The data collection procedure and process is one of the most critical components in a research study that affects the findings. Problems in data collection may directly influence the findings, and consequently, may lead to questionable inferences. Despite the challenges in data collection, this study provides insights for STEM education researchers and practitioners on effective data collection, in order to ensure that the data is useful for answering questions posed by research. Our engineering education research study was a part of a three-year, NSF funded project implemented in the Midwest
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TEAM MEMBERS:
Ibrahim YeterAnastasia Marie RynearsonHoda EhsanAnnwesa DasguptaBarbara FagundesMuhsin MeneskeMonica Cardella
Integrating science, technology, engineering, and mathematics (STEM) subjects in pre-college settings is seen as critical in providing opportunities for children to develop knowledge, skills, and interests in these subjects and the associated critical thinking skills. More recently computational thinking (CT) has been called out as an equally important topic to emphasize among pre-college students. The authors of this paper began an integrated STEM+CT project three years ago to explore integrating these subjects through a science center exhibit and a curriculum for 5-8 year old students. We
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TEAM MEMBERS:
Morgan HynesMonica CardellaTamara MooreSean BrophySenay PurzerKristina TankMuhsin MeneskeIbrahim YeterHoda Ehsan
Computational Thinking (CT) is an often overlooked, but important, aspect of engineering thinking. This connection can be seen in Wing’s definition of CT, which includes a combination of mathematical and engineering thinking required to solve problems. While previous studies have shown that children are capable of engaging in multiple CT competencies, research has yet to explore the role that parents play in promoting these competencies in their children. In this study, we are taking a unique approach by investigating the role that a homeschool mother played in her child’s engagement in CT
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
Increasing demand for curricula and programming that supports computational thinking in K-2 settings motivates our research team to investigate how computational thinking can be understood, observed, and supported for this age group. This study has two phases: 1) developing definitions of computational thinking competencies, 2) identifying educational apps that can potentially promote computational thinking. For the first phase, we reviewed literatures and models that identified, defined and/or described computational thinking competencies. Using the model and literature review, we then
For the past two decades, researchers and educators have been interested in integrating engineering into K-12 learning experiences. More recently, computational thinking (CT) has gained increased attention in K-12 engineering education. Computational thinking is broader than programming and coding. Some describe computational thinking as crucial to engineering problem solving and critical to engineering habits of mind like systems thinking. However, few studies have explored how computational thinking is exhibited by children, and CT competencies for children have not been consistently defined
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
The purpose of this paper is to provide a better understanding of Maine’s capability to promote 5th-12th graders’ engagement and achievement in STEM during out-of-school hours. The paper will provide a background for the design conference task of constructing “STEM intensives” that make optimal use of Maine’s resources and connect these resources with students in ways that make sense.
This paper describes innovative ways of bringing mathematical learning into community venues in rural settings. We selected highly engaging mathematical activities, adapted them for middle school youth and their families, and brought them to the “locavore” contexts of Farmers Markets and community agricultural fairs. “STEM Guides”—community people hired to connect youth with local STEM resources—set up math-oriented booths at local Farmers Markets and fairs. They enlisted visitors in weighing produce, comparing weights of typical fruits/vegetables to record-weighing produce, and composing
In this article we describe a model designed for rural settings that uses community-based “STEM Guides” as human brokers to engage isolated 10- to 18-year-old youth in STEM. The STEM Guides connect youth with opportunities that already exist in their communities, including after-school programs, clubs, camps, library activities, special events, contests, and competitions. STEM Guides also introduce youth and their families to virtual opportunities, such as citizen science monitoring, and statewide experiences, such as the Maine State Science Fair.
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TEAM MEMBERS:
Jan MokrosJennifer AtkinsonSue AllenAlyson SaundersKate Kastelein
This article describes the research and development of an NSF-funded, five-year experimental program to strengthen informal (out-of-school) STEM learning by youth in five rural communities. The central component of the model was a cadre of community members known as ‘STEM Guides’ who were hired to work as brokers between youth and the STEM learning resources potentially available to them. These STEM Guides were respected adults with credible connections to youth, flexible schedules, the ability to travel within the community, and enthusiasm for identifying local STEM resources. The Guides were
This document is the final summative evaluation report written by EDC, the external evaluator of the STEM Guides project. The report concludes that the project was highly ambitious, with many dynamic and evolving pieces. It was deemed successful as a model of brokering connections between students aged 10-18 and STEM resources and opportunities in rural Maine communities. The STEM Guides program contributed to the increase in STEM awareness within each community, as well as connecting youth with interesting and relevant STEM experiences.