Investigators from the MIT Media Lab will develop and study a new generation of the Scratch programming platform, designed to help young people learn to think creatively, reason systematically, and work collaboratively -- essential skills for success in the 21st century. With Scratch, young people (ages 8 and up) can program their own interactive stories, games, animations, and simulations, then share their creations with others online. Young people around the world have already shared more than 1 million projects on the Scratch community website (http://scratch.mit.edu). The new generation, called Scratch 2.0, will be fully integrated into the Internet, so that young people can more seamlessly share and collaborate on projects, access online data, and program interactions with social media. The research is divided into two strands: (1) Technological infrastructure for creative collaboration. With Scratch 2.0, people will be able to design and program new types of web-based interactions and services. For example, they will be able to program interactions with social-media websites (such as Facebook), create visualizations with online data, and program their own collaborative applications. (2) Design experiments for creative collaboration. As the team develops Scratch 2.0, they will run online experiments to study how their design decisions influence the ways in which people collaborate on creative projects, as well as their attitudes towards collaboration. This work builds on a previous NSF grant (ITR-0325828) that supported the development of Scratch. Since its public launch in 2007, Scratch has become a vibrant online community, in which young people program and share interactive stories, games, animations, and simulations - and, in the process, learn important computational concepts and strategies for designing, problem solving, and collaborating. Each day, members of the Scratch community upload nearly 1500 new Scratch projects to the website - on average, a new project almost every minute. In developing Scratch 2.0, the team will focus on two questions from the NSF Program Solicitation: (1) Will the research lead to the development of new technologies to support human creativity? (2) Will the research lead to innovative educational approaches in computer science, science, or engineering that reward creativity? Intellectual Merit: The intellectual merit of the project is based on its study of how new technologies can foster creativity and collaboration. The investigators will conduct design experiments to examine how new features of Scratch 2.0 engage young people in new forms of creative expression, collaboration, learning, and metadesign. Young people are already interacting with many cloud-based services (such as YouTube and Facebook). But Scratch 2.0 is fundamentally different in that it aims to engage people in programming their own projects and activities in the cloud. With Scratch 2.0, young people won?t just interact with the cloud, they will create in the cloud. The goal is to democratize the development of cloud-based activities, so that everyone can become an active contributor to the cloud, not just a consumer of cloud-based services. This development and study of Scratch 2.0 will lead to new insights into strategies for engaging young people in activities that cultivate collaboration and creativity. Broader Impacts: The broader impact of the project is based on its ability to broaden participation in programming and computer science. The current version of Scratch has already helped attract a broader diversity of students to computer science compared to other programming platforms. The investigators expect that the collaboration and social-media features of Scratch 2.0 will resonate with the interests of today's youth and further broaden participation. Integration of Scratch into the introductory computer science course at Harvard led to a sharp reduction in the number of students dropping the course, and an increase in the retention of female students. There have been similar results in pre-college courses. The National Center for Women & Information Technology (NCWIT) calls Scratch a ?promising practice? for increasing gender diversity in IT.
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Mitchel ResnickNatalie RuskJohn Maloney
ITR: A Networked, Media-Rich Programming Environment to Enhance Informal Learning and Technological Fluency at Community Technology Centers The MIT Media Laboratory and UCLA propose to develop and study a new networked, media-rich programming environment, designed specifically to enhance the development of technological fluency at after-school centers in economically disadvantaged communities. This new programming environment (to be called Scratch) will be grounded in the practices and social dynamics of Computer Clubhouses, a network of after-school centers where youth (ages 10-18) from low-income communities learn to express themselves with new technologies. We will study how Clubhouse youth (ages 10-18) learn to use Scratch to design and program new types of digital-arts projects, such as sensor-controlled music compositions, special-effects videos created with programmable image-processing filters, robotic puppets with embedded controllers, and animated characters that youth trade wirelessly via handheld devices. Scratch's networking infrastructure, coupled with its multilingual capabilities, will enable youth to share their digital-arts creations with other youth across geographic, language, and cultural boundaries. This research will advance understanding of the effective and innovative design of new technologies to enhance learning in after-school centers and other informal-education settings, and it will broaden opportunities for youth from under-represented groups to become designers and inventors with new technologies. We will iteratively develop our technologies based on ongoing interaction with youth and staff at Computer Clubhouses. The use of Scratch at Computer Clubhouses will serve as a model for other after-school centers in economically-disadvantaged communities, demonstrating how informal-learning settings can support the development of technological fluency, enabling young people to design and program projects that are meaningful to themselves and their communities.
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TEAM MEMBERS:
Mitchel ResnickJohn MaedaYasmin Kafai
We examined the durability of students’ understanding of lunar phenomena one year after a combination of planetarium and classroom lessons. Children (N=16) were interviewed before and after instruction during Year 1 and then again one year later. Analysis of the interview results and instruction reveals that many students retained an understanding of some of the key constructs targeted in the program. Results also suggest that students were more likely to learn and remember challenging constructs that they actively engaged with in both the planetarium and the classroom.
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Pennsylvania State UniversityJulia PlummerArcadia University
The article discusses initiatives by the Cornell Lab of Ornithology to connect youth to the natural world through birding. It has developed educational resources, known as BirdSleuth which are used around the U.S. to support students in citizen-science participation, outdoor activities, and inquiry-based investigations. It talks about BirdSleuth's Investigating Evidence module, the "Classroom BirdScope" research journal, and the Cornell Lab of Ornithology's eBird citizen-science project.
The article discusses citizen science projects focused on entomology, and examines their usefulness for engaging students in science education and providing meaningful hands-on educational experiences. Advice for incorporating citizen science into lessons and curricula are offered, and the applicability of entomology to science education standards is touched on.
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Renee ClarJames WandersheeJohn GuytonMichael Williams
Collaboration efforts between educator preparation programs and children's science museums are important in assisting elementary pre-service teachers connect the theory they have learned in their classrooms with the actual practice of teaching. Elementary pre-service teachers must not only learn the science content, but how to effectively deliver that science content to a group of students. One university provided their elementary pre-service teachers with the opportunity to prepare and deliver science lessons to students in a children's science museum in south Texas.
This study explored the nature of the relationship between a fifth-grade teacher and an informal science educator as they planned and implemented a life science unit in the classroom, and sought to define this relationship in order to gain insight into the roles of each educator. In addition, student learning as a result of instruction was assessed. Prior research has predominately examined relationships and roles of groups of teachers and informal educators in the museum setting (Tal et al. in Sci Educ 89:920–935, 2005 ; Tal and Steiner in Can J Sci Math Technol Educ 6:25–46, 2006 ; Tran 2007
Many of the biggest problems facing the United States and the world require engineering expertise to solve: climate change, feeding a growing population, energy independence, access to clean water, crumbling infrastructure, and others. And with global economic competitiveness inextricably linked to innovation, employers across a wide range of engineering and non-engineering fields such as health care, management, and marketing are seeking employees with engineering knowledge and related skills. These skills include the ability to creatively and systematically solve ill-defined problems
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Community for Advancing Discovery Research in Education (CADRE)
This evaluation reports on the Mission: Solar System project, a 2-year project funded by NASA. The goal of the Mission: Solar System was to create a collection of resources that integrates digital media with hands-on science and engineering activities to support kids’ exploration in formal and informal education settings. Our goal in creating the resources were: For youth: (1) Provide opportunities to use science, technology, engineering, and math to solve challenges related to exploring our solar system, (2) Build and hone critical thinking, problem-solving, and design process skills, (3)
The Young Developers program is an after school program conceptualised and run by The P-STEM Foundation. It introduces computer programming and design concepts to high school age students from South African historically disadvantaged communities, where the majority of students have had little or no interaction with computers. Young Developers uses Self Organised Learning Methodology and involves introducing a series of increasingly complex challenges / questions that the participants have to collaboratively solve. The first module is run in Scratch with the final objective being the creation of a racing car game. The second module is run in Python using Turtle graphics with an objective of creating an animation. This program runs as pods in each of the communities that the P-STEM foundation works in. Each pod has up to 30 teens from the age of 10 to 18. Each pod is peer led and peer driven, and the pace of learning is determined by the participants. In 2015, we would also like to introduce national competitions which pods participate in against other pods.
Bang, Warren, Rosebery, and Medin explore empirical work with students from non-dominant communities to support teaching science as a practice of inquiry and understanding, not as a “settled” set of ideas and skills to learn.
The adoption of the Next Generation Science Standards means that many educators who adhere to model-based reasoning styles of science will have to adapt their programs and curricula. In addition, all practitioners will have to teach modeling, and model-based reasoning is a useful way to do so. This brief offers perspectives drawn from Lehrer and Schauble, two early theorists in model-based reasoning.