Science

In a project designed to help create the next generation of problem-solvers, North Carolina State University researchers challenged a group of 11^th graders to investigate and find solutions to a global problem: that billions of people lack access to clean water and sanitation services.

This week is Global Goals week — an annual week of action, awareness, and accountability for the United Nations’ Sustainable Development Goals, which are aimed at addressing global challenges like poverty and hunger. In North Carolina, two schools have integrated purpose-driven, interdisciplinary, and collaborative inquiry into their classrooms to empower students and teachers as local and global change agents during a particularly uncertain school year.

This study explored how engaging in critical inquiry through Project-Based Inquiry (PBI) Global fostered social action with high school students. Drawing on theoretical perspectives from critical inquiry and social action and employing a collective case study approach, we focused on six diverse students from two of the 18 teams who participated in a PBI Global examining global water and sanitation over a two-month period.

Humankind faces unprecedented environmental, social, and economic challenges. There is a critical need for STEM education to foster both science learning and the application of learning to problem solving. At the University of Utah, Professor Nancy Butler Songer and her collaborators have developed a suite of interdisciplinary instructional and field-based data collection resources offering elementary and secondary students the chance to create solutions for local, urban environmental issues.

This article addresses the need and potential for students to develop problem-solving skills as part of STEM learning.

It is vital to develop an understanding of students' self-regulatory processes in the domains of STEM (Science, Technology, Engineering, and Mathematics) for the quality delivery of STEM education. However, most studies have followed a variable-centered approach, leaving open the question of how specific SRL (Self-regulated Learning) behaviors group within individual learners. Furthermore, little is known about how students' SRL profiles unfold over time in STEM education, specifically in the context of engineering design. In this study, we examined the change of students’ SRL profiles over time as 108 middle school students designed green buildings in a simulation-based computer-aided design (CAD) environment

From a network perspective, self-regulated learning (SRL) can be conceptualized as networks of mutually interacting self-regulatory learning behaviors. Nevertheless, the research on how SRL behaviors dynamically interact over time in a network architecture is still in its infancy, especially in the context of STEM (sciences, technology, engineering, and math) learning. In the present paper, we used a multilevel vector autoregression (VAR) model to examine the temporal dynamics of SRL behaviors as 101 students designed green buildings in Energy3D, a simulation-based computer-aided design (CAD) environment.

This multiple case study focused on the implementation of a computer-aided design (CAD) simulation to help students engage in engineering design to learn science concepts. Our findings describe three case studies that adopted the same learning design and adapted it to three different populations, settings, and classroom contexts: at the middle-school, high-school, and pre-service teaching levels.

This multiple case study focused on the implementation of a computer-aided design (CAD) simulation to help students engage in engineering design to learn science concepts. Our findings describe three case studies that adopted the same learning design and adapted it to three different populations, settings, and classroom contexts: at the middle-school, high-school, and pre-service teaching levels.

This multiple case study focused on the implementation of a computer-aided design (CAD) simulation to help students engage in engineering design to learn science concepts. Our findings describe three case studies that adopted the same learning design and adapted it to three different populations, settings, and classroom contexts: at the middle-school, high-school, and pre-service teaching levels.