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Abstract Hundreds of studies have explored student evolution acceptance because evolution is a core concept of biology that many undergraduate biology students struggle to accept. However, this construct of “evolution acceptance” has been defined and measured in various ways, which has led to inconsistencies across studies and difficulties in comparing results from different studies. Many studies and essays have offered evaluations and perspectives of evolution acceptance instruments, but publications with a focus on consensus building across research teams is still needed. Further, little attention has been paid to how evolution acceptance instruments may be interpreted differently by students with varied religious backgrounds. Funded by a Research Coordination Network in Undergraduate Biology Education grant from the National Science Foundation, we gathered 16 experts from different disciplinary and religious backgrounds to review current evolution acceptance instruments and create a guide to the strengths and weaknesses of these instruments, including appropriate contexts for using these instruments and their potential weaknesses with different religious populations. Finally, in an attempt to move the field forward, we articulated a consensus definition of evolution acceptance that can be used to guide future instrument development. 

University-based makerspaces are receiving increasing attention as promising innovations that may contribute to the development of future engineers. Using a theory of social boundary spaces, we investigated whether the diverse experiences offered at university-based makerspaces may contribute to students’ learning and development of various “soft” or “21st century” skills that go beyond engineering-specific content knowledge. Through interviews with undergraduate student users at two university-based makerspaces in the United States we identified seven different types of boundary spaces (where multiple communities, and the individuals and activities affiliated with those communities, come together). We identified students engaging in the processes of identification, reflection, and coordination, which allowed them to make sense of, and navigate, the various boundary spaces they encountered in the makerspaces. These processes provided students with opportunities to engage with, and learn from, individuals and practices affiliated with various communities and disciplines. These opportunities can lead to students’ development of necessary skills to creatively and collaboratively address interdisciplinary socio-scientific problems. We suggest that university-based makerspaces can offer important developmental experiences for a diverse body of students that may be challenging for a single university department, program, or course to offer. Based on these findings, we recommend university programs and faculty intentionally integrate makerspace activities into undergraduate curricula to support students’ development of skills, knowledge, and practices relevant for engineering as well as 21st century skills more broadly. 

In the last decade, postsecondary institutions have seen a notable increase in makerspaces on their campuses and the integration of these spaces into engineering programs. Yet research into the efficacy of university-based makerspaces is sparse. We contribute to this nascent body of research in reporting on findings from a phenomenological study on the perceptions of faculty, staff, and students concerning six university-based makerspaces in the United States. We discuss the findings using a framework of heterogeneous engineering (integration of the social and technical aspects of engineering practice). Various physical, climate, and programmatic features of makerspaces were read as affordances for students’ development of engineering practices and their continued participation and persistence in engineering. We discuss the potential of makerspaces in helping students develop knowledge, skills, and proclivities that may support their attending to especially wicked societal problems, such as issues of sustainability. We offer implications for makerspace administrators, engineering program leaders, faculty, and staff, as well as those developing and delivering professional development for faculty and staff, to better incorporate makerspaces into the university engineering curriculum.