Researchers examined whether engineering activities and lessons can help students apply science and math content in real-world contexts and gain insights into the professional activities and goals of engineers.
The new standards posit that “scientific argumentation,” in which students use data to argue from evidence, is a key practice for student science learning. However, a mismatch in expectations about the purpose of classroom discussions can inhibit productive forms of argumentation. Berland and Hammer compare forms of class discussions to identify how best to support students’ engagement in argumentation.
Dancu, Gutwill, and Hido describe a process for designing science museum exhibits to create playful learning experiences. They outline five characteristics of play: It is structured by constraints, active without being stressful, focused on process not outcome, self-directed, and imaginative. For each characteristic, they offer an example of iterative design using formative evaluation.
WCS launched its electronic field trip program, Distance Learning Expeditions, in 2001 when there
was tremendous interest in the educational community in the potential of videoconferencing
technology for program delivery, as well as money available for the purchase of related broadcast
equipment. The program grew rapidly and was successful through 2009 -- serving 9,600 students
in 2006-07, its largest year. From 2010 to 2014, with school budget cuts, high equipment
maintenance costs, and shifts in staffing, participation in the program declined. In 2010, WCS
secured a grant from IMLS for
Most communities have afterschool programs that give school-aged students a safe place to go after the dismissal bell rings. The next step after simply providing a safe haven is to create a nurturing environment that develops young people’s talents and supports their needs. A formal mentoring program can help to achieve this goal.
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TEAM MEMBERS:
Sara McDanielAnna-Margaret YarbroughKevin Besnoy
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 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
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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
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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.