Reflections from a researcher and caregiver on the process of working together on a study examining strategies to communicate the relevance of engineering practices at exhibits.
Tinkering experiences in informal learning spaces can engage families in engineering practices and support learning (Pagano et al., 2020). Further, reflections after informal learning experiences can reveal and extend children’s memory and learning (Pagano et al., 2019), but reflections vary by age, culture, setting, program, and other factors (Fivush et al., 2006). We examined how the conversational structure and engineering content of families’ reflections vary across multiple museum visits and across different types of tinkering programs (e.g., open-ended vs. function-focused).
Tinkering activities designed for parents and children can foster spatial thinking, which benefits spatial skill development (Ramey et al., 2020). During tinkering activities, families may be challenged to use tools and materials to solve open-ended problems (Bevan, 2017). The problems specified by different tinkering challenges can highlight intrinsic or extrinsic spatial information (Chatterjee, 2008; Mix et al., 2018). In this project we asked, how does the spatial information highlighted by a tinkering challenge affect the quality of families’ spatial thinking?
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TEAM MEMBERS:
Naomi PolinskyElena FiegenKaitlyn HurkaCatherine HadenDavid Uttal
The tinkering process of making, testing, and iteratively redesigning projects can teach children about engineering concepts (Marcus et al., 2021; NGSS, 2013), but there is variability in how tinkering programs are designed. Storytelling may make children’s learning experiences personally meaningful and narratively organized, thereby supporting memory (Bruner, 1996). We designed multiple story-based tinkering programs and examined how the types of story characters and goals introduced in the tinkering programs would relate to the content of families’ talk in post-tinkering reflections.
In this project, we asked whether storytelling during tinkering might support children’s engagement in STEM and how that may differ across boys and girls. According to Bruner (1996), stories can help children to organize experiences by adding coherence, increasing understanding, and facilitating learning. We observed associations between story and STEM in two contexts: home and museum exhibit.
Given the important role of autonomy support in children’s motivation and learning, this study asked whether parents’ use of autonomy supportive language (vs. controlling language) was associated with children’s engagement in science, technology, engineering, and mathematics in a bi-directional manner during an at-home tinkering activity.
Hands-on tinkering experiences can help promote more equitable STEM learning opportunities for children from diverse backgrounds (Bevan, 2017; Vossoughi & Bevan, 2014). Latine heritage families naturally engage in and talk about engineering practices during and after tinkering in a children’s museum (Acosta & Haden, in press). We asked how the everyday practice of oral stories and storytelling could be leveraged during an athome tinkering activity to support children’s informal engineering and spatial learning.
Informal educational activities, such as tinkering, can be beneficial for children’s engineering learning (Bevan, 2017; Sobel & Jipson, 2016). Storytelling can help children organize and make meaning of their experiences (Brown et al., 2014; Bruner, 1996), thereby supporting learning. Digital storytelling, in which narratives and reflections are combined with photos and videos in order to be shared with an audience, has become a familiar, enjoyable activity for many children (Robin, 2008). We examine whether digital storytelling activities during tinkering and reflection will be related to
Informal educational activities, such as tinkering, can be beneficial for children’s engineering learning (Bevan, 2017; Sobel & Jipson, 2016). Storytelling can help children organize and make meaning of their experiences (Brown et al., 2014; Bruner, 1996), thereby supporting learning. We examine whether digital storytelling activities during tinkering and reflection will be related to more engineering talk.We also explore whether children with previous digital storytelling experience will produce higher quality narratives than children without.
This practitioner guide summarizes lessons learned from a three-year design-based research project focused on using elements of narrative (such as characters, settings, and problem frames) to evoke empathy and support girls' engagement in engineering design practices. The guide includes a summary of the driving concepts and key research findings from this work, as well as design principles for creating narrative-based engineering activities. Six activity case studies illustrate the design principles in action, and facilitation tips and observation tools offer practical guidance in developing
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