Afterschool continues to be promoted as a complementary setting to school for strengthening science, technology, engineering, and math (STEM) education (for example, Krishnamurthi, Bevan, Rinehart, & Coulon, 2013). This is a reasonable idea: 10.2 million children and youth in the U.S. participate in structured afterschool programs (Afterschool Alliance, 2014), and the flexibility of afterschool settings allows for innovative approaches to STEM exploration and engagement.
Across the country, school administrators and educators struggle to find time for children to engage in physical activity while still giving them enough time in academic instruction. The steep rise in childhood obesity in the U.S. (National Center for Health Statistics, 2011; Ogden, Carroll, Kit, & Flegal, 2014) suggests that the concern is urgent.
DATE:
TEAM MEMBERS:
Georgia HallKristin Fay PostonStephanie Harris
Across the U.S., youth development approaches are being tested in out-of-school time programs as a strategy to combat the growing opportunity gap between privileged and underprivileged youth (Gardner, Roth, & Brooks-Gunn, 2009). Along with increased recognition of the value of youth development programming has come increased financial support (Padgette, 2003; Zeller-Berkman, 2010). This investment, in turn, brings increased pressure to continually prove to funders that youth development programs affect student outcomes (Zeller-Berkman, 2010). The increased emphasis on accountability has
DATE:
TEAM MEMBERS:
Sarah Zeller-BerkmanCarolina Munoz-ProtoMaria Elena Torre
The afterschool hours offer children unscripted and flexible time to explore their spaces and interests so they can learn in and from their surroundings. They engage with the world, exploring natural environments and connecting with others through social relationships. For example, during informal fútbol games with friends, children learn how to position their bodies to block opponents and take shots on goal. At home, they view cartoons on television and delight in characters that float by escaping from gravity. With their families, they prepare the garden in spring by collecting earthworms
DATE:
TEAM MEMBERS:
Kathryn CiechanowskiSueann BottomsAna Lucia FonsecaTyler St. Clair
Professional development is vital to the success of afterschool programs. Effective professional development enhances afterschool program quality by facilitating staff performance and knowledge; in addition, professional development is vital for improving student learning outcomes (Bouffard & Little, 2004; Hall & Surr, 2005; Joyce & Showers, 2002). Well-planned professional development also contributes to increased staff satisfaction and retention (Huang & Cho, 2010).
Challenge seeking is an important component of children’s personal and academic development. Defined in this paper as a set of beliefs and behaviors that propels individuals to initiate and persist at difficult ventures, challenge seeking is a key indicator of mastery goal orientation. This orientation has been linked with a number of positive and adaptive behaviors. For instance, research shows that individuals who pursue mastery goals are more likely than others to value cooperation, seek help when confused, and use deeper learning strategies such as monitoring their comprehension and
The Wild Center will develop, implement, and disseminate a model program, VTS in Science, for the science museum field adapted from the Visual Thinking Strategies (VTS) teaching method. In partnership with several museums, educators, and a consulting firm, the Wild Center will use current research to develop informal and formal learning programming; implement a model professional development program for science museum professionals and elementary teachers; provide educators resources and knowledge to develop VTS in Science programming relevant to daily teaching—including a VTS in science toolkit; facilitate a long-term collaborative process and model school-museum partnership among a diverse group of education providers; and evaluate the effectiveness of the VTS in Science program in order to promote replication by science museums nationally.
Brookfield Zoo will expand its "Zoo Adventure Passport" (ZAP!) program for urban families with children ages 3-12 to serve additional families and increase informal science learning opportunities in the two Chicago suburbs of Cicero/Berwyn and Melrose Park. The program will serve as a gateway to new family experiences, teaching families and children about their local and world environments, and providing an opportunity for family enrichment in a community-centered learning environment. The zoo will use presentations and activities to enhance science learning, offer field trips that reconnect urban families with wildlife and nature, and provide STEM content through multigenerational science learning. Through this project, the zoo will increase family participation by 25%; improve student performance in school; increase family interest in and enthusiasm about science, nature, and the environment, and increase family participation in their children's education.
The Arboretum at Flagstaff will design build and evaluate three outdoor kiosks for the "Interactive STEM Learning Center" (I-STEM), which will engage students and general audiences in the science, technology, engineering, and mathematics of real-time climate change research, interpretation, and mitigation. The kiosks will help the arboretum raise awareness about climate change, connect people to on-the-ground scientific investigation, teach students and teachers, and de-mythologize a politicized issue. The project will create a local resource for learning about climate change impacts and mitigation practices that are place-based and more readily accepted.
The Museo de Arte de Puerto Rico will develop and implement "Art and Technology," which will provide learning opportunities to at-risk youth in the San Juan metropolitan area by integrating the museum's exhibits and collections as a platform for learning activities and dynamic thinking. Through lessons on digital media, photography, and art aligning with academic standards, students will acquire technology and problem-solving skills, language proficiency and communication skills, the ability to better interact with peers, and enhanced information skills. At-risk youth will be able to use the museum as an innovative learning facility with free art and technological resources to develop their skills to learn, create, and share with their peers their work in a safe environment.
Sam Noble Oklahoma Museum of Natural History will develop traveling natural history science curricula kits for K-12 students. This project will expand the museum's outreach program, featuring STEM (Science, Technology, Engineering, and Mathematics) content with a focus on Oklahoma geology, life, and cultural science. The museum will share the educational kits, featuring materials aligning with state educational standards, with teachers across Oklahoma. The museum's digitization of the kits will increase the capacity and number of teachers who have access to the material and enable students to experience high-quality STEM educational opportunities offsite and online.
The Cyberlearning and Future Learning Technologies Program funds efforts that support envisioning the future of learning technologies and advance what we know about how people learn in technology-rich environments. In this Cyberlearning EAGER project, the project team is developing foundations for using "paper mechatronics" as a learning technology. Paper mechatronics makes possible a craft-oriented approach to engineering and computing education that integrates key concepts from mechanical engineering, electrical engineering, control systems, and computer programming, while using paper as the primary material for learner design, exploration, and inquiry. In this approach, learners will design foldable paper components and assemblies; program motors, sensors and controls; test their ideas iteratively; and share their designs on a website. This paper-based modeling approach to learning concepts in and practices of mechanical engineering, electrical engineering, control systems, and computer programming ultimately aims to make it possible for all learners to have exposure to and the opportunity to participate in creative engineering, design, and computer programming.
The approach to learning through designing and making through paper mechatronics is made possible by a convergence of many different technological factors -- the array of small computers, sensors, and actuators that are becoming available at low cost and a size that children can use; availability of a wide variety of manipulable conductive materials (threads, paints, fabrics); low-cost and precise desktop and laser cutters for paper and similar materials; a wide variety of novel paper-like materials; and new ways of interacting with the computer. The approach has its foundations in Papert's constructionism and in the current maker movement, but it has potential beyond constructionism itself, both in practice and with respect to what can potentially be learned about learning and development in in context of its use.