Given the growth of technology in the 21st century and the growing demands for computer science skills, computational thinking has been increasingly included in K-12 STEM (Science, Technology, Engineering and Mathematics) education. Computational thinking (CT) is relevant to integrated STEM and has many common practices with other STEM disciplines. Previous studies have shown synergies between CT and engineering learning. In addition, many researchers believe that the more children are exposed to CT learning experiences, the stronger their programming abilities will be. As programming is a
Informal learning environments such as science centers and museums are instrumental in the promotion of science, technology, engineering, and mathematics (STEM) education. These settings provide children with the chance to engage in self-directed activities that can create a of lifelong interest and persistence in STEM. On the other hand, the presence of parents in these settings allows children the opportunity to work together and engage in conversations that can boost understanding and enhance learning of STEM topics. To date, a considerable amount of research has focused on adult-child
Engineering is a critical yet understudied topic in early childhood. Previous research has shown that even young children can engage in (versions of) engineering design practices and processes that are similar to those of adult engineers and designers. In this session, we will share and discuss current research projects to explore how different in-school and out-of-school contexts and activities support 3- to 8-year-old children as they engage in engineering design. We will consider ways that the different characteristics of the activities and spaces, as well as the practices of teachers
This is an overview of the programs hosted by the Chicago Children's Musuem (CCM) and the Evanston Public Library (EPL). There were a total of eight programs at the CCM:
"Making Stringed Instruments" with Dustin, head of Tinkering School Chicago
"Making Swing Sets" with Dan, a mechanical engineer
"Making Fan-Powered Cars" with Jason, a mechanical engineer and co-founder of Project SYNCERE
"Making Wings" with Anna, a costume engineer
"Wired Up" a project involving circuits with Jason, a mechanical engineer and co-founder of Project SYNCERE
"Robots and Dirt" a project using
This poster was presented at the American Educational Research Association Annual Meeting, Toronto, Ontario, CA in April 2019.
Young children have been described as immersed in a diverse world of personal stories, with different structures and functions, through family narrative practices (Miller, Chen & Olivera, 2014). Drawing on story schema theory (Mandler, 1978) and linguistic approaches to the analysis of narrative form (Labov, 1982), personal narratives that support learning and remembering must include evaluation of actions, and emotions, to convey what is meaningful and memorable
This poster was presented at the American Educational Research Association Annual Meeting, Toronto, Ontario, CA in April 2019.
The project's goal is to identify and document effective processes for engaging engineering experts to lead inquiry based programs in ways that advance STEM learning opportunities for children and families.
Today’s digital and online media demand an approach to learning keyed to a networked and interconnected world. The growth of online communities, social and online media, open educational resources, ubiquitous computing, big data, and digital production tools means young people are coming of age with a growing abundance of access to knowledge, information, and social connection. These shifts are tied to a host of new opportunities for interest-driven learning, creative expression, and diverse forms of contribution to civic, political, and economic life. Even learning of traditional academic
K-12 informal engineering education can support student confidence, interest, and awareness of the field of engineering. Studies have suggested that K-12 informal learning can influence students’ awareness of the fields of engineering as potential career opportunities. Researchers have also found that engineering activities outside of school can engage youth in disciplines of which they are unfamiliar because of a lack of engineering opportunity in K12 formal education. In this paper, we provide a rich case study of one lesson’s implementation in a 5th-6th grade girls afterschool program. Our
This Conference Paper was presented at the International Soceity for the Learning Sciences Confernece in June 2018. We summarize interviews with youth ages 9-15 about their failure mindsets, and if those midsets cross boundaries between learning environments.
Previous research on youth’s perceptions and reactions to failure established a view of failure as a negative, debilitating experience for youth, yet STEM and in particular making programs increasingly promote a pedagogy of failures as productive learning experiences. Looking to unpack perceptions of failure across contexts and
This poster shows an overview of the The Designing Our Tomorrow (DOT) project. The project aims to develop a framework for creating exhibit-based engineering design challenges and expand an existing model of facilitation for use in engineering exhibits. DOT seeks to broaden participation in engineering and build capacity within the informal science education (ISE) field while raising public awareness of the importance of sustainable engineering design practices.
This poster was presented at the 2019 AISL PI Meeting, and describes the the ongoing research questions and goals of the Ute STEM Project, which explores the integration of the traditional ecological knowledge (TEK) of the Ute Indians of Colorado and Utah and Western science, technology, engineering and math (STEM).
The is the poster presented at the 2019 AISL PI Meeting about a project that explored ways to create conversations between scientists and publics that both groups value and learn from. The content focus was the emerging field of synthetic biology and two methods were developed. Hands-on activities like those developed and distributed by the Nanoscale Informal Science Education Network were developed but with the twist that each activity was designed to stimulate a conversation about societal implications of various applications of synthetic biology. Scientists and science students were trained