The number of jobs requiring proficiency in the science, technology, engineering and math (STEM) fields is projected to grow by 17 percent between 2008 and 2018, which is almost double the growth of non-STEM occupations. Computing and engineering represent a majority of these STEM jobs, and it is important that students are prepared to take advantage of these opportunities. Afterschool programs represent an avenue to provide robust learning experiences in computing and engineering, especially as schools are under many constraints and pressures that might prevent them from offering these topics
The Science and Technology Museum from Catalunya (mNACTEC) has developed a virtual exhibition from the documents and objects used for the exhibition "Experimental Physics Laboratory of the Mentor Alsina". The main objective of the virtual exhibition is complementary to the current exhibition. Provide information, list of objects and operating proposal that could be difficult to develop in an exhibition in which dominates the environmental sense. The virtual exhibition offers information on all objects of the early twentieth century that form the collection of laboratory and interactive
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TEAM MEMBERS:
Joan MunozSantiago VallmitjanaJaume ValentinesStefano D'Argenio
The Coalition for Science After School was launched January 28, 2004 at the Santa Fe Institute, home to the world’s leading researchers on the study of complexity. Against the dazzling backdrop of the New Mexican mesa, 40 educational leaders from diverse but overlapping domains—science, technology, engineering and mathematics education and after-school programs—met to grapple with three emerging, important trends in youth development and science learning in this country: 1. An explosion in the number of U.S. youth attending after-school programs, and increasing links between school and after
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TEAM MEMBERS:
The Coalition for Science After SchoolLeah Reisman
resourceresearchProfessional Development, Conferences, and Networks
Designed learning environments like museums have the potential to change the way that families think and talk about scientific topics together in everyday contexts like the home. The current study examines the affect of a visit to a museum exhibit highlighting the processes of manufacturing on the ability of parents and children to talk about how familiar objects are made. A model for family knowledge building is also presented as a means of assessing whether parents and children improved their understanding of manufacturing processes after their museum visit. A simulated home activity
While we should celebrate our success at evolving many vital aspects of the human-technology interactive experience, we question the scope of this progress. Step back with us for a moment. What really matters? Everyday life spans a wide range of emotions and experiences -- from improving productivity and efficiency to promoting wonderment and daydreaming. But our research and designs do not reflect this important life balance. The research we undertake and the applications we build employ technology primarily for improving tasks and solving problems. Our claim is that our successful future
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TEAM MEMBERS:
Eric PaulosTom JenkinsAugust JokiParul Vora
From March 26-28, 2014, the Coalition for Science After School (CSAS) hosted its final summit, Passing the Torch: Advancing Opportunity for Quality Science Learning. The Summit was intended to: (1) celebrate a decade of progress in strengthening and expanding STEM learning opportunities in out-of-school time; (2) call attention to critical issues in ensuring that all young people have opportunities for quality STEM experiences in their local communities; and (3) stimulate ideas, strategies, partnerships and commitments to continue to increase opportunities for quality STEM experiences across
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TEAM MEMBERS:
The Coalition for Science After SchoolLeah Reisman
This action plan lays out a structure that will allow stakeholders from local, State, and Federal governments, as well as nongovernmental STEM education stakeholder groups, to work together to coordinate and enhance the Nation's ability to produce a numerate and scientifically and technologically literate society and to increase and improve the current STEM education workforce. Strategies for producing the next generation of innovators are not explicitly addressed in this action plan and will require subsequent study. A coherent system of STEM education is essential to the Nation's economy and
The Maker Program Blueprint offers a template for afterschool or summer programs and addresses the types of spaces that can be used, ideas about schedules and format, and the materials and personnel needed to create and sustain a program.
In January 2012, New York Hall of Science (NYSCI) hosted Design-Make-Play: Growing the Next Generation of Science Innovators. The two-day conference brought together leaders of schools, community-based programs, research and development organizations, the funding community, universities, government and business. They gathered at NYSCI to assemble evidence supporting the belief that designing, making and playing can create new pathways into science, technology, engineering and math (STEM), particularly among children. A core argument of Design-Make-Play is that informal learning centers like
Recognizing that the Maker movement embodies aspects of science, technology, engineering, and mathematics (STEM) learning that are the hallmarks of effective education — deep engagement with content, critical thinking, problem solving, collaboration, learning to learn, and more — NYSCI, in collaboration with Dale Dougherty and Tom Kalil, approached the National Science Foundation to sponsor a two-day workshop. Over 80 leaders in education, science, technology and the arts came together at NYSCI to consider how the Maker movement can help stimulate innovation in formal and informal education
In October 2005, the National Science Foundation brought members of its nanoscale science and engineering education (NSEE) projects to Arlington, VA for a 2-day workshop to explore the status of on-going efforts and to forge collaborations at the national level that would facilitate future efforts. NSF currently funds NSEE projects through the Division of Elementary, Secondary, and Informal Education (ESIE), the Directorate for Engineering as part of the Nanoscale Science and Engineering Centers (NSEC), National Nanotechnology Infrastructure Network (NNIN), the Network for Computational
NSF's Cyberinfrastructure Vision for 21st Century Discovery is presented in a set of interrelated chapters that describe the various challenges and opportunities in the complementary areas that make up cyberinfrastructure: computing systems, data, information resources, networking, digitally enabled-sensors, instruments, virtual organizations, and observatories, along with an interoperable suite of software services and tools. This technology is complemented by the interdisciplinary teams of professionals that are responsible for its development, deployment and its use in transformative