K-12 science teachers in the United States are encouraged to teach their students engineering. When incorporating engineering into their science curricula, teachers commonly either focus on: (1) engineering and lace science throughout; or (2) science and lace engineering throughout. This study explores middle school students' nature of engineering…

The aim with this study was to analyse and explore how physical sciences, engineering science and technology subjects (technical electrical technology, technical civil technology, technical mechanical technology) can contribute to the alignment of the technical sciences curriculum. We used document analysis to collect data. An analysis of the…

To promote rich discourse around scientific and engineering practices, teachers may turn to engineering design-based science curricula; however, this has discursive demands which have yet to be examined in a unit focused on integration of engineering and science. To investigate these discursive demands, we expand on the definition of discourse to…

Given the current emphasis on science, technology, engineering, and math (STEM) education and its key attributes, middle school is an optimal time to implement STEM-based curricula. However, the interdisciplinary and open-ended nature of STEM projects often makes implementation difficult. In this article, we describe a professional development…

Yuan Ze University targeted Biomaterials Science and developed a curriculum related to Biotechnology, Biochemical Engineering, and Biomaterials for engineering students to cultivate talents for both engineering and biotechnology. After several years of operation, recruiting students has succeeded, and students are satisfied with the course design…

Mechatronic systems that couple mechanical and electrical systems with the help of computer control are forcing a paradigm shift in the design, manufacture, and implementation of mechanical devices. The inherently interdisciplinary nature of these systems generates exciting new opportunities for developing a hands-on, inventive, and…

The world faces a number of complex challenges that are sometimes referred to as "wicked problems." Universities have been relatively poor at preparing graduates for such challenges, yet it will be the future professionals who need to tackle the problems. This essay looks at two related projects that have attempted to advance the skills…

A wide range of biotechnological and biomedical processes and products involves the design, synthesis, and analysis of biological interfaces. Such biointerfaces mediate interactions between living cells or intracellular species and designed materials or biologics. Incorporating the experiences of a NSF-­sponsored IGERT (Integrative Graduate…

Industrial chemistry in general and catalysis in particular should be included as part of college chemistry curricula. (JN)

Describes an interdisciplinary chemistry course at the New Jersey Institute of Technology (NJIT) in which at least one quarter of the time is devoted to materials science. Includes information on course content, laboratory work, and assessment of student performance on chemistry and materials science topics. (JN)

Examines reasons for dissatisfaction with the limitations of single-discipline approaches to engineering education. Considers the development of a systems-based interdisciplinary course. Provides an example at the University of Bradford. (YP)

Describes the development of systems thinking and the form taken in the study of work and organizations. Discusses some criticisms from social scientists. Explores the relationship among systems, interdisciplinarity, and engineering education. (Author/YP)

Discusses the necessity of interdisciplinary and systems approaches in engineering education for analyzing complex issues. Presents several recent problems. (YP)

Recommends systems subjects as part of college curricula for providing students with broader skills and with background that does not become outdated. Topics included are requirements of a basic examination, cooperation with other professionals, and examples of systems technologies and interdisciplinary research. (Author/YP)

Argues that systems thinking can be developed by experiential learning activities which complement both intradisciplinary projects and technical knowledge inputs. Discusses the development of systems thinking, the form of engineering curricula, and assessment. (Author/YP)