The purpose of this paper is to explore results from a qualitative study of how high school aged BLV youth used spatial language during a virtual engineering experience administered by the National Federation of the Blind (NFB). Findings from this study can provide recommendations to enhance language in curricula that better reflects BLV students' content and may ultimately encourage more BLV students to pursue careers in STEM fields.
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TEAM MEMBERS:
Gary TimkoNatalie ShaheenWade GoodridgeTheresa GreenDaniel Kane
Informal STEM learning experiences (ISLEs), such as participating in science, computing, and engineering clubs and camps, have been associated with the development of youth’s science, technology, engineering, and mathematics interests and career aspirations. However, research on ISLEs predominantly focuses on institutional settings such as museums and science centers, which are often discursively inaccessible to youth who identify with minoritized demographic groups. Using latent class analysis, we identify five general profiles (i.e., classes) of childhood participation in ISLEs from data
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TEAM MEMBERS:
Remy DouHeidi CianZahra HazariPhilip SadlerGerhard Sonnert
National Foundation for the Blind (NFB) Engineering Quotient (EQ) for Teachers is a free, online curriculum and collection of resources for educators who want to teach NFB EQ, the National Federation of the Blind’s week-long engineering program designed for blind and low-vision youth.
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TEAM MEMBERS:
Natalie ShaheenWade GoodridgeSarah LopezPeter AndersonAnn CunninghamDavid Nietfeld
Early learning experiences for children have the potential to make a lasting impression on a young person, and ultimately influence their interests, school trajectories, and professional careers. As such, there has been an increasing effort to understand what can make these experiences more or less productive for young people, particularly in science, technology, engineering, and mathematics fields that face ongoing challenges related to workforce development. A better understanding of what happens during and after early engineering activities - and in particular, what contributes to a productive and engaging experience for children between the ages of 3 and 5 - can inform the design of new activities and potentially catalyze greater interest and learning about engineering at a young age. This study seeks to add new knowledge in this area by exploring how and why different elements of engineering activities for young children might be more or less effective for early learners. In addition, the study also examines engagement and interest related to engineering at the family level, acknowledging the essential roles that parents and families play in the overall development of young children. Finally, this study includes a specific focus on low-income and Spanish-speaking families, thereby engaging with communities that historically have less access to early science and engineering learning opportunities and remain persistently underrepresented in these fields. In order to maximize the impact of this research, findings from this study will be shared broadly with parents, educators, and researchers from multiple fields such as engineering education, child development, and informal/out-of-school time education.
This study has the potential to have a transformative impact on engineering education by developing both educational products and conceptual frameworks that advance the field's knowledge of how to effectively engage young learners and their parents/caregivers in meaningful and productive engineering learning experiences. This study seeks to break new ground at the frontiers of early childhood engineering, specifically through a) articulating and refining a new integrated conceptual framework that weaves together theories of learning and development with theoretical constructs from engineering design and b) applying and refining this integrated framework when creating, implementing, assessing, and revising components of family-based engineering activities for early learners, particularly those from low-income and Spanish-speaking families. Unlike many other early childhood engineering programs, this project focuses on the family context, which is the primary driver of learning and interest development at this age. The study therefore provides an opportunity to advance the field by both helping young children build engineering skills and interests before starting kindergarten while also empowering parents to support their children's engineering education at a critical developmental period. Additionally, by enhancing parent-child interactions and supporting a range of early childhood development goals, this project will also contribute to efforts to decrease the persistent kindergarten readiness gap across racial, ethnic, and socioeconomic groups. The research ultimately supports efforts to increase the diversity of individuals who will potentially enter the engineering workforce.
Interest is a critical motivating factor shaping how children engage with STEM inside and outside of school and across their lives. In this paper, we introduce the concept of interest catalyst that emerged from longitudinal research with preschool-age children and their families as critical to the process through which each family developed unique interest pathways through their experience with a family-based informal engineering education program. As defined by the team, an interest catalyst is an instance or moment in which an element of the program (or other learning resource or experience)
In collaboration with Metropolitan Family Service (MFS), we conducted a three-year design-based research study to better understand how the characteristics of hands-on, home-based family engineering activities influence how preschool-age children and their parents engage in the engineering design process. Four themes emerged from the study: (1) Families used their imagination and activity narrative elements to set the design context, (2) Families evaluated and revised their solutions based on imagination-driven constraints, (3) Families creatively modified the design space, and (4) Imaginative
This poster was presented at the 2021 NSF AISL Awardee Meeting.
Head Start on Engineering is an ongoing initiative focused on empowering families to use engineering to help their children thrive. We aspire to collaborate as equal partners with the communities we serve and inform a more equitable vision for engineering education in our society.
This award is funded in part under the American Rescue Plan Act of 2021 (Public Law 117-2).
It has been well documented that under-resourced Latinx communities face persistent barriers to accessing quality STEM education and STEM careers, particularly in the field of engineering. For young children and their families from these communities, the development of executive function skills offers promising pathways to support educational success and prepare children to engage with STEM practices and content. Executive function skills, such as focusing attention, retaining information, and managing emotions are critical for children’s development and long-term success, and have been identified as central to engagement with STEM practices and content, whether in or out of school. However, much of the work on development of executive function skills to date has been conducted with White, middle-class children and has largely ignored the knowledge, values, or perspectives of other communities, including Latinx families. Similar gaps also exist in attention to culturally responsive approaches to using family-based STEM activities to support executive function skills. Taken together, there is a critical need to work with Latinx communities to re-imagine the intersection of STEM learning and executive function skills using equity-based frameworks. This Pilot and Feasibility project will develop and test a new participatory, dialogic method that leverages informal family engineering activities to support the development of executive function skills for preschool-age children from Latinx families. The combination of this proposal’s unique engagement of parents as research partners with the study of engineering and executive functions could lay the foundation for a promising program of future equity-focused research.
Three research questions will guide the study: 1) What knowledge, assets, and practices already exist within Latinx families related to these executive function skills? 2) What aspects of executive function skills can be supported through informal family engineering activities? and 3) What are promising design strategies for adapting informal family engineering activities to highlight family assets and support executive function skills for young children? To address these questions, the project team will engage Latinx parents in a dialogue series in which parents are central collaborators, sharing their in-depth perspectives and partnering with researchers to develop conceptual frameworks and new approaches. Data generated through these ongoing discussions will be analyzed using (a) qualitative, participatory approaches, including iterative co-development and refinement of emergent themes with parents, (b) detailed inductive coding of parent dialogue group discussions using grounded theory techniques, and (c) retrospective analysis at the end of the project. The parent dialogue series will be supported by a systematic literature review examining the intersections between engineering design, executive function, and the strengths and assets within Latinx families. The results of the exploratory research will include a (1) conceptual framework co-developed with parents that highlights promising opportunities and design strategies for using family engineering design activities to support executive function skills for preschool-age children from Latinx families and (2) research agenda outlining questions and priorities for future work that reflect the goals and interests of this community. Aligned with project’s equity approach, the team will work collaboratively with project partners and families for dissemination, focusing on amplifying community voices, sharing challenges and successes, and supporting improvements in the local community. Results will also be broadly shared with educators and researchers to advance knowledge and promote new equitable approaches to collaborating with parents from Latinx communities.
This Pilots and Feasibility project is funded by the Advancing Informal STEM Learning (AISL) program.
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 document provides a brief story about how the Designing our Tomorrow team explored some of their questions about exhibit features by using the C-PIECE Framework: Framework of Collaborative Practices at Interactive Engineering Challenge Exhibits.
This exploratory line of inquiry looked at relationships between exhibit features and visitor groups’ Informed engineering design practices. This brief includes an Introduction, Methods and Findings, Summary, and Implications.
This exploratory line of inquiry was conducted to inform the development of the Designing our Tomorrow exhibit and
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