Counterspaces in science, technology, engineering, and mathematics (STEM) are often considered “safe spaces” at the margins for groups outside the mainstream of STEM education. The prevailing culture and structural manifestations in STEM have traditionally privileged norms of success that favor competitive, individualistic, and solitary practices—norms associated with White male scientists. This privilege extends to structures that govern learning and mark progress in STEM education that have marginalized groups that do not reflect the gender, race, or ethnicity conventionally associated with
Described by Wohlwend, Peppler, Keune and Thompson (2017) as “a range of activities that blend design and technology, including textile crafts, robotics, electronics, digital fabrication, mechanical repair or creation, tinkering with everyday appliances, digital storytelling, arts and crafts—in short, fabricating with new technologies to create almost anything” (p. 445), making can open new possibilities for applied, interdisciplinary learning in science, technology, engineering and mathematics (Martin, 2015), in ways that decenter and democratize access to ideas, and promote the construction
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TEAM MEMBERS:
Jill CastekMichelle Schira HagermanRebecca Woodland
Awareness of a STEM discipline is a complex construct to operationalize; a learner’s awareness of a discipline is sometimes viewed through the lens of personal identity, use of relevant discourse, or knowledge of career pathways. This research proposes defining engineering awareness through a learner’s associations with engineering practices - fundamental processes involved in engineering such as identifying criteria and constraints, testing designs, diagnosing issues and assessing goal completion. In this study, a learner’s engineering awareness was determined by examining 1) their ability to
This paper provides detailed descriptions of the goals, theoretical perspectives, context, and methods used in A study of collaborative practices at interactive engineering challenge exhibits (the C-PIECE Study), the first of two studies in the Designing Our Tomorrow (DOT) research program. The C-PIECE Study supported foundational and exploratory lines of inquiry related to engineering practices used by families engaging with design challenge exhibits. This paper describes the study background and methods as an anchor to four other products that detail these four specific lines of inquiry and
The purpose of this research was to explore associations between engineering practices included in the C-PIECE framework. In this work, we took particular interest in practices under the Defining a Problem proficiency. Practices under Defining a Problem have great potential to influence the entire exhibit interaction and early observations indicated that visitor groups did not engage frequently in these practices at the informed level, therefore they were seen as an opportunity ripe for study. Through observations, interviews, and video analysis, the DOT research team investigated the
Are you interested in co-creating fun activities that exercise groups’ engineering practices? Are you curious about the types of practices that groups can exercise through exhibits?
The Framework of Collaborative Practices at Interactive Engineering Challenge Exhibits (C-PIECE Framework) provides informal education professionals with a guide when co-developing, designing, facilitating, evaluating and researching engineering design challenge experiences.
This framework was developed with input from inter-generational families, including girls 9 to 14 years old. It was adapted from theory
Our museum-based participatory research (PR) project was a collaboration between researchers and educators in an out-of-school time STEM education program for young people that positions STEM as a tool for community social justice. This project drew on literatures on reflective practice in museums and on research-practice partnerships. Yet following existing approaches did not work for us. Aligning research and pedagogical practices, we co-created practical, reflective, and practice-based data generation methods, calling them “embedded research practices:” context-specific, emergent methods
This brief focuses on a participatory study with the high school program of the Kitty Andersen Youth Science Center (KAYSC) at the Science Museum of Minnesota (SMM). Young people are organized into teams of up to 20 youth with an adult practitioner who delivers programming based on a STEM content area. Their activities and project-based learning are based in both STEM and social justice, coined in the KAYSC as “STEM Justice.”
As part of our study, we wanted to understand youth and adult needs that exist in an informal STEM education program that weaves equity into its core. This brief
The theory of “science capital” is increasingly showing up in formal and informal science education. Both face the common challenge of what is often called a “theory/practice divide”: academic theory not seeming relevant to the day-to-day needs and practices of educators.
This brief shares what happened when practitioners and researchers working with the Kitty Andersen Youth Science Center (KAYSC) at the Science Museum of Minnesota took both theory and practice seriously, reclaiming terms and ideas in service of our work and communities. It explores how an informal science learning (ISL)
This brief shares youth development insights from a museum-based, informal science learning program that uses STEM as a tool for social justice. Key to the success of this program were young people and adults feeling at home in a welcoming, diverse, and inclusive space; activities that focused on connecting and relationships; a holistically supportive space that attended to family and personal needs; shared norms for conversation and expectations; and science content grounded in young people’s lives, experiences, and communities as well as work with community members.
These needs were
We characterize the factors that determine who becomes an inventor in the United States, focusing on the role of inventive ability (“nature”) vs. environment (“nurture”). Using deidentified data on 1.2 million inventors from patent records linked to tax records, we first show that children’s chances of becoming inventors vary sharply with characteristics at birth, such as their race, gender, and parents’ socioeconomic class. For example, children from high-income (top 1%) families are ten times as likely to become inventors as those from below-median income families. These gaps persist even
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TEAM MEMBERS:
Alex BellRaj ChettyXavier JaravelNeviana PetkovaJohn Van Reenen
Exhibit Design for Girls’ Engagement (EDGE) began as an NSF-funded research project led by the Exploratorium to learn how science museums can better engage girls aged 8–13 with STEM exhibits. Over the course of the research, we identified nine design attributes that were consistently positively related to girls’ engagement with these exhibits. The Exploratorium then went on a three-year journey funded by the Gordon & Betty Moore Foundation to explore ways to fold the EDGE design attributes into our exhibits, with a focus on existing exhibits. This was an exciting opportunity to put the EDGE