachers’ development of conceptual understandings through engagement with both disciplinary content and practices, including science teaching at the primary level. One topic of importance for primary science instruction focuses on Earth systems and, in particular, hydrological phenomena.

There is a need to arm students with noncognitive, or 21^st Century, skills to prepare them for a more STEM-based job market. As STEM schools are created in a response to this call to action, research is needed to better understand how exemplary STEM schools successfully accomplish this goal. This conversion mixed method study analyzed student work samples and teacher lesson plans from seven exemplary inclusive STEM high schools to better understand at what level teachers at these schools are engaging and developing student 21^st Century skills.

Meaningfully engaging students in the NGSS scientific practices requires that student ideas become the driving force of classroom activity. However, in order for student ideas to take on this new role, teachers must engage in responsive teaching in which they elicit, notice, and respond to the substance of student thinking. In this work, we explore a variety of types of responsive teaching and elaborate a specific type of responsive teaching—what we call epistemologically responsive science teaching.

Application of new automated scoring technologies, such as natural language processing and machine learning, makes it possible to provide automated feedback on students' short written responses. Even though many studies investigated the automated feedback in the computer-mediated learning environments, most of them focused on the multiple-choice items instead of the constructed response items. This study focuses on the latter and investigates a formative feedback system integrated into an online science curriculum module teaching climate change.

The Framework for K‐12 Science Education and the Next Generation Science Standards propose that students learn core ideas and practices related to engineering as well as science. To do so, students will need high‐quality curricular materials designed to meet these goals. We report an efficacy study of an elementary engineering curriculum, Engineering is Elementary (EiE) that includes a set of hypothesized critical components designed to encourage student engagement in practices, connect engineering and science learning, and reach diverse students.

This graphic is designed to support students, teachers, and families in thinking across timescales to understand socio-ecological relationships to place across time.